WO2008058165A2 - Bioanode and biocathode stack assemblies - Google Patents
Bioanode and biocathode stack assemblies Download PDFInfo
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- WO2008058165A2 WO2008058165A2 PCT/US2007/083847 US2007083847W WO2008058165A2 WO 2008058165 A2 WO2008058165 A2 WO 2008058165A2 US 2007083847 W US2007083847 W US 2007083847W WO 2008058165 A2 WO2008058165 A2 WO 2008058165A2
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- WIPO (PCT)
- Prior art keywords
- enzyme
- fuel
- cell device
- biofuel cell
- carbon
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Classifications
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/16—Biochemical fuel cells, i.e. cells in which microorganisms function as catalysts
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M16/00—Structural combinations of different types of electrochemical generators
- H01M16/003—Structural combinations of different types of electrochemical generators of fuel cells with other electrochemical devices, e.g. capacitors, electrolysers
- H01M16/006—Structural combinations of different types of electrochemical generators of fuel cells with other electrochemical devices, e.g. capacitors, electrolysers of fuel cells with rechargeable batteries
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M4/8605—Porous electrodes
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M4/90—Selection of catalytic material
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/02—Details
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M8/00—Fuel cells; Manufacture thereof
- H01M8/04—Auxiliary arrangements, e.g. for control of pressure or for circulation of fluids
- H01M8/04298—Processes for controlling fuel cells or fuel cell systems
- H01M8/04694—Processes for controlling fuel cells or fuel cell systems characterised by variables to be controlled
- H01M8/04858—Electric variables
- H01M8/04895—Current
- H01M8/0491—Current of fuel cell stacks
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
Definitions
- the present invention is directed in general to biological enzyme-based fuel cells (a.k.a. biofuel cells) and their methods of manufacture and use. More specifically, the invention is directed to bioanodes, bioanode stacks, biocathodes, and their method of manufacture and use.
- a biofuel cell is an electrochemical device in which energy derived from chemical reactions is converted to electrical energy by catalytic activity of living cells and/or their enzymes.
- Biofuel cells generally use complex molecules to generate at the anode the hydrogen ions required to reduce oxygen to water, while generating free electrons for use in electrical applications.
- a bioanode is the electrode of the biofuel cell where electrons are released upon the oxidation of a fuel and a biocathode is the electrode where electrons and protons from the anode are used by the catalyst to reduce peroxide or oxygen to water.
- Biofuel cells differ from the traditional fuel cells by the material used to catalyze the electrochemical reaction. Rather than using precious metals as catalysts, biofuel cells rely on biological molecules such as enzymes to carry out the reaction.
- a biofuel cell device for generating electrical current, comprising a fuel manifold, an anode assembly, a cathode assembly, a housing, and a controller.
- the fuel manifold has a face, and at least one cavity in the face defining a fuel reservoir, an inlet for flow of fuel fluid into the manifold to fill the reservoir and an outlet for flow of fuel fluid out of the manifold.
- the anode assembly comprises at least one bioanode positioned for contact with fuel fluid in said fuel reservoir.
- the cathode assembly comprises at least one cathode positioned for flow of fuel fluid through the bioanode to the cathode.
- the housing houses the manifold, anode assembly and cathode assembly.
- the controller controls the output of electrical current from the biofuel cell device.
- Another aspect is a biofuel cell device for supplying electrical power to a load, said device comprising at least one fuel cell; a controller for controlling an output of the fuel cell according to a defined operating mode; and a switch circuit situated between the fuel cell and the load, said switch circuit being responsive to the controller for AKER 10002.1
- a further aspect is a biofuel cell device for supplying electrical power to a load, said device comprising at least one fuel cell; a controller for controlling an output of the fuel cell according to a defined operating mode; and a supplemental power circuit responsive to the controller for selectively connecting a supplemental power source to the output of the fuel cell thereby supplementing the electrical power supplied to the load by the biofuel cell device.
- biofuel cell device for supplying electrical power to a load, said device comprising a plurality of fuel cells electrically connected in series; a controller for controlling an output of each of the fuel cells according to at least one of a plurality of defined operating modes; and a switch circuit situated between the fuel cells and the load, said switch circuit being responsive to the controller for selectively connecting one or more of the fuel cells to the load according to the operating mode.
- Yet a further aspect is a method of electrically conditioning an output of one or more fuel cells of a biofuel cell device, said biofuel cell device being adapted for supplying electrical power to a load, said method comprising electrically connecting a switch circuit between the fuel cells and the load; and operating the switch circuit to selectively connect one or more of the fuel cells to the load according to at least one of a plurality of defined operating modes.
- Another aspect of the invention is an electrode comprising a first region of electrically conductive material being permeable to air and impermeable to a fuel fluid; a second region of conductive material being permeable to the fuel fluid and to air; and a non-precious metal catalyst being able to contact both the fuel fluid and air.
- An air- breathing half-cell comprising the electrode would generate a current density of at least about 16, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, or more mA/cm 2 when operating at room temperature, an electrode potential of 0.4 V, and a catalyst loading of 10 mg/cm 2 .
- a further aspect of the invention is a heated-treated electrode comprising an electron conductor; and at least one non-precious metal catalyst being capable of selectively reducing oxygen to water.
- An air-breathing half-cell comprising the electrode would generate a current density of at least about 16, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, or more mA/cm 2 when operating at room temperature, an electrode potential of 0.4 V, and a catalyst loading of 10 mg/cm 2 .
- Yet another aspect of the invention is a biocathode comprising an electron conductor, at least one cathode enzyme capable of reacting with an oxidant to produce water, and an enzyme immobilization material capable of immobilizing and stabilizing the enzyme, the material being permeable to the oxidant.
- the electron conductor comprises functionalized multi-walled carbon nanotubes, an activated carbon-based material, or a combination thereof.
- a further aspect of the invention is a catalyst comprising cobaltCITIl ⁇ AS ⁇ .lO.l l.lS.l ⁇ n.lS ⁇ a ⁇ S-hexadecafluoro ⁇ H ⁇ lH- phthalocyanine (CoPcF); and polypyrrole.
- CoPcF and polypyrrole have been heat treated to increase the interaction between the cobalt metal atom and the polypyrrole nitrogen atoms.
- particles comprising a core coated with an immobilized enzyme, the enzyme being immobilized in an immobilization material and having an activity of at least about 0.65, 0.7, 0.75, 0.8, 0.85, 0.9, 0.95, or more relative to its initial activity before immobilization and coating.
- particles comprising a core coated with an immobilized enzyme, the enzyme being immobilized in an immobilization material and retaining at least about 75% of its initial catalytic activity for at least 7 days when the enzyme is continuously catalyzing a chemical transformation.
- the enzyme retains at least about 75% of its initial catalytic activity for at least 30 days when the enzyme is continuously catalyzing a chemical transformation.
- particles comprising a core coated with an immobilized organelle.
- the organelle is immobilized in an immobilization material.
- a further aspect is a process for preparing particles coated with an immobilized enzyme or organelle comprising: mixing a solution comprising an enzyme or organelle and a suspension comprising at least one core particle, an immobilization material, and a liquid medium to form a mixture. Then, the mixture is spray-dried.
- Another aspect of the invention is an enzyme immobilized in an enzyme immobilization material wherein either: the enzyme comprises starch-consuming amylase and the enzyme immobilization material comprises butyl chitosan suspended in t-amyl alcohol or the enzyme comprises maltose-consuming amylase and the enzyme immobilization material comprises medium molecular weight decyl-modified chitosan.
- the enzyme comprises starch-consuming amylase and the enzyme immobilization material comprises butyl chitosan suspended in t-amyl alcohol or the enzyme comprises maltose-consuming amylase and the enzyme immobilization material comprises medium molecular weight decyl-modified chitosan.
- Yet another aspect is a self-supporting electron conductor comprising a monolayer comprised of a first electrically conductive material having high surface area for transferring electrons, a second electrically conductive material for supporting the electron conductor, and a binder.
- the weight ratio of the second electrically conductive material to the first electrically conductive material in the electron conductor is at least 0.5: 1 to provide sufficient rigidity to the electron conductor for it to be self-supporting.
- the weight ratio of the second electrically conductive material to the first electrically conductive material in the electron conductor is at least 1: 1.
- Fig. 1 is a schematic of a fuel cell device of the present invention.
- FIG. 2 is a perspective of a fuel cell device of the present invention.
- FIG. 3 is a separated perspective of the device of Fig. 2.
- Fig. 4 is a fragmentary perspective of a fuel manifold of the device of Fig. 2.
- Fig. 5 is a front elevation of the fuel manifold.
- Fig. 6 is a cross section of the fuel manifold taken along line 6-6 of Fig. 5.
- Fig. 7 is a front elevation of an anode assembly of the device of Fig. 2.
- FIG. 8 is a separated perspective of the anode assembly of Fig. 7.
- Fig. 9 is a cross section of the anode assembly taken along line 9-9 of Fig. 7.
- Fig. 10 is a front elevation of a cathode assembly of the device of Fig. 2.
- FIG. 11 is a separated perspective of the cathode assembly of Fig. 10.
- Fig. 12 is a cross section of the cathode assembly taken along line 12-12 of Fig. 10.
- Fig. 13 is a perspective of a housing part of a fuel cell device of the present invention.
- Fig. 14 is a schematic of a fuel cell device.
- Fig. 15 is a schematic of a controller of the fuel cell device.
- Figs. 16 and 17 depict an exemplary user interface for receiving user input to design and simulate the modes for an eight cell device.
- Fig. 18 is a perspective of an electronics assembly of the fuel cell device. AKER 10002.1
- Fig. 19 is a separated perspective of fuel cell device of a second embodiment of the present invention.
- Fig. 20 is a perspective of a fuel manifold of the device of Fig. 19.
- Fig. 21 is a separated perspective of the anode assembly of Fig. 19.
- Fig. 22 is schematic of an electrode comprising a first region of electrically conductive material that is permeable to air and impermeable to a fuel fluid, a second region of conductive material that is permeable to the fuel fluid and to air, and a catalyst that is able to contact both the fuel fluid and air.
- This electrode is the working electrode (WE) of an air-breathing half-cell.
- the working electrode (WE) contains the regions or layers labeled 1st region, 2nd region, and catalyst.
- the half cell also includes a reference electrode (RE) placed near the working electrode and a counter electrode (CE) of preferably a precious metal mesh or carbon sheet.
- RE reference electrode
- CE counter electrode
- Fig. 23 is an electron conductor having an asymmetrical pore distribution.
- Fig. 24 is polarization and power curves representing the current progress with NAD dependent GDH biofuel cell stack.
- Fig. 25 is a curve comparing two carbon gas diffusion layer materials (Single sided Elat and gas diffusion layer (GDL) prepared as described herein) and two current collector materials (Au plated SS and Ni) for their impact on the performance of a NAD dependent ADH anodes.
- GDL single sided Elat and gas diffusion layer
- Fig. 26 is curves comparing carbon support (gas diffusion layer) material properties of the various materials and their impact on the performance of a NAD dependent ADH anode.
- Fig. 27 is a curve comparing six types of ADH enzyme and a commercially available ADH (NAD dependent).
- Fig. 28 is a power curve of a single half cell anode (lcm 2 ) demonstrating power densities of 15 mW/cm 2 .
- Fig. 29A and 29B are polarization and power curves representing the current progress and state of the art in PQQ dependent ADH biofuel cell stack performance.
- Fig. 30A and 30B are polarization and power curves representing the current progress and state of the art in PQQ dependent ADH biofuel cell stack performance. AKER 10002.1
- Fig. 31 represents polarization of air-breathing cathodes in 1 M sulfuric acid solution.
- Platinum black Johnson Matthey
- Teflon treated carbon cloth E-Tek
- CoPcFCPPy was coated on Teflon treated carbon cloth (E-Tek) in a loading of 10 mg/cm with 30% Nafion in the catalyst layer with or without phosphotungstic acid (PTA) at a ratio of 1 : 10 (PTA:CoPcFCPPy).
- Scan rate 2 mV/s
- Fig. 32 is a polarization curve of cathode electrodes in 1 M sulfuric acid solution with 15 or 30% ethanol.
- CoPcFCPPy as prepared above was coated on Torey carbon paper in a loading of 10 mg/cm 2 with 30% Nafion in the catalyst layer.
- Fig. 33 is a polarization curve of air-breathing cathodes in 1 M sulfuric acid solution containing 15% ethanol.
- CoPcFCPPy as prepared in example 7 was coated on Teflon treated carbon cloth (E-Tek) in a loading of 10 mg/cm 2 with 30% Nafion in the catalyst layer.
- Fig. 34 is a time dependent oxygen reduction current at 0.4 V in 1 M sulfuric acid solution containing 5% ethanol.
- CoPcFCPPy as prepared in 7 was coated on Teflon treated carbon cloth (E-Tek) in a loading of 10 mg/cm 2 with 30% Nafion in the catalyst layer and with or without phosphotungstic acid (PTA) at a weight ratio of 1 : 10 (PTA:CoPcFCPPy).
- Platinum black Johnson Matthey
- Teflon treated carbon cloth E-Tek
- a platinum cathode was also tested in 1 M sulfuric acid solution. Scan rate: 2 mV/s
- Fig. 35 is a polarization curve of air-breathing cathodes in 1 M sulfuric acid solution containing 15% ethanol.
- Platinum black Johnson Matthey
- Teflon treated carbon cloth E-Tek
- CoPcFCPPy was coated on Teflon treated carbon cloth (E-Tek) in a loading of 10 mg/cm with 30% Nafion in the catalyst layer.
- Scan rate 2 mV/s
- Fig. 36 is a polarization curve of air-breathing cathodes in 1 M sulfuric acid solution.
- CoPcFPPy catalysts were coated on Teflon treated carbon cloth (E-Tek) in a loading of 10 mg/cm 2 with 30% Nafion in the catalyst layer. Scan rate: 2 mV/s. Before fabricating the air breathing cathodes the CoPcFCPPy catalysts were leached in 1 M sulfuric acid for 0, 1, 20 or 120 hours. AKER 10002.1
- Fig. 37 is a polarization curve of air-breathing cathodes in 1 M sulfuric acid solution.
- CoPcFCPPy pyrolyzed or unpyrolyzed was coated on Teflon treated carbon cloth (E-T ek) in a loading of 10 mg/cm 2 with 30% nafion in the catalyst layer.
- Scan rate 2 mV/s.
- Fig. 38 is a polarization curve of air-breathing cathodes in 1 M sulfuric acid solution in the presence or absence of 15% ethanol. Pyrolyzed CoPcF/C catalysts were coated on Teflon treated carbon cloth (E-T ek) in a loading of 10 mg/cm 2 with 30% Nafion in the catalyst layer. Scan rate: 2 mV/s.
- Fig. 39 is a polarization curve of air-breathing cathodes in 1 M sulfuric acid solution.
- CoPcFPPy and CoPcCPPy catalysts were coated on Teflon treated carbon cloth (E-T ek) in a loading of 10 mg/cm with 30% nafion in the catalyst layer.
- Scan rate 2 mV/s.
- Fig. 40 is a cyclic voltammogram of bilirubin oxidase (Myrothecium verrucaria)-multiwall carbon nanotube immobilized on Torey carbon paper in acetate buffer solution (pH 5). Scan rate: 100 mV/s.
- Fig. 41 is a cyclic voltammogram of laccase (Agaricus bisporus)- multiwall carbon nanotube immobilized on Torey carbon paper in acetate buffer solution (pH 5). Scan rate: 50 mV/s.
- Fig. 42 is a polarization curve of air-breathing biocathode in acetate buffer solution (pH 5). Laccase (Trametes spec)/ carboxyl functionalized-multiwall carbon nanotubes were immobilized on water-proofing carbon cloth. Scan rate: 2 mV/s.
- Fig. 43 is a polarization curve of air-breathing biocathode in acetate buffer solution (pH 5). Bilirubin oxidase (Myrothecium verrucaria)/ carbon nanotubes were immobilized on water-proofing carbon cloth. Scan rate: 2 mV/s.
- Fig. 44 is a polarization curve of air-breathing biocathode in acetate buffer solution (pH 5).
- Bilirubin oxidase Myrothecium verrucaria
- carbon blacks or carbon nanotubes were immobilized on water-proofing carbon cloth.
- Scan rate 2 mV/s.
- Fig. 45 is a polarization curve of air-breathing biocathode in acetate buffer solution (pH 5).
- Bilirubin oxidase Myrothecium verrucaria
- hydroxyl functionalized multiwall carbon nanotubes were immobilized on water-proofing carbon cloths (double sided coatings - DS from E-Tek; in house coatings - Carbon cloth D/XE2).
- Scan rate 2 mV/s.
- Fig. 46 is a polarization curve of biocathode in acetate buffer solution saturated by oxygen (pH 5).
- Bilirubin oxidase Myrothecium verrucaria
- Scan rate 2 mV/s
- Fig. 47 is a schematic representation of a particle coated with an electron mediator, an enzyme (with two subunits), and an enzyme immobilization material.
- Fig. 48 is a schematic of an airbrush spray drying a mixture onto a polycarbonate shield.
- Fig. 49 is a linear sweep voltammogram demonstrating the retention of activity of encapsulated alcohol dehydrogenase as described in Example 17 and made into a carbon composite electrode.
- Fig. 50 is a graph of the relative enzyme activity for starch-consuming amylase immobilized in various enzyme immobilization materials.
- Fig. 51 is a graph of the relative enzyme activity for maltose-consuming amylase immobilized in various enzyme immobilization materials.
- Fig. 52 is a schematic of an air breathing biocathode electrode.
- the electrode comprises a conductive monolayer 527.
- Fig. 53 is a schematic of a bioanode electrode.
- the electrode comprises a conductive monolayer 537.
- Fig. 54 is a polarization and power curves comparison of a GDL of the invention to a GDL (Elat) for a biocathode electrode based fuel cell.
- the anode for both cells was a platinum black catalyst on Elat with hydrogen as a fuel.
- the cathode catalyst for both cells was an immobilized laccase enzyme with oxygen as the oxidant.
- Fig. 55 is a polarization and power curves comparison of an anode GDL prepared as described herein to a commercial Anode GDL (Elat) direct methanol fuel cell.
- the anode for both cells was a platinum ruthenium black catalyst on respective GDL materials with 5.0% methanol as a fuel.
- the cathode catalyst for both cells was a platinum black catalyst on Elat GDL with oxygen as the oxidant.
- Fig. 56 is a schematic for the enzyme/nanowires and carbon particle interaction.
- Fig. 57 is a schematic of the pre-defined electron pathways (neural- network- like structure) formed due to interaction of nanowires with each other.
- Fig. 58 is a half cell test of a non-mediated Bio Carbon Paste electrode in 1 M phosphate buffer. AKER 10002.1
- Fig. 59 is a mediated anode half cell in 1 M phosphate buffer at pH 7.2.
- Fig. 60 is a Laccase cathode comparison at room temperature versus a Pt black anode H 2 /O 2 Fuel Cell with and without carbon filler.
- Fig. 61 depicts the performance when the carbon content is varied in a Laccase/Pt black at room temperature in a H 2 /O 2 PEM fuel cell.
- Fig. 62 depicts the performance of various different carbon species in a Laccase/Pt black H 2 O 2 PEM fuel cell at room temperature.
- Fig. 63 depicts the performance of various enzyme/TBAB loadings in a Laccase/Pt black H2O2 PEM fuel cell at room temperature.
- Fig. 64 depicts the performance of various electrode supports in a Laccase/Pt black H 2 /O 2 PEM fuel cell at room temperature.
- Fig. 65 depicts the performance of a chitosan immobilized Laccase/Pt black H 2 /O 2 biocathode PEM fuel cell at room temperature.
- Fig. 66 is a schematic of the TBAB modified Nafion based electrode press package.
- Fig. 67A and 67B are Steps 1 and 2 of a chitosan immobilized enzyme electrode press package.
- Fig. 1 illustrates one embodiment of a fuel cell device of the present invention, designated in its entirety by the reference numeral 1.
- the device 1 is capable of generating electrical current which may be used to meet the power consumption demands of a load indicated at 5.
- the fuel cell device 1 may be used to power small handheld electronics.
- Fuel for operating the device 1 is provided from a suitable source 7 and is either consumed during use or discharged from the device 1 after use to a suitable waste destination (e.g., receptacle) 9.
- Fig. 2 illustrates the fuel cell device 1 of Fig. 1
- Fig. 3 is a separated view showing the various components of the device 1.
- the device comprises a fuel manifold 15 having a front side 21, a back side 23, an inlet 29 for flow of fuel fluid from the fuel source 7 into the manifold and an outlet 33 for flow of fuel fluid from the manifold to the waste destination 9.
- the manifold 15 comprises one or more fuel AKER 10002.1
- the fuel cell device also includes front and back anode assemblies generally designated 45 and 47, respectively, on opposite front and back sides 21, 23 of the manifold 15 for reacting with fuel in the fuel reservoir(s) 41, and front and back cathode assemblies generally indicated at 51 and 53, respectively, adjacent the front and back anode assemblies 45, 47.
- An electronic controller generally designated 71 (Fig. 14) is provided for controlling operation of the device, as will be described later.
- a supplemental power circuit, generally indicated at 81 (Fig. 15) is also included for providing power to supplement the normal output of the fuel cells, as needed.
- the components described above are contained in a housing, generally designated 91, so that the fuel cell device is self-contained as a relatively small, compact unit. Each of the above components is described in detail below.
- the fuel manifold 15 of the illustrated embodiment comprises a body or block 101 of suitable dielectric material (e.g., acrylic) having a top 105, a bottom 107, opposite ends 109, a front face 111 and a back face 115.
- the block 101 is formed (e.g., molded, machined, etc.) to have any suitable shape (e.g., rectangular or otherwise) and is preferably constructed from a single one-piece member. Alternatively, it may be constructed from a number of separate members affixed to one another to form a unitary structure.
- the fuel reservoirs 41 are defined by cavities (also designated 41) in the front and back faces 111, 115 of the block.
- each fuel reservoir 41 can contain from one cavity to up to 40 or more cavities depending on the design and the number of bio fuel cells needed in the assembly.
- Fuel enters each fuel reservoir 41 through an inlet port 121 at the top of the reservoir and exits the same reservoir through an outlet port 125 at the top of the reservoir.
- the top of each fuel reservoir 41 is stepped such that the inlet port 121 is in an inlet port surface 127 and the outlet port 125 is in an outlet port surface 129 spaced above the surface 127.
- the elevation of the outlet port 125 of each reservoir is higher than the elevation of the inlet port 121 of each reservoir.
- the vertical spacing between these two surfaces 127, 129 creates a chamber or space 131 having a height (e.g., 0.10 in.) suitable for holding any air bubbles which may become trapped in the fuel AKER 10002.1
- the fuel reservoirs 41 of the manifold 15 are connected by flow passages or conduits 135 which may, for example, comprise 1/8" x 1/8" polypropylene barbed elbows fitted into bores in the manifold.
- the fuel fluid flows sequentially (in series) from one fuel reservoir 41 of the series to the next fuel reservoir 41 of the series.
- fuel fluid flows from the inlet 29 of the manifold 15 into a first fuel reservoir 41 at the front side 21 of the manifold adjacent one end 109 of the manifold, then in sequence to the second, third and fourth reservoirs 41 at the front side (from left to right as viewed in Figs.
- a valve e.g., a check valve 141 is provided between the outlet port 125 of one reservoir 41 and the inlet port 121 of the next reservoir 41 of the series to prevent the back-flow of fuel from one reservoir 41 to another as fuel flows from the inlet 29 of the manifold 15, through the various fluid reservoirs 41 in sequence, to the outlet 33 of the manifold.
- the use of the check valves e.g., Poweraire valves
- the check valves 141 arranged in series there is one fuel input and output to fill all of the reservoirs 41.
- the fuel reservoirs 41 in the manifold 15 are arranged such that the fuel reservoirs on the back side 23 of the manifold are directly opposite the reservoirs at the front side 21 of the manifold.
- the manifold may have more than one inlet 29 and more than one outlet 33.
- one inlet and one outlet are provided to service the fuel reservoirs 41 at the front side 21 of the manifold, and a separate inlet and outlet are provided to service the fuel reservoirs 41 at the back side 23 of the manifold.
- the front anode assembly 45 includes a frame 151 comprising, in one embodiment, a pair of mating front and back frame members 15 IA, 15 IB.
- Each frame member 15 IA, 15 IB has a plurality of openings 155 in it configured and arranged to match the configuration and arrangement of fuel reservoirs 41 in the front AKER 10002.1
- the frame members may be of vinyl sheet material having a thickness of about 0.018 in. Other materials may also be used. Also, the frame 151 may have configurations different from that shown.
- the front anode assembly 45 also includes a number of anodes, each generally designated 157, held by the frame 151 in the frame openings 155, one anode per frame opening.
- each anode 157 comprises a current collector 161 secured in a respective frame opening 155.
- the current collector 161 comprises a wire mesh panel of nickel having a thickness of about 0.018 in.
- a suitable electrical lead 169 e.g., a 28-gauge conductor
- Each anode 157 also includes a gas diffusion layer 165 on the back face of the current collector 161 between the current collector and the back frame member 15 IB.
- this diffusion layer 165 may be a carbon paste structure as described in the Gas Diffusion Layer section below.
- a catalyst layer (not shown) is then added to the gas diffusion layer 165 by applying a cast mixture of enzyme in buffer solution and tetrabutylammonium-modified Nafion ® ionomer.
- the catalyst layer is allowed to dry before joining it to the anode assembly.
- the enzyme used in the catalyst layer is pyrroloquinoline quinone-dependent alcohol dehydrogenase (PQQ-ADH).
- Each anode 157 is sized slightly larger than a corresponding frame opening 155 so that the side edge margins of the anode extend beyond respective sides of the frame opening for overlapping portions of the frame members 151A, 151B.
- the anodes 157 are secured to the frame members by a front layer 175 of adhesive disposed between the front frame member 15 IA and the current collectors 161 of the anodes 157, and a back layer 181 of adhesive between the back frame member 15 IB and the diffusion layers 165 of the anodes 157.
- the front and back adhesive layers 175, 181 comprise a urethane hot melt adhesive film having a thickness of about 0.005 in., for example.
- the front and back adhesive layers 175, 181 are configured to have a size and shape corresponding to the size and shape of the front and back frame members 151A, 151B, respectively.
- the adhesive melts to secure the two frame members 15 IA, 15 IB, collectors 161 and diffusion layers 165 in fixed position relative to one another to form a unitary front anode structure.
- each anode 157 comprises a current collector 535 embedded within AKER 10002.1
- the current collector has a proximal end and a distal end and extends along a longitudinal axis.
- a conductive monolayer 537 in contact with the current collector 535 extends coaxially from the proximal end to the distal end of the current collector.
- a suitable electrical lead 169 is affixed to the collector 535.
- the self-supporting bioanode catalyst support does not include an embedded current collector 535.
- the conductive monolayer 537 is a mixture of a first electrically conductive material, a second electrically conductive material, and a binder, and can be fabricated as described in the S elf- Supporting Bioanode Catalyst Support Fabrication section below.
- a catalyst layer (not shown) is then applied to the surface of the monolayer 537 by the method described in the Conductive Polymer Based Nanowires section below.+
- catalyst particles containing an enzyme as described in the Encapsulated Enzyme Incorporation into Carbon Paste and Biocatalyst Ink Formulation sections below
- Each anode 157 is sized slightly larger than a corresponding frame opening 155 so that the side edge margins of the anode extend beyond respective sides of the frame opening for overlapping portions of the frame members 151A, 151B.
- the anodes 157 are secured to the frame members by a front layer 175 of adhesive disposed between the front frame member 15 IA and the monolayer 537 of the anodes 157, and a back layer 181 of adhesive between the back frame member 15 IB and the monolayer 537 of the anodes 157.
- the front and back adhesive layers 175, 181 comprise a urethane hot melt adhesive film having a thickness of about 0.005 in., for example.
- the front and back adhesive layers 175, 181 are configured to have a size and shape corresponding to the size and shape of the front and back frame members 15 IA, 15 IB, respectively.
- the adhesive melts to secure the two frame members 151A, 151B, and the monolayer 537 in fixed position relative to one another to form a unitary front anode structure.
- the front anode assembly 45 is secured to the front face 111 of the manifold 15 so that the frame openings 155 and anodes 157 are in general alignment with respective front fuel reservoirs 41, the arrangement being such that fuel fluid in each reservoir 41 is adapted to contact a respective anode 157 of the front anode assembly 45.
- the size and shape of the outline of each frame opening 155 approximates the size and shape of the corresponding fuel reservoir 45 so that substantially the entire area of AKER 10002.1
- the anode assembly 45 is secured in a sealing manner to the manifold 15 by a layer of adhesive (e.g., a layer of 0.005 in. thick hot melt urethane adhesive melted at 128 0 C) between the back face of the frame 151 and the front face 111 of the manifold 15.
- a layer of adhesive e.g., a layer of 0.005 in. thick hot melt urethane adhesive melted at 128 0 C
- a seal is provided which isolates each front fuel reservoir 41 and its respective anode 157 from each adjacent front fuel reservoir and its respective anode 157.
- the seal may be formed in other ways, as by the use of one or more gaskets.
- the back anode assembly 47 is preferably constructed in a manner substantially identical to the front anode assembly 45, and corresponding parts are identified by corresponding reference numbers.
- the back anode assembly 47 is positioned against the back face 115 of the manifold 15 with the frame openings 155 and anodes 157 in registration with the fuel reservoirs 41 at the back side 23 of the manifold.
- the back anode assembly 47 is secured in position with respect to the manifold 15 and in sealing engagement with the back face 115 of the manifold in the same manner described above in regard to the front anode assembly 45.
- the anode assembly described above generally comprises a nickel current collector, a carbon-based gas diffusion layer, a PQQ-dependent alcohol dehydrogenase enzyme and PQQ as the electron mediator.
- a person of skill in the art would know that these components could be replaced with various alternatives as described below.
- a system using direct electron transfer is described.
- the electron transfer is associated with, or occurs during, the catalytic transformation of the substrate to the product.
- the enzyme acts as an electrocatalyst and nanowires (tailored with appropriate surface functional groups) grafted on a first conductive material, such as carbon particles, facilitate the electron transfer between the enzyme, electron conductor (electrode), and the substrate molecule.
- this process involves no electron mediator.
- the nanowire increases the conductivity, but does not undergo reversible electron transfer, direct electron transfer is observed.
- a DET system usually offers more efficient electron transfer rates, because of operation in a potential range closer to the redox potential of the enzyme and the enzyme being less exposed to interfering reactions. Generally, the higher the integration/communication between the biomolecule and the AKER 10002.1
- the performance of a high power output biofuel cell system based on direct electron transfer depends upon aspects of the enzyme immobilization procedure.
- the nature of the electron conductor/support e.g., chemical nature of the surface functional groups, dimensions of the nanowires, and electrical and ionic conductivity properties of the nanowires
- the properties and the stability of the biomolecule e.g., immobilization technologies used to stabilize the enzyme
- the nanowires (tailored with appropriate surface functional groups) grafted on first conductive material have electron mediators grafted on the surface of the first conductive material. These electron mediators can undergo reversible electron transfer at the anode or cathode.
- the nanowire grafted particles can be used as a core for the immobilized enzyme coated particles described below.
- Electrodes Described below is a procedure for fabrication of custom bioanode and biocathode electron conductors (electrodes) for use in a biofuel cell.
- the bioanode catalyst support described herein is similar to the enzyme coated side of the biocathode, where a high surface area micro-porous structure is used for the enzyme immobilization and electrolyte/substrate incorporation.
- a schematic of the Bioanode Catalyst Support is shown in Figure 53.
- the first electrically conductive material e.g., carbon black
- the electron mediator or dopant e.g., by grafting doped conductive polymers onto its surface
- the catalyst support layer used for the anode electrodes is made from a mixture of carbon materials, binder, pore forming agents, solvents and optional catalyst such as enzymes.
- properties of the support structure can be altered to provide desirable performance for specific applications. For example, properties that can be varied include: (1) electronic conduction, (2) AKER 10002.1
- the mixture forming the support structure is initially made up as a paste and then pressed into a frame (e.g., MDS filled Nylon 6/6 frame (0.020" thick)) that is adhered to a polytetrafluoroethylene (PTFE) coated fiberglass temporary support (e.g., (0.020" thick)) with a double-sided pressure adhesive film (e.g., (0.002" thick)) for an electrode that does not have an embedded expanded metal current collector.
- a frame e.g., MDS filled Nylon 6/6 frame (0.020" thick)
- PTFE polytetrafluoroethylene
- an electrode with an embedded current collector support two frames (e.g., MDS filled Nylon 6/6 frames (0.010" thick)) with pressure adhesive film are fixed onto either face of a piece of expanded metal (e.g., (0.005" thick)) and the PTFE coated fiberglass temporary support is not needed. Excess paste material on the frame and on top is removed with a tool (e.g., painter's knife or a spatula). While the paste is still moist, the electrode structure is pressed at 2000 pounds for 15 seconds in a press package consisting of two steel plates (6" x 6" x 0.065"), two PTFE coated fiberglass sheets (4" x 4" x 0.005"), and two paper towels folded to fit. The electrode(s) are removed from the package and any excess paste material on the frame is removed with a painter's knife and a paper towel. The entire assembly is then sintered at temperature up to 200 0 C for up to 20 minutes, depending on the desired structure and formulation.
- a tool e.g., painter
- the electrode is removed from the frame(s) and temporary support and cooled between two aluminum blocks (12" x 12" x 1") until set, usually only a couple of minutes, prior to use in a biofuel cell.
- Conductivity measurements are made using a milliohm meter with the two points 1 cm separated. The measurements are reported relative to a commercial gas diffusion layer (GDL) material that was measured in the same fashion; the measurements are not a stated literature value where the conditions of the test and equipment are not known. The values are also given as approximations due to variances in the limited manual fabrication runs for each electrode type.
- GDL gas diffusion layer
- the catalyst layer can be applied to the catalyst support as described in the Encapsulated Enzyme Incorporation into Carbon Paste section below.
- catalyst particles containing an enzyme as described in the Encapsulated Enzyme Incorporation into Carbon Paste and Biocatalyst Ink Formulation sections below
- Electrodes and catalyst layers described herein A variety of acceptable components can be used to construct the electrodes and catalyst layers described herein.
- the following tables detail various carbon blacks, pore forming reagents, binder materials, and conductive carbon fibers and their suppliers. These materials can be used to prepare the electron conductors (electrodes) described herein.
- the carbon black materials are selected to affect the surface area of the electron conductor along with its electrical conductivity and electron transfer.
- the pore forming reagents are used to increase the surface area of the electron conductor (electrode) by forming pores within the structure and thus, increasing its surface area and the ability of substrate to diffuse to enzymes if present.
- the binder materials can be used to advantageously alter the hydrophobic/hydrophilic character of the electron conductor (electrode) to increase mass transport and also affect the structural integrity of the structure.
- the conductive carbon fibers can be selected to affect the conductivity along with affecting the structural integrity of the electron conductor (electrode).
- the bioanode in accordance with some embodiments of this invention comprises a current collector (e.g., current collector 161), a gas diffusion layer (or electron conductor)(e.g., gas diffusion layer 165), optionally an electron mediator, optionally an electrocatalyst for the electron mediator, and an enzyme that is immobilized in an enzyme immobilization material.
- a current collector e.g., current collector 161
- a gas diffusion layer e.g., gas diffusion layer 165
- an electron mediator optionally an electrocatalyst for the electron mediator
- an enzyme that is immobilized in an enzyme immobilization material optionally, these components are adjacent to one another, meaning they are physically or chemically connected by appropriate means.
- the current collector (e.g., 161) is a substance that conducts electrons and provides a lattice support for the gas diffusion layer and catalyst layer. Thus, materials that provide these functions can be used for the current collector. For various bioanode embodiments, a nickel or nickel containing material (i.e., Inconel) is preferred. When a PQQ-dependent alcohol dehydrogenase enzyme is used as the bioanode enzyme, the nickel ions generated from the slow dissolution of the current collector act as a promoter for the enzymatic reaction. AKER 10002.1
- the gas diffusion layer (or electron conductor)(e.g, 165) is a substance that conducts electrons.
- the gas diffusion layer can be an organic or inorganic material as long as it is able to conduct electrons through the material.
- the gas diffusion layer can be a carbon-based material, stainless steel, stainless steel mesh, a metallic conductor, a semiconductor, a metal oxide, a modified conductor, or combinations thereof.
- the gas diffusion layer is a carbon-based material.
- Particularly suitable gas diffusion layers are carbon-based materials.
- Exemplary carbon-based materials are carbon cloth, carbon paper, carbon screen printed electrodes, carbon paper (Toray), carbon paper (ELAT), carbon black (Vulcan XC-72, E- tek), carbon black, carbon powder, carbon fiber, single-walled carbon nanotubes, double- walled carbon nanotubes, multi-walled carbon nanotubes, carbon nanotubes arrays, diamond-coated conductors, glassy carbon, mesoporous carbon, and combinations thereof.
- carbon-based materials are graphite, uncompressed graphite worms, delaminated purified flake graphite (Superior® graphite), high performance graphite and carbon powders (Formula BTTM, Superior® graphite), highly ordered pyrolytic graphite, pyrolytic graphite, polycrystalline graphite, and combinations thereof.
- a preferred gas diffusion layer is a sheet of carbon cloth.
- the gas diffusion layer can be made of a metallic conductor.
- Suitable electron conductors can be prepared from gold, platinum, iron, nickel, copper, silver, stainless steel, mercury, tungsten, other metals suitable for electrode construction, and combinations thereof.
- gas diffusion layers which are metallic conductors can be constructed of nanoparticles made of cobalt, carbon, and other suitable metals.
- Other metallic electron conductors can be silver-plated nickel screen printed electrodes.
- the gas diffusion layer can be a semiconductor.
- Suitable semiconductor materials include silicon and germanium, which can be doped with other elements.
- the semiconductors can be doped with phosphorus, boron, gallium, arsenic, indium or antimony, or a combination thereof.
- the gas diffusion layer can be a metal oxide, metal sulfide, main group compound (i.e., transition metal compound), a material modified with an electron conductor, and combinations thereof.
- An exemplary gas diffusion layer of this type is nanoporous titanium oxide, tin oxide coated glass, cerium oxide particles, AKER 10002.1
- the gas diffusion layer comprises carbon black, mesoporous carbon, epoxy, and polytetrafluoroethylene.
- the gas diffusion layer comprises dry components of Monarch 1400 carbon black (Cabot) and Chemsorb 1505 G5 porous, impregnated steam activated carbon (C*Chem), and wet components of Quick Set 2 part epoxy (The Original Super Glue Corp.) dissolved in acetone and 60 % polytetrafluoroethylene (PTFE) dispersion in water (Sigma).
- the dry components are ground in a food grinder and the wet components are mixed with an ultra sonic homogenizer, then the dry and wet components are combined and mixed with a putty knife until the mixture has the consistency of toothpaste.
- the bioanode electron mediator serves to accept or donate electron(s), readily changing from oxidized to reduced forms.
- the electron mediator is a compound that can diffuse into the enzyme immobilization material and/or be incorporated into the immobilization material. It is preferred that the electron mediator's diffusion coefficient is maximized.
- Exemplary electron mediators are nicotinamide adenine dinucleotide (NAD + ), flavin adenine dinucleotide (FAD), nicotinamide adenine dinucleotide phosphate (NADP), pyrroloquinoline quinone (PQQ), equivalents of each, and combinations thereof.
- Other exemplary electron mediators are phenazine methosulfate, dichlorophenol indophenol, short chain ubiquinones, potassium ferricyanide, a protein, a metalloprotein, stellacyanin, and combinations thereof.
- the bioanode comprises an electrocatalyst for an electron mediator which facilitates the release of electrons at the electron conductor.
- an electron mediator that has a standard reduction potential of 0.0V ⁇ 0.5 V is used as the electron mediator.
- an electron mediator that provides reversible electrochemistry on the electron conductor surface can be used. This electron mediator is AKER 10002.1
- the electrocatalyst is a substance that facilitates the release of electrons at the electron conductor. Stated another way, the electrocatalyst improves the kinetics of a reduction or oxidation of an electron mediator so the electron mediator reduction or oxidation can occur at a lower standard reduction potential.
- the electrocatalyst can be reversibly oxidized at the bioanode to produce electrons and thus, electricity.
- the electrocatalyst is adjacent to the electron conductor, the electrocatalyst and electron conductor are in electrical contact with each other, but not necessarily in physical contact with each other.
- the electron conductor is part of, associates with, or is adjacent to an electrocatalyst for an electron mediator.
- the electrocatalyst can be an azine, a conducting polymer or an electroactive polymer.
- Exemplary electrocatalysts are methylene green, methylene blue, luminol, nitro-fluorenone derivatives, azines, osmium phenanthrolinedione, catechol- pendant terpyridine, toluene blue, cresyl blue, nile blue, neutral red, phenazine derivatives, tionin, azure A, azure B, toluidine blue O, acetophenone, metallophthalocyanines, nile blue A, modified transition metal ligands, l,10-phenanthroline-5,6-dione, 1,10-phenanthroline- 5,6-diol, [Re(phen-dione)(CO)3Cl], [Re(phen-dione)3](PF 6 )2, poly(metallophthalocyanine), poly(thionine), poly(thi
- An enzyme catalyzes the oxidation of the fuel fluid at the bioanode.
- modified naturally-occurring enzymes can be utilized.
- engineered enzymes that have been engineered by natural or directed evolution can be used.
- an organic or inorganic molecule that mimics an enzyme's properties can be used in an embodiment of the present invention.
- exemplary enzymes for use in a bioanode are oxidoreductases.
- the oxidoreductases act on the CH-OH group or CH-NH group of the fuel (alcohols, ammonia compounds, carbohydrates, aldehydes, ketones, hydrocarbons, fatty acids and the like).
- the enzyme is a dehydrogenase.
- exemplary enzymes include alcohol dehydrogenase, aldehyde dehydrogenase, formate dehydrogenase, formaldehyde dehydrogenase, glucose dehydrogenase, glucose oxidase, lactatic dehydrogenase, lactose dehydrogenase, pyruvate dehydrogenase, or lipoxygenase.
- the enzyme is an alcohol dehydrogenase (ADH).
- the enzyme(s) selected for use in the bioanode are suitable for maximizing the energy density of a particular fuel fluid.
- hydrogen fuel requires one enzyme
- methanol requires three.
- the enzymes of Krebs cycle can be used.
- aconitase fumarase, malate dehydrogenase, succinate dehydrogenase, succinyl-CoA synthetase, isocitrate dehydrogenase, ketoglutarate dehydrogenase, citrate synthase and combinations thereof can be used in the bioanode.
- the enzyme is a PQQ-dependent alcohol dehydrogenase.
- PQQ is the coenzyme of PQQ-dependent ADH and remains electrostatically attached to PQQ-dependent ADH and therefore the enzyme will remain in the enzyme immobilization material leading to an increased lifetime and activity for the biofuel cell.
- the PQQ-dependent alcohol dehydrogenase enzyme is extracted from gluconobacter. When extracting the PQQ-dependent ADH, it can be in two forms: (1) the PQQ is electrostatically bound to the PQQ-dependent ADH or (2) the PQQ is not electrostatically bound the PQQ-dependent ADH.
- PQQ is added to the ADH upon assembly of the bioanode.
- the PQQ-dependent ADH is extracted from gluconobacter with the PQQ electrostatically bound.
- An enzyme or organelle immobilization material can be used to immobilize and stabilize enzymes or organelles. This discussion of immobilization materials applies to enzyme immobilization materials as well as organelle immobilization materials.
- the enzyme immobilization material is permeable to a compound smaller than the enzyme so the desired reaction can be catalyzed by the immobilized enzyme.
- an enzyme is used to catalyze various reactions and this enzyme is immobilized in an enzyme immobilization material that both immobilizes and stabilizes the enzyme.
- the enzyme immobilization material provides a chemical and mechanical barrier to prevent or impede enzyme denaturation.
- the enzyme immobilization material physically confines the enzyme, preventing the enzyme from unfolding.
- the process of unfolding an enzyme from a folded three-dimensional structure is one mechanism of enzyme denaturation.
- a free enzyme in solution loses its catalytic activity within a few hours to a few days, whereas a properly immobilized and stabilized enzyme of this invention can retain its catalytic activity for at least about 7 days to about 730 days or more.
- the retention of catalytic activity is defined by the number of days that the enzyme retains at least about 75% of its initial activity while continually catalyzing a chemical transformation.
- the enzyme activity can be measured by chemiluminescence, electrochemical, UV-Vis, radiochemical or fluorescence assay wherein the intensity of the property is measured at an initial time.
- a fluorescence assay is used to measure the enzyme activity.
- a stabilized enzyme of the invention retains at least about 75% of its initial activity while the enzyme is continually catalyzing a chemical transformation for at least about 7 days to about 730 days.
- the immobilized and stabilized enzyme retains at least about 75% of its initial catalytic activity for at least about 30, 45, 60, 75, 90, 105, 120, 150, 180, 210, 240, 270, 300, 330, 365, 400, 450, 500, 550, 600, 650, 700, 730 days or more, preferably retaining at least about 80%, 85%, 90%, 95% or more of its initial catalytic activity for at least about 5, 10, 15, 20, 25, 30, 45, 60, 75, 90, 105, 120, 150, 180, 210, 240, 270, 300, 330, 365, 400, 450, 500, 550, 600, 650, 700, 730 days or more.
- an enzyme is "stabilized" (for use in a bioanode or biocathode of a biofuel cell or other uses wherein relatively long periods of AKER 10002.1
- catalytic activity are needed) if it retains at least about 75% of its initial catalytic activity for at least about 30 days to about 730 days or more when actively catalyzing a chemical transformation.
- the enzyme after immobilization in the enzyme immobilization material, retains at least about 0.65, 0.7, 0.75, 0.8, 0.85, 0.9, 0.95, or more, of its activity relative to the activity of the enzyme before immobilization.
- An immobilized enzyme is an enzyme that is physically confined in a certain region of the enzyme immobilization material while retaining its catalytic activity.
- There are a variety of methods for enzyme immobilization including carrier-binding, cross-linking and entrapping.
- Carrier-binding is the binding of enzymes to water-insoluble carriers.
- Cross-linking is the intermolecular cross-linking of enzymes by bifunctional or multifunctional reagents.
- Entrapping is incorporating enzymes into the lattices of a semipermeable material.
- the particular method of enzyme immobilization is not critically important, so long as the enzyme immobilization material (1) immobilizes the enzyme, and (2) stabilizes the enzyme.
- the enzyme immobilization material is also permeable to a compound smaller than the enzyme.
- An immobilized organelle is an organelle that is physically confined in a certain region of the immobilization material while retaining its catalytic activity.
- the immobilization material allows the movement of a substrate, fuel fluid, or oxidant compound through it so the compound can contact the enzyme or organelle.
- the immobilization material can be prepared in a manner such that it contains internal pores, channels, openings or a combination thereof, which allow the movement of the compound throughout the immobilization material, but which constrain the enzyme or organelle to substantially the same space within the immobilization material. Such constraint allows the enzyme or organelle to retain its catalytic activity.
- the enzyme or organelle is confined to a space that is substantially the same size and shape as the enzyme or organelle, wherein the enzyme or organelle retains substantially all of its catalytic activity.
- the pores, channels, or openings have physical dimensions that satisfy the above requirements and depend on the size and shape of the specific enzyme or organelle to be immobilized.
- the enzyme or organelle is entrapped within the openings of an immobilization material and contacted with nanowires grafted to a first conductive material such as carbon black particles.
- the nanowires comprise a polymeric material, an oxide, an organometallic material, or a metallic material. Such materials are discussed above in the DET section and in the Conductive Polymer Based Nanowires section below.
- the enzyme or organelle is preferably located within a pore of the immobilization material and the compound travels in and out of the immobilization material through transport channels.
- the relative size of the pores and transport channels can be such that a pore is large enough to immobilize an enzyme or organelle, but the transport channels are too small for the enzyme or organelle to travel through them.
- a transport channel preferably has a diameter of at least about 10 nm.
- the pore diameter to transport channel diameter ratio is at least about 2: 1, 2.5: 1, 3: 1, 3.5: 1, 4: 1, 4.5: 1, 5: 1, 5.5: 1, 6: 1, 6.5: 1, 7: 1, 7.5: 1, 8: 1, 8.5: 1, 9: 1, 9.5: 1, 10: 1 or more.
- a transport channel has a diameter of at least about 2 nm and the pore diameter to transport channel diameter ratio is at least about 2: 1, 2.5: 1, 3: 1, 3.5: 1, 4: 1, 4.5: 1, 5: 1, 5.5: 1, 6: 1, 6.5: 1, 7: 1, 7.5: 1, 8: 1, 8.5: 1, 9: 1, 9.5: 1, 10: 1 or more.
- the immobilization material has a micellar or inverted micellar structure.
- the molecules making up a micelle are amphipathic, meaning they contain a polar, hydrophilic group and a nonpolar, hydrophobic group.
- the molecules can aggregate to form a micelle, where the polar groups are on the surface of the aggregate and the hydrophobic, nonpolar groups are sequestered inside the aggregate.
- Inverted micelles have the opposite orientation of polar groups and nonpolar groups.
- the amphipathic molecules making up the aggregate can be arranged in a variety of ways so long as the polar groups are in proximity to each other and the nonpolar groups are in proximity to each other.
- the molecules can form a bilayer with the nonpolar groups pointing toward each other and the polar groups pointing away from each other.
- a bilayer can form wherein the polar groups can point toward each other in the bilayer, while the nonpolar groups point away from each other.
- the micellar immobilization material is a modified perfluoro sulfonic acid-PTFE copolymer (or modified perfluorinated ion exchange polymer)(modified Nafion® or modified Flemion®) membrane.
- the AKER 10002.1 is a modified perfluoro sulfonic acid-PTFE copolymer (or modified perfluorinated ion exchange polymer)(modified Nafion® or modified Flemion®) membrane.
- perfluorinated ion exchange polymer membrane is modified with a hydrophobic cation that is larger than the ammonium (NH 4 + ) ion.
- the hydrophobic cation serves the dual function of (1) dictating the membrane's pore size and (2) acting as a chemical buffer to help maintain the pore's pH level, both of which stabilize the enzyme.
- the properties of the perfluoro sulfonic acid-PTFE copolymer (or perfluorinated ion exchange polymer) membrane are altered by exchanging the hydrophobic cation for protons as the counterion to the -SO 3 " groups on the perfluoro sulfonic acid-PTFE copolymer (or anions on the perfluorinated ion exchange polymer) membrane.
- This change in counterion provides a buffering effect on the pH because the hydrophobic cation has a much greater affinity for the -SO3 " sites than protons do.
- This buffering effect of the membrane causes the pH of the pore to remain substantially unchanged with changing solution pH; stated another way, the pH of the pore resists changes in the solution's pH.
- the membrane provides a mechanical barrier, which further protects the immobilized enzymes or organelles.
- the first step is to cast a suspension of perfluoro sulfonic acid-PTFE copolymer (or perfluorinated ion exchange polymer), particularly Nafion®, with a solution of the hydrophobic cations to form a membrane.
- the excess hydrophobic cations and their salts are then extracted from the membrane, and the membrane is re-cast.
- the membrane Upon re-casting, the membrane contains the hydrophobic cations in association with the -SO 3 " sites of the perfluoro sulfonic acid-PTFE copolymer (or perfluorinated ion exchange polymer) membrane. Removal of the salts of the hydrophobic cation from the membrane results in a more stable and reproducible membrane; if they are AKER 10002.1
- the excess salts can become trapped in the pore or cause voids in the membrane.
- a modified Nafion® membrane is prepared by casting a suspension of Nafion® polymer with a solution of a salt of a hydrophobic cation such as quaternary ammonium bromide. Excess quaternary ammonium bromide or hydrogen bromide is removed from the membrane before it is re-cast to form the salt-extracted membrane. Salt extraction of membranes retains the presence of the quaternary ammonium cations at the sulfonic acid exchange sites, but eliminates complications from excess salt that may be trapped in the pore or may cause voids in the equilibrated membrane.
- a salt of a hydrophobic cation such as quaternary ammonium bromide
- hydrophobic cations are ammonium-based cations, quaternary ammonium cations, alkyltrimethylammonium cations, alkyltriethylammonium cations, organic cations, phosphonium cations, triphenylphosphonium, pyridinium cations, imidazolium cations, hexadecylpyridinium, ethidium, viologens, methyl viologen, benzyl viologen, bis(triphenylphosphine)iminium, metal complexes, bipyridyl metal complexes, phenanthroline-based metal complexes, [Ru(bipyridine)3] 2+ and [Fe(phenanthroline)3] 3+ .
- the hydrophobic cations are ammonium- based cations.
- the hydrophobic cations are quaternary ammonium cations.
- the quaternary ammonium cations are represented by Formula 1 :
- R 1 , R 2 , R3, and R 4 are independently hydrogen, hydrocarbyl, substituted hydrocarbyl, or heterocyclo wherein at least one of Ri, R 2 , R3, and R 4 is other than hydrogen.
- R 1 , R 2 , R3, and R 4 are independently hydrogen, methyl, ethyl, propyl, butyl, pentyl, hexyl, heptyl, octyl, nonyl, decyl, undecyl, dodecyl, tridecyl or tetradecyl wherein at least one of Ri, R 2 , R3, and R 4 is other than hydrogen.
- R 1 , R 2 , R 3 , and R 4 are the same and are methyl, ethyl, propyl, butyl, pentyl or hexyl. In yet another embodiment, preferably, R 1 , R 2 , R 3 , and R 4 are butyl.
- the quaternary ammonium cation is tetrapropylammonium AKER 10002.1
- T3A tetrapentylammonium (T5A), tetrahexylammonium (T6A), tetraheptylammonium (T7A), trimethylicosylammonium (TMICA), trimethyloctyldecylammonium (TMODA), trimethylhexyldecylammonium (TMHDA), trimethyltetradecylammonium (TMTDA), trimethyloctylammonium (TMOA), trimethyldodecylammonium (TMDDA), trimethyldecylammonium (TMDA), trimethylhexylammonium (TMHA), tetrabutylammonium (TBA), triethylhexylammonium (TEHA), and combinations thereof.
- TMICA trimethyloctyldecylammonium
- THDA trimethylhexyldecylammonium
- TTDDA trimethyltetradecy
- micellar or inverted micellar immobilization materials are hydrophobically modified polysaccharides, these polysaccharides are selected from chitosan, cellulose, chitin, starch, amylose, alginate, glycogen, and combinations thereof.
- the micellar or inverted micellar immobilization materials are polycationic polymers, particularly, hydrophobically modified chitosan.
- Chitosan is a poly[ ⁇ -(l-4)-2-amino-2-deoxy-D-glucopyranose].
- Chitosan is typically prepared by deacetylation of chitin (a poly[ ⁇ -(l-4)-2-acetamido-2- deoxy-D-glucopyranose]).
- chitin a poly[ ⁇ -(l-4)-2-acetamido-2- deoxy-D-glucopyranose]
- the typical commercial chitosan has approximately 85% deacetylation.
- deacetylated or free amine groups can be further functionalized with hydrocarbyl, particularly, alkyl groups.
- the micellar hydrophobically modified chitosan corresponds to the structure of Formula 2
- n is an integer
- Ri 0 is independently hydrogen, hydrocarbyl, substituted hydrocarbyl, or a hydrophobic redox mediator
- Rn is independently hydrogen, hydrocarbyl, substituted hydrocarbyl, or a hydrophobic redox mediator.
- n is an integer that gives the polymer a molecular weight of from about 21,000 to about 500,000; preferably, from about 90,000 to about 500,000; more preferably, from about 150,000 to about 350,000; more preferably, from about 225,000 to about 275,000.
- Rio is independently hydrogen or alkyl and Rn is independently hydrogen or alkyl.
- Ri 0 is independently hydrogen or hexyl and Rn AKER 10002.1
- Rio is independently hydrogen or octyl and Rn is independently hydrogen or octyl.
- micellar hydrophobically modified chitosan is a micellar hydrophobic redox mediator modified chitosan corresponding to Formula 2A
- Ri Oa is independently hydrogen, or a hydrophobic redox mediator
- Rii a is independently hydrogen, or a hydrophobic redox mediator
- micellar hydrophobically modified chitosan is a modified chitosan or redox mediator modified chitosan corresponding to Formula 2B
- Rn, R 12 , and n are defined as in connection with Formula 2.
- Rn and R 12 are independently hydrogen or straight or branched alkyl; preferably, hydrogen, butyl, pentyl, hexyl, heptyl, octyl, nonyl, decyl, undecyl, or dodecyl.
- Rn and R 12 are independently hydrogen, butyl, or hexyl.
- the micellar hydrophobically modified chitosans can be modified with hydrophobic groups to varying degrees.
- the degree of hydrophobic modification is determined by the percentage of free amine groups that are modified with hydrophobic groups as compared to the number of free amine groups in the unmodified chitosan.
- the degree of hydrophobic modification can be estimated from an acid-base titration and/or nuclear magnetic resonance (NMR), particularly 1 H NMR, data.
- NMR nuclear magnetic resonance
- This degree of hydrophobic modification can vary widely and is at least about 1, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 25, 30, 32, 24, 26, 28, 40, 42, 44, 46, 48%, or more.
- the degree of hydrophobic modification is from about 10% to about 45%; from about 10% to about 35%; from about 20% to about 35%; or from about 30% to about 35%.
- the hydrophobic redox mediator of Formula 2A is a transition metal complex of osmium, ruthenium, iron, nickel, rhodium, rhenium, or cobalt with 1,10-phenanthroline (phen), 2,2'-bipyridine (bpy) or 2,2',2"- terpyridine (terpy), methylene green, methylene blue, poly(methylene green), poly(methylene blue), luminol, nitro-fluorenone derivatives, azines, osmium phenanthrolinedione, catechol-pendant terpyridine, toluene blue, cresyl blue, nile blue, neutral red, phenazine derivatives, tionin, azure A, azure B, toluidine blue O, acetophenone, metallophthalocyanines, nile blue A, modified transition metal ligands, l,10-phenanthroline-5,6
- the hydrophobic redox mediator is Ru(phen) 3 +2 , Fe(phen) 3 +2 , Os(phen) 3 +2 , Co(phen) 3 +2 , Cr(phen) 3 +2 , Ru(bpy) 3 +2 , Os(bpy) 3 +2 , Fe(bpy) 3 +2 , Co(bpy) 3 +2 , Cr(bpy) 3 +2 ,Os(terpy) 3 +2 , Ru(bpy) 2 (4-methyl-4'-(6-hexyl)-2,2'-bipyridine) +2 , Co(bpy) 2 (4- methyl-4'-(6-hexyl)-2,2'-bipyridine) +2 , Cr(bpy)2(4-methyl-4'-(6-hexyl)-2,2'-bipyridine) +2 , Fe(bpy) 2 (4-methyl-4'-(6-hexyl) 2,2
- the hydrophobic redox mediator is Ru(bpy) 2 (4-methyl-4'-(6-hexyl)-2,2'-bipyridine) +2 , Co(bpy) 2 (4-methyl-4'-(6-hexyl)-2,2'- bipyridine) +2 , Cr(bpy) 2 (4-methyl-4'-(6-hexyl)-2,2'-bipyridine) +2 , Fe(bpy) 2 (4-methyl-4'-(6- hexyl)-2,2'-bipyridine) +2 , Os(bpy) 2 (4-methyl-4'-(6-hexyl)-2,2'-bipyridine) +2 , or combinations thereof.
- the hydrophobic redox mediator is Ru(bpy) 2 (4-methyl-4'-(6-hexyl)-2,2'-bipyridine) +2 .
- the hydrophobic redox mediator is typically covalently bonded to the chitosan or polysaccharide backbone.
- the hydrophobic redox mediator is covalently bonded to one of the amine functionalities of the chitosan through a -N-C- bond.
- the metal complex is attached to the chitosan through an -N-C- bond from a chitosan amine group to an alkyl group attached to one or more of the ligands of the metal complex.
- a structure corresponding to Formula 2C is an example of a metal complex attached to a chitosan
- n is an integer
- Ri Oc is independently hydrogen or a structure corresponding to Formula 2D
- R 1 lc is independently hydrogen or a structure corresponding to Formula ID
- m is an integer from 0 to 10
- M is Ru, Os, Fe, Cr, or Co
- heterocycle is bipyridyl, substituted bipyridyl, phenanthroline, acetylacetone, and combinations thereof.
- the hydrophobic group used to modify chitosan serves the dual function of (1) dictating the immobilization material's pore size and (2) modifying the chitosan' s electronic environment to maintain an acceptable pore environment, both of which stabilize AKER 10002.1
- hydrophobically modifying chitosan produces an immobilization material wherein the pore size is dependent on the size of the hydrophobic group. Accordingly, the size, shape, and extent of the modification of the chitosan with the hydrophobic group affects the size and shape of the pore.
- This function of the hydrophobic group allows the pore size to be made larger or smaller or a different shape to fit a specific enzyme or organelle by varying the size and branching of the hydrophobic group.
- the properties of the hydrophobically modified chitosan membranes are altered by modifying chitosan with hydrophobic groups.
- This hydrophobic modification of chitosan affects the pore environment by increasing the number of available exchange sites to proton.
- the hydrophobic modification of chitosan provides a membrane that is a mechanical barrier, which further protects the immobilized enzymes.
- Table 5 shows the number of available exchange sites to proton for the hydrophobically modified chitosan membrane. Table 5: Number of available exchange sites to proton per gram of chitosan polymer
- polycationic polymers are capable of immobilizing enzymes or organelle and increasing the activity of enzymes immobilized therein as compared to the activity of the same enzyme or organelle in a buffer solution.
- the polycationic polymers are hydrophobically modified polysaccharides, particularly, hydrophobically modified chitosan.
- the enzyme activities for glucose oxidase were measured. The highest enzyme activity was observed for glucose oxidase in a hexyl modified chitosan suspended in t-amyl alcohol.
- a chitosan gel was suspended in acetic acid followed by addition of an alcohol solvent.
- an aldehyde e.g., butanal, hexanal, octanal, or decanal
- sodium cyanoborohydride e.g., butanal, hexanal, octanal, or decanal
- the resulting product was separated by vacuum filtration and washed with an alcohol solvent.
- the modified chitosan was then dried in a vacuum oven at 40 0 C and resulted in a flaky white solid.
- the derivatized redox mediator (Ru(bipyridine) 2 (4-methyl-4'-(6-bromohexyl)-2,2'-bipyridine) +2 ) was then contacted with deacetylated chitosan and heated. The redox mediator modified chitosan was then precipitated and recrystallized.
- the hydrophobically modified chitosan membranes have advantageous insolubility in ethanol.
- the chitosan enzyme immobilization materials described above generally are functional to immobilize and stabilize the enzymes in solutions having up to about 99 wt.% or 99 volume% ethanol.
- the chitosan immobilization material is functional in solutions having 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95 or more wt.% or volume% ethanol.
- the micellar or inverted micellar immobilization materials are polyanionic polymers, such as hydrophobically modified polysaccharides, particularly, hydrophobically modified alginate.
- Alginates are linear unbranched polymers containing ⁇ -(l-4)-linked D-mannuronic acid and ⁇ -(l-4)-linked L-guluronic acid residues. In the unprotonated form, ⁇ -(l-4)-linked D-mannuronic acid corresponds to the structure of Formula 3A
- ⁇ -(l-4)-linked L-guluronic acid corresponds to the structure of Formula 3 B
- Alginate is a heterogeneous polymer consisting of polymer blocks of mannuronic acid residues and polymer blocks of guluronic acid residues.
- Alginate polymers can be modified in various ways.
- One type is alginate modified with a hydrophobic cation that is larger than the ammonium (NH 4 + ) ion.
- the hydrophobic cation serves the dual function of (1) dictating the polymer's pore size and (2) acting as a chemical buffer to help maintain the pore's pH level, both of which stabilize the enzyme or organelle.
- modifying alginate with a hydrophobic cation produces an immobilization material wherein the pore size is dependent on the size of the hydrophobic cation.
- the size, shape, and extent of the modification of the alginate with the hydrophobic cation affects the size and shape of the pore.
- This function of the hydrophobic cation allows the pore size to be made larger or smaller or a different shape to fit a specific enzyme or organelle by varying the size and branching of the hydrophobic cation.
- the properties of the alginate polymer are altered by exchanging the hydrophobic cation for protons as the counterion to the -C(V groups on the alginate.
- This change in counterion provides a buffering effect on the pH because the hydrophobic cation has a much greater affinity for the -CO 2 sites than protons do.
- This buffering effect of the alginate membrane causes the pH of the pore to remain substantially unchanged with changing solution pH; stated another way, the pH of the pore resists changes in the solution's pH.
- the alginate membrane provides a mechanical barrier, which further protects the immobilized enzymes or organelles.
- the first step is to cast a suspension of alginate polymer with a solution of the hydrophobic cation to form a membrane.
- the excess hydrophobic cations and their salts are then extracted from the membrane, and the membrane is re-cast.
- the membrane Upon re-casting, the membrane contains the hydrophobic cations in association with -CO 2 sites of the alginate membrane. Removal of the salts of the hydrophobic cation from the membrane results in a more stable and reproducible membrane; if they are not removed, the excess salts can become trapped in the pore or cause voids in the membrane.
- a modified alginate membrane is prepared by casting a suspension of alginate polymer with a solution of a salt of a hydrophobic cation such as quaternary ammonium bromide. Excess quaternary ammonium bromide or hydrogen AKER 10002.1
- bromide are removed from the membrane before it is re-cast to form the salt-extracted membrane.
- Salt extraction of membranes retains the presence of the quaternary ammonium cations at the carboxylic acid exchange sites, but eliminates complications from excess salt that may be trapped in the pore or may cause voids in the equilibrated membrane.
- Exemplary hydrophobic cations are ammonium-based cations, quaternary ammonium cations, alkyltrimethylammonium cations, alkyltriethylammonium cations, organic cations, phosphonium cations, triphenylphosphonium, pyridinium cations, imidazolium cations, hexadecylpyridinium, ethidium, viologens, methyl viologen, benzyl viologen, bis(triphenylphosphine)iminium, metal complexes, bipyridyl metal complexes, phenanthroline-based metal complexes, [Ru(bipyridine) 3 ] 2+ and [Fe(phenanthroline) 3 ] 3+ .
- the hydrophobic cations are ammonium- based cations.
- the hydrophobic cations are quaternary ammonium cations.
- the quaternary ammonium cations are represented by Formula 4:
- R 1 , R 2 , R3, and R 4 are independently hydrogen, hydrocarbyl, substituted hydrocarbyl, or heterocyclo wherein at least one of Ri, R 2 , R3, and R 4 is other than hydrogen.
- R 1 , R 2 , R 3 , and R 4 are independently hydrogen, methyl, ethyl, propyl, butyl, pentyl, hexyl, heptyl, octyl, nonyl, decyl, undecyl, dodecyl, tridecyl or tetradecyl wherein at least one of Ri, R 2 , R3, and R 4 is other than hydrogen.
- R 1 , R 2 , R 3 , and R 4 are the same and are methyl, ethyl, propyl, butyl, pentyl or hexyl. In yet another embodiment, preferably, R 1 , R 2 , R 3 , and R 4 are butyl.
- the quaternary ammonium cation is tetrapropylammonium (T3A), tetrapentylammonium (T5A), tetrahexylammonium (T6A), tetraheptylammonium (T7A), trimethylicosylammonium (TMICA), trimethyloctyldecylammonium (TMODA), trimethylhexyldecylammonium (TMHDA), trimethyltetradecylammonium (TMTDA) , trimethyloctylammonium (TMOA), trimethyldodecylammonium (TMDDA), trimethyldecylammonium (TMDA), trimethylhexylammonium (TMHA), tetrabutylammonium (TBA), triethylhexylammonium (TEHA), and combinations thereof.
- T3A tetrapropylammonium
- T5A te
- the hydrophobically modified alginate membranes have advantageous insolubility in ethanol.
- the alginate enzyme immobilization materials described above generally are functional to immobilize and stabilize the enzymes in solutions having at least about 25 wt.% or 25 volume% ethanol.
- the alginate immobilization material is functional in solutions having 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90 or more wt.% or volume% ethanol.
- the selected enzyme or organelle can be immobilized in various immobilization materials, deposited on an electron conductor, and treated with a solution containing an electron mediator (e.g., NAD + ) and/or a substrate for the particular enzyme in a buffer solution.
- a fluorescence micrograph is obtained and shows fluorescence when the enzyme or organelle immobilized in the particular immobilization material is still a catalytically active enzyme after immobilization. This is one way to determine whether a particular immobilization material will immobilize and stabilize an enzyme or organelle while retaining the enzyme's or organelle's catalytic activity.
- the enzyme immobilization material that provided the greatest relative activity is provided by immobilization of the enzyme in butyl chitosan suspended in t-amyl alcohol.
- the greatest relative activity is provided by immobilization of the enzyme in medium molecular weight decyl modified chitosan.
- the front cathode assembly 51 at the front side 21 of the manifold 15 is constructed in a manner similar to the front anode assembly 45. That is, the assembly 51 includes a similar frame, generally designated 201, comprising a pair of mating frame members 20 IA, 20 IB having openings 205, and a number of cathodes, each generally designated 207, held by the frame 201 in the frame openings 205, one cathode per frame opening.
- each cathode 207 comprises a current collector 211.
- the current collector 211 comprises a wire mesh panel of gold- plated stainless steel having a thickness of about 0.018 in.
- a suitable electrical lead 213 e.g., a 28-gauge conductor
- the cathode 207 also includes a layered catalyst structure, generally designated 225, on the back face of the current collector 211. This layered catalyst structure comprises a gas diffusion layer, a catalyst layer, and a polyelectrolyte membrane (Nafion ® ).
- the cathode gas diffusion layer comprises dry components of Monarch 1400 carbon black (Cabot) and Chemsorb 1505 G5 porous, impregnated steam activated carbon (C*Chem), and wet components of Quick Set 2 part epoxy (The Original Super Glue Corp.) dissolved in acetone and 60 % polytetrafluoroethylene (PTFE) dispersion in water (Sigma).
- the dry components are ground in a food grinder and the wet components are mixed with an ultra sonic homogenizer, then the dry and wet components are combined and mixed with a putty knife until the mixture has the consistency of toothpaste.
- the gas diffusion layer and catalyst layer need not be distinct layers, but can be combined.
- this layered catalyst structure is affixed to the back face of the current collector 211.
- the catalyst layered structure is prepared by applying an ink comprising a platinum black catalyst and Nafion ® ionomer to one side of the gas diffusion layer (e.g., E-T ek as LT2500W Low Temperature Elat with microporous layer on either side).
- the ink comprising the catalyst has dried, the catalyst layered structure is assembled by placing the gas diffusion layer on top of the current collector with platinum black catalyst side up, then placing the polyelectrolyte membrane (e.g., Nafion ® ) on top of the gas diffusion and catalyst layers.
- the polyelectrolyte membrane e.g., Nafion ® ionomer
- the polyelectrolyte membrane is impermeable to the fuel fluid, but is able to conduct electrons and protons.
- Each cathode 201 is sized slightly larger than a corresponding frame opening 205 so that the side edge margins of the cathode extend beyond respective sides of the frame opening for overlapping portions of the frame members 201A, 201B.
- the cathodes 201 are secured to the frame members by a front layer 275 of adhesive disposed between the front frame member 20 IA and the current collectors 211 of the cathodes 201, and a back layer 277 of adhesive between the back frame member 20 IB and the layered catalyst structure 225 of the cathodes 201.
- the front and back adhesive layers 275, 277 comprise a urethane hot melt adhesive film having a thickness of about 0.0005 in., for example.
- the front and back adhesive layers 275, 277 are configured to have a size and shape corresponding to the size and shape of the front and back frame members 20 IA, 20 IB, respectively.
- the adhesive melts to secure the two frame members 20 IA, 20 IB, collectors 211 and catalyst structures 225 in fixed position relative to one another to form a unitary front cathode structure.
- each cathode 207 comprises a current collector 525 embedded within the cathode.
- the current collector has a proximal end and a distal end and extends along a longitudinal axis.
- a conductive monolayer 527 in contact with the current collector 525 extends coaxially from the proximal end to the distal end of the current collector.
- a suitable electrical lead 213 is affixed to the collector 525.
- the self-supporting biocathode catalyst support does not include an embedded current collector 525.
- the conductive monolayer 527 is a mixture of a first electrically conductive material, a second electrically conductive material, and a binder, and can be fabricated as described in the Self-Supporting Biocathode Catalyst Support Fabrication section below.
- a side of the conductive monolayer 527 functions as a hydrophobic air breathing portion of a biocathode.
- a catalyst layer containing enzymes (not shown) is then applied to an opposite side of the monolayer 527 by the method described in the Conductive Polymer Based Nanowires section below.
- the resulting biocathode includes a hydrophobic air breathing side on one face of the current collector 525, and an enzyme containing side on the back face of the collector 525.
- catalyst particles containing an enzyme as described in the Encapsulated Enzyme Incorporation into Carbon Paste section below
- Each cathode 201 is sized slightly larger than a corresponding frame opening 205 so that the side edge margins of the cathode extend beyond respective sides of the frame opening for overlapping portions of the frame members 20 IA, 20 IB.
- the cathodes 201 are secured to the frame members by a front layer 275 of adhesive disposed between the front frame member 20 IA and a side of the monolayer 527 of the cathodes 201, and a back layer 277 of adhesive between the back frame member 201B and the opposite side of the monolayer 527 of the cathodes 201.
- the front and back adhesive layers 275, 277 comprise a urethane hot melt adhesive film having a thickness of about 0.0005 in., for example.
- the front and back adhesive layers 275, 277 are configured to have a size and shape corresponding to the size and shape of the front and back frame members 20 IA, 20 IB, respectively.
- the adhesive melts to secure the two frame members 20 IA, 20 IB, collectors 525 and monolayer 527 in fixed position relative to one another to form a unitary front cathode structure.
- the front cathode assembly 51 is secured in fixed position with respect to the front anode assembly 45 and the manifold 15 so that the anodes 157 and cathodes 207 are in general alignment with one another and with respective fuel reservoirs 41 at the front side 21 of the fuel manifold.
- the front cathode frame 201 is secured to the front anode frame 151 by adhesive or other suitable mechanical means.
- a seal (not shown) is provided between the front cathode frame 201 and the front anode frame 151 to isolate each anode/cathode set from each adjacent anode/cathode set.
- the seal may be formed in different ways, as by the use of a suitable layer of adhesive between the rear face of the cathode frame 201 and the front face of the anode frame 151, or by one or more sealing members (e.g., gaskets), or in other ways.
- a suitable layer of adhesive between the rear face of the cathode frame 201 and the front face of the anode frame 151, or by one or more sealing members (e.g., gaskets), or in other ways.
- the back cathode assembly 53 at the back side 23 of the manifold 15 is constructed in a manner substantially identical to the front cathode assembly 51, and corresponding parts are identified by the same reference numbers.
- the frame 201 of the back cathode assembly 53 is positioned against the back anode assembly 47 with the back cathodes 201 and back anodes 157 in registration with one another and with respective fuel reservoirs 41 at the back side 23 of the manifold 15.
- the back cathode assembly 53 is secured in fixed position with respect to the manifold 15 and the back anode assembly 47 in the same manner described above in regard to the front cathode assembly 51.
- the perimeter size and shape of the manifold 15, front and back anode assemblies 45, 47, and front and back cathode assemblies 51, 53 are substantially the same so that these components can be stacked or layered to form a compact unitary structure as shown in Fig. 6 for placement in the housing 91.
- the size of the structure will vary depending on the number of fuel cells "stacked" together.
- Each fuel cell comprises a fuel reservoir 41, an anode 157, and a cathode 201.
- a fuel cell device 1 having a stack of eight cells, as shown in Figs. 1-6 may have the following dimensions: 3.5 x 2.0 x 1.0 inches (approximately 8.9 cm x 5.1 cm x 2.54 cm). In the design of this invention, any number of fuel cells can be readily stacked together to form a compact unit.
- Cathodes and biocathodes of the invention generally comprise a catalyst, an electron conductor (gas diffusion layer), and optionally a current collector.
- a cathode or biocathode of the invention includes a catalyst that is selective for reduction of oxygen in the air, capable of direct electron transfer with the cathode electron conductor, and capable of minimal, if any, catalysis of the oxidation of an alcohol fuel fluid when used in a fuel cell.
- the cathode further comprises an enzyme immobilization material.
- the cathode also includes an electron conductor (gas diffusion layer) that is permeable to air and the fuel fluid, facilitates direct electron transfer with the catalyst, and manages the water produced in the oxygen reduction reaction to minimize or prevent flooding of the cathode.
- the catalyst is capable of gaining electrons directly from the electron conductor and releasing them to the oxidant, which is oxygen.
- the cathode or biocathode further comprises an electron mediator that mediates the electron transfer from the electron conductor to the AKER 10002.1
- the cathode or biocathode further comprises an electron mediator and an electrocatalyst for the electron mediator, where the electron mediator and the electrocatalyst facilitate the transfer of electrons from the electron conductor to the catalyst and further to the oxidant, oxygen.
- the electrode comprises a first region of electrically conductive material that is permeable to air and impermeable to a fuel fluid, a second region of conductive material that is permeable to the fuel fluid and to air, and a catalyst that is able to contact both the fuel fluid and air.
- the electrode is depicted in FIG. 22 as the working electrode (WE) of an air-breathing half-cell.
- the working electrode (WE) contains the regions or layers labeled 1st region, 2nd region, and catalyst.
- the half cell also includes a reference electrode (RE) placed near the working electrode and a counter electrode (CE) of preferably a precious metal mesh or carbon sheet.
- RE reference electrode
- CE counter electrode
- An air-breathing half-cell comprising this electrode (WE) generates a current density of at least about 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, or more mA/cm 2 when operating at room temperature, an electron potential of 0.4 V, and a catalyst loading of 10 mg/cm 2 .
- WE electrowetting-on-dielectric
- an air breathing cathode of the invention When an air breathing cathode of the invention is incorporated into a fuel cell, it has been found to provide greater current density at room temperature, 0.4 V electron potential and a catalyst loading of 10 mg/cm 2 as compared to the same fuel cell which instead includes a known air-breathing non-platinum cathode.
- an electrode comprising an electron conductor, at least one non-precious metal catalyst, and an optional carbon-supported polyamine.
- the electrode has undergone heat treatment to increase metal atom interaction with the polyamine and the non-precious metal catalyst selectively reduces oxygen to water.
- an air-breathing half-cell comprising the electrode generates at least about 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, or more mA/cm when operating at room temperature, an electron potential of 0.4 V, and a catalyst loading of 10 mg/cm 2 .
- the electrode comprises an electron conductor, an enzyme capable of reacting with an oxidant to produce water, an enzyme immobilization material, and optionally an electron mediator and/or an electrocatalyst for the electron AKER 10002.1
- the electron conductor comprises a functionalized multi-walled carbon nanotube or an activated carbon based material for increasing current density as compared to an electrode with the same electron conductor that is not functionalized or activated.
- cathode and biocathode embodiments wherein there is direct electron transfer from the electron conductor to the catalyst are preferred, although embodiments of enzyme-catalyzed biocathodes having electron mediators or electron mediators and electrocatalysts are within the scope of the invention.
- various embodiments of the cathodes and biocathodes of the invention produce a current density of at least about 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, or more mA/cm 2 when operating at room temperature, an electron potential of 0.4 V, and a catalyst loading of 10 mg/cm .
- the cathode catalyst can generally be an enzyme or a non-precious metal catalyst.
- the catalyst is selective for reduction of the oxidant, oxygen. This selectivity is preferred because such a cathode catalyst will not react to oxidize the fuel fluid and thus, maintains high utilization of fuel and high cathode potential.
- the anode and cathode do not have to be separated by a polymer electrolyte membrane, thus improving the cost and efficiency of the fuel cell.
- an enzyme When an enzyme is used as the catalyst, it must be capable of reducing oxygen at the biocathode. Generally, naturally-occurring enzymes, man-made enzymes, artificial enzymes and modified naturally-occurring enzymes can be utilized. In addition, engineered enzymes that have been engineered by natural or directed evolution can be used. Stated another way, an organic or inorganic molecule that mimics an enzyme's properties can be used in an embodiment of the present invention.
- the enzyme is bilirubin oxidase, laccase, superoxide dismutase, peroxidase, or combinations thereof.
- the enzyme comprises bilirubin oxidase.
- the cathode catalyst is a non-precious metal catalyst.
- the non-precious metal catalyst selectively reduces oxygen without reacting with the fuel fluid.
- Another preferred characteristic of the non-precious metal catalyst is that it is substantially tolerant to the presence of the fuel fluid.
- the catalyst activity is not substantially decreased upon increasing the concentration of fuel fluid in contact with the catalyst.
- the current density generated by a half-cell comprising the catalyst when using an electrolyte solution containing an alcohol is not substantially less than (i.e., is at least about 75% of) the maximum current density generated by the same half-cell when using an electrolyte solution containing 5% alcohol.
- the current density using an electrolyte solution containing 30 wt.% alcohol in a half cell is at least about 75% of the maximum current density using an electrolyte solution containing 5 wt.% alcohol.
- the catalyst is tolerant to the presence of methanol and ethanol.
- the catalyst can be heat treated at about 500-900°C.
- the non-precious metal catalyst can be a transition metal, a transition metal macrocycle, or combinations thereof.
- the catalyst can be a transition metal phthalocyanine, a transition metal porphyrin, derivatives or analogs thereof, or combinations thereof.
- Exemplary transition metal macrocycles are iron phthalocyanine, cobalt phthalocyanine, iron porphyrin, cobalt porphyrin, derivatives or analogs thereof, or combinations thereof.
- Preferred transition metal macrocycles comprise cobalt(II)l,2,3,4,8,9,10,l l,15,16,17,18,22,23,24,25-hexadecafluoro-29H,31H- phthalocyanine, or derivatives or analogs thereof.
- the non-precious metal catalyst preferably interacts or associates with a polyamine.
- the polyamine is a carbon-supported amine.
- the polyamine can be polyaniline, polypyrrole, derivatives or analogs thereof, or combinations thereof.
- the polyamine comprises polypyrrole or derivatives or analogs thereof.
- a heat treatment step is performed to break down the interactions within the non-precious metal catalyst and the polyamine and make interactions (or bonds) between the non-precious metal catalyst and the polyamine.
- This heat treatment step is preferably performed in an inert atmosphere.
- the non-precious metal catalyst particularly the metal macrocycle catalyst, is heated while in contact with the polyamine or carbon-supported polyamine to about 500°C to about 900°C; preferably, about 550°C to about 650°C; more preferably, about AKER 10002.1
- the duration of this heating step is typically for about 0.5 hours to about 6 hours; preferably, about 0.5 hours to about 3 hours; more preferably, about 1 hour.
- the hydrophobicity of the electron conductor of these electrodes can be controlled to manage the water produced during the reduction of oxygen.
- a hydrophilic agent such as phosphotungstic acid, poly(4-styrenesulfonic acid), or combinations thereof can be added to decrease the hydrophobicity of the electron conductor.
- Table 7 lists the various acceptable materials and process conditions used to prepare the electrodes containing a non-precious metal catalyst and a polyamine, and performance characteristics observed when these electrodes are incorporated into a half cell as described above. Each material, process condition, or performance characteristic is contemplated in combination with the electron conductor materials described below and every other each material, process condition, or performance characteristic listed. Table 7
- Cobalt phthalocyanine analog cobalt(II)l,2,3,4,8,9,10,l l, 15,16,17,1
- Electron Conductor gas diffusion layer
- the electron conductor is a substance that conducts electrons.
- the electron conductor can be organic or inorganic in nature as long as it is able to conduct electrons through the material.
- the electron conductor is a carbon-based material.
- Exemplary carbon-based materials are carbon cloth (E-T ek), carbon paper, carbon screen printed electrodes, carbon paper (Toray), carbon paper (ELAT), carbon black (Vulcan XC-72, Cabot), carbon black, carbon powder, carbon fiber, single-walled carbon nanotubes, double-walled carbon nanotubes, multi-walled carbon nanotubes, carbon nanotubes arrays, diamond-coated conductors, AKER 10002.1
- electron conductors having a porous carbon structure wherein the porosity varies depending on the position within the electron conductor layer is useful for fuel cells utilizing a liquid electrolyte or fuel fluid.
- functionalized multi-walled carbon nanotubes and activated carbon electron conductors facilitate direct electron transfer from the electron conductor to the enzyme in the biocathode.
- an electron conductor gas diffusion layer having pores that are larger in one region of the electron conductor than in another region of the electron conductor are used.
- an electron conductor having an asymmetrical pore distribution is depicted in FIG. 23. The pore sizes are controlled so that a first region of the electron conductor is permeable to air, but impermeable to a fuel fluid (the light portions shown in FIG. 23) and a second region of the electron conductor is permeable to air and a fuel fluid (the dark portions shown in FIG. 23).
- the electron conductor is substantially permeable to a material (e.g., air or fuel fluid) when a substantial amount (i.e., at least about 50, 55, 60, 65, 70, 75, 80, 85 or more volume%) of the material is able to permeate through the material over a particular amount of time.
- a substantial amount i.e., at least about 50, 55, 60, 65, 70, 75, 80, 85 or more volume%
- the electron conductor is substantially permeable to a fuel fluid when at least about 50 volume% of the fuel fluid passes through the electron conductor within about 3 hours.
- This type of electron conductor is particularly useful for fuel cells using a liquid electrolyte rather than a solid electrolyte.
- electron conductors comprise carbon black.
- acceptable alternatives are electrically conducting carbon materials having a high surface area, an acceptable porosity in terms of being permeable to air and/or permeable to air and fuel fluid, and an appropriate hydrophobicity.
- the hydrophobicity is controlled to manage water produced from the reduction of oxygen.
- the hydrophobicity can be increased by adding increasing amounts of polytetrafluoroethylene to the electron conductor. Thus, the more polytetrafluoroethylene added to the electron conductor, the greater the hydrophobicity of the electron conductor.
- hydrophobicity can be decreased by either adding lower amounts of polytetrafluoroethylene or by adding a hydrophilic agent such as phosphotungstic acid, or poly(4-styrenesulfonic acid).
- Electron conductors having a porosity gradient can be prepared by adding a pore-forming agent.
- Acceptable pore-forming agents diffuse into the electron conductor (e.g., carbon layer) and then are easily removed from the electron conductor.
- An exemplary pore-forming agent is ammonium carbonate.
- the electron conductor comprises functionalized multi-walled carbon nanotubes (MWCNT). These functionalized MWCNT are modified by hydroxyl, carboxyl, amino, or thiol groups, or combinations thereof on the surface of the nanotubes. In various preferred embodiments, the functionalized MWCNT are modified with hydroxyl or carboxyl groups, or combinations thereof.
- the functionalized MWCNT have an average diameter of less than about 15 nm. Preferably, the functionalized MWCNT have an average diameter of less than about 8 nm.
- These functionalized MWCNT are particularly preferred in biocathodes having an enzyme as the catalyst and wherein direct electron transfer between the electron conductor and the enzyme is desired.
- Other electron conductors comprise activated carbon.
- a variety of carbon materials can be activated as described below.
- the carbon black that is activated is a carbon black sold under the Printex XE-2 name having a highly structured, extra conductive black with an average particle size of 30 nm and a BET surface area of about 910 m /g; it is commercially available from Degussa.
- the carbon materials are activated by heating to 600-900° C, followed by immersing in cold water. Without being bound by a particular theory, it is believed that the heating followed by rapid cooling breaks the carbon sheet and forms structures that have a high surface area and may be similar to nanotubes.
- the function of the functionalized MWCNT and the activated carbon when used in an enzyme-catalyzed biocathode is to (1) interact with the amino acid side groups of the enzyme by hydrogen bonding; (2) orient the enzyme to keep the active side of the biocathode to the enzyme; and (3) provide an advantageous orientation of the electron tunnel of the enzyme in the biocathode.
- an electron conductor having the desired surface area, porosity, and hydrophobicity is prepared.
- an electron conductor is prepared by immersing a piece of carbon- based support material in an electrophoretic deposition bath containing the desired electron conductor material (e.g., carbon black), a non-ionic surfactant, and a hydrophobic agent (e.g., polytetrafluoroethylene (PTFE)).
- the desired electron conductor material e.g., carbon black
- a non-ionic surfactant e.g., polytetrafluoroethylene (PTFE)
- PTFE polytetrafluoroethylene
- a coating dough of the desired electron conductor material e.g., carbon black
- a hydrophobic agent e.g., PTFE
- solvent is prepared and coated on both sides of the electron conductor prepared by electrophoretic deposition.
- the solvent in the coating dough is evaporated to form a coating film.
- the coating film is hot pressed and then sintered.
- the pore distribution can be controlled by brushing a pore-forming agent on one side of the electron conductor, allowing the agent to diffuse into the electron conductor and then heat decomposing the pore-forming agent to form the pores.
- the electron conductor pictured in Figure 2 was prepared by immersing a piece of carbon cloth (18 cm 2 , E-Tek, BlA) in the electrophoretic deposition bath containing 20 mL of a solution of 0.60 g carbon black (XE2, degussa), 0.60 mL Triton X-100, 0.67 g 60% polytetrafluoroethylene (PTFE) dispersion (Aldrich) and 100 mL milliQ water.
- the electrophoretic deposition was performed at 40 V for 20 minutes using carbon paper as the counter electrode and a distance of 3 mm between the carbon cloth and the carbon paper.
- the carbon cloth was rinsed with water to remove Triton X-100 and dried in a vacuum oven at 100 0 C for 1 hour. Dough of 0.40 g carbon black (Degussa, XE2), 0.33 g 60% PTFE suspension (Aldrich) and 8 mL ethanol was prepared. Then the dough was coated on both sides of the carbon cloth made by electrophoretic deposition as described above. The solvent in the coated film was evaporated at room temperature for 30 minutes. Then, the film was hot pressed at a pressure of 500 pounds at 95°C before sintering it at 380 0 C for 30 minutes. The PTFE content in the coated film was about 33 wt.%. Further, the pore distribution in the coated AKER 10002.1
- a non-precious metal catalyst such as a cobalt macrocycle (e.g., cobalt phthalocyanine (CoPc) and cobalt(II) 1,2,3,4,8,9,10,11,15,16,17,18,22,23,24,25- hexadecafluoro-29H,3 lH-phthalocyanine (CoPcF)), is prepared by dispersing the non- precious metal catalyst (e.g., CoPc or CoPcF) in a solvent and placing the dispersion in an ultrasonic bath.
- a cobalt macrocycle e.g., cobalt phthalocyanine (CoPc) and cobalt(II) 1,2,3,4,8,9,10,11,15,16,17,18,22,23,24,25- hexadecafluoro-29H,3 lH-phthalocyanine (CoPcF)
- Solvent is then evaporated and the dry powder is placed in a crucible and heat-treated in an inert atmosphere at a temperature of 500-900°C.
- the resulting catalyst is combined with a Nafion solution and dispersed in a solvent using an ultrasonic bath. This mixture is slowly coated onto the active side of an electron conductor (gas diffusion layer) and dried.
- a hydrophilic agent e.g., phosphotungstic acid
- a hydrophilic agent is added to the mixture with the non-precious metal catalyst and Nafion solution and dispersed in an ultrasonic bath before coating on the electron conductor.
- the non-precious metal catalyst e.g., CoPc or CoPcF
- Nafion solution e.g., CoPc or CoPcF
- the non-precious metal catalyst and Nafion solution are dispersed in a solvent and this solution is slowly coated onto the active side of the electron conductor and dried.
- a non-precious metal catalyst such as a cobalt macrocycle (e.g., cobalt phthalocyanine (CoPc) and cobalt(II) 1,2,3,4,8,9,10,11,15,16,17,18,22,23,24,25- hexadecafluoro-29H,3 lH-phthalocyanine (CoPcF)), is prepared by dispersing the non- precious metal catalyst (e.g., CoPc or CoPcF) and a polyamine (e.g., polypyrrole) in a solvent and placing the dispersion in an ultrasonic bath.
- a cobalt macrocycle e.g., cobalt phthalocyanine (CoPc) and cobalt(II) 1,2,3,4,8,9,10,11,15,16,17,18,22,23,24,25- hexadecafluoro-29H,3 lH-phthalocyanine (CoPcF)
- Solvent is then evaporated and the dry powder is placed in a crucible and heat-treated in an inert atmosphere at a temperature of 500-900°C.
- the resulting catalyst is combined with a Nafion solution and dispersed in a solvent using an ultrasonic bath. This mixture is slowly coated onto the active side of an electron conductor (gas diffusion layer) and dried.
- a hydrophilic agent e.g., phosphotungstic acid
- the non-precious metal catalyst e.g., CoPc or CoPcF
- polyamine e.g., CoPc or CoPcF
- a non-precious metal catalyst such as a cobalt macrocycle (e.g., cobalt phthalocyanine (CoPc) and cobalt(II) 1,2,3,4,8,9,10,11,15,16,17,18,22,23,24,25- hexadecafluoro-29H,3 lH-phthalocyanine (CoPcF)), is prepared by dispersing the non- precious metal catalyst (e.g., CoPc or CoPcF) and a carbon material (e.g., carbon black) in an ultrasonic bath with subsequent evaporation of the solvent.
- a cobalt macrocycle e.g., cobalt phthalocyanine (CoPc) and cobalt(II) 1,2,3,4,8,9,10,11,15,16,17,18,22,23,24,25- hexadecafluoro-29H,3 lH-phthalocyanine (CoPcF)
- the dry powder is placed in a crucible and heat-treated in an inert atmosphere at a temperature of 500-900°C.
- the powder is then combined with a Nafion solution and dispersed in a solvent in an ultrasonic bath and slowly coated onto the active side of the electron conductor (gas diffusion layer) and dried.
- a carbon material was dispersed in solvent in an ultrasonic bath to make a carbon suspension.
- An enzyme such as BOD or laccase
- buffer was added into the suspension followed by shaking. This mixture was slowly coated on to the active side of an electron conductor (gas diffusion layer) and then dried.
- the biocathode catalyst support design provides the flexibility of structural design, materials selection, and the ability to create multilayer structures with appropriate hydrophobic/hydrophilic properties for supporting a biocathode catalyst such as an enzyme.
- a schematic of the Biocathode Catalyst Support is shown in Figure 52.
- the biocathode catalyst support includes an embedded expanded metal material 525 for collecting current and for increasing the rigidity of the biocathode catalyst support, and an electrically conductive monolayer 527 surrounding the current collector 525.
- the current collector 525 is an optional component of the biocathode catalyst support; if it is not included, current is collected from the electrically conductive monolayer 527 of the biocathode catalyst support by an electrical connection.
- an optimal biocathode electrode allows for water management (i.e., water rejection when there is excess water) on the air breathing or oxidant reactant side of the electrode to prevent excess generated water from blocking AKER 10002.1
- the first electrically conductive material is modified with an electron mediator, such as carbon black modified with a doped conductive polymer, for increasing electronic and ionic conductivity and improving DET.
- the first electrically conductive layer of one or more carbon blacks is mixed with the second electrically conductive layer of one or more carbon fibers, and one or more binders to form the conductive monolayer.
- the carbon blacks are present in the mixture in a concentration of about 30 wt.% to about 45 wt.%
- the carbon fibers are present in the mixture in a concentration of about 20 wt.% to about 40 wt.%
- the binders are present in the mixture in a concentration of about 25 wt.% to about 40 wt.%.
- the carbon blacks are present in the mixture in a concentration of about 33 wt.%
- the carbon fibers are present in the mixture in a concentration of about 33 wt.%
- the binders are present in the mixture in a concentration of about 33 wt.%.
- the catalyst support layer used for the biocathode electrodes is made from a mixture of carbon materials, binder, pore forming agents, solvents, and optional catalyst such as enzymes, similar to that of the bioanode.
- the properties of the entire structure can be altered to provide desired properties for a specific application or a combination of these components can be used to make an electrode with two or more distinct regions for water management and enzyme interaction. Examples of such properties include: (1) substrate permeation, (2) electronic conduction, hydrophobicity/hydrophilicity, (3) surface area, and (4) surface structure. AKER 10002.1
- the fabrication of the biocathode catalyst support material is similar to that described for the bioanode with the exception of the frame material and sintering cycles and temperatures.
- the MDS Nylon 6/6 frame material used in the bioanode can be replaced by a similar thickness PTFE coated fiberglass sheet.
- the sintering cycle for the biocathode can be changed due to the use of polytetrafluoroethylene (PTFE) as a binder as replacement for the poly(vinylidene fluoride) binder.
- PTFE polytetrafluoroethylene
- the entire assembly i.e., frame(s) and electrode material
- the electrode is removed from the frame(s) and temporary support and cooled between two aluminum blocks (12" x 12" x 1") until set, usually only a couple of minutes, prior to a second sintering at a temperature of 300 0 C for up to 10 minutes.
- the catalyst layer can be applied to the catalyst support as described in the Encapsulated Enzyme Incorporation into Carbon Paste section below.
- catalyst particles containing an enzyme as described in the Encapsulated Enzyme Incorporation into Carbon Paste and Biocatalyst Ink Formulation sections below
- an enzyme as described in the Encapsulated Enzyme Incorporation into Carbon Paste and Biocatalyst Ink Formulation sections below
- the major properties for tailoring nanowires that improve direct electron transfer in biological systems for biofuel cell applications are (1) electric and ionic conductivity, (2) high aspect ratio to penetrate into the enzyme active center, (3) thermal stability of the precursor material, and (4) electrochemical stability of the precursor material under fuel cell operating conditions.
- the major functionality of the nanowires is to provide a nano-architectural structure with pre-defined electron transfer pathways interconnecting the redox site within the enzyme and the electrode surface (see Figure 56 AKER 10002.1
- Figure 56 shows a schematic of a nanowire array interacting with enzyme and carbon particles.
- Figure 57 shows the interaction of nanowires with each other creating a neural structure-like electron transfer network between carbon particles, which are the major component used in manufacturing the base electrode.
- Conductive polymers are exemplary polymeric materials for manufacturing nanowires via an oxidative polymerization route.
- a dopant to improve the conductivity of the polymer
- a first conductive material such as carbon black particles
- conductive nanowires e.g., electric and ionic
- Some dopants have more than one function, and may impact the nanowire dimension during the synthesis by acting as an internal pore structure or inner diameter modifier.
- Nanowires not only can be grown from polymeric materials, but also from oxide, organometallic, and metallic materials under the appropriate synthesis procedures.
- the polymeric precursor or oxide/organometallic precursors form a conductive nanowire that can transfer electrons efficiently.
- Biocathode Nanowires for Enzymatic Oxygen Reduction Reaction examples of conductive polymer based nanowires will be given for enzymatic oxygen reduction reaction in biofuel cells, but this invention is not limited only with conductive polymers.
- Conductive oxide precursors, conductive whiskers precursors, and metallic nanowires that can be grown and grafted onto various base support materials (i.e., carbon particles) and can be utilized to immobilize enzymes besides creating neural-network-like structures that are highly efficient in direct electron processes in biological systems for biofuel cells.
- Various polymers can be used as conductive polymers in forming the nanowires, for example, polyaniline, polypyrrole, polyacetylene, leucoemaraldine base, emaraldine base, pernigraniline base form of aniline, polythiophene, poly(p-phenylene), poly(p-phenylene vinyl) and their binary, tertiary, quaternary combinations can be used as precursors to grow conductive nanowires.
- Chemical and electrochemical polymerization routes can be used to polymerize the base monomer to obtain the desired nanowires. To obtain the required dimensions, use of a dopant or dopants is preferred.
- Various organic AKER 10002.1 is preferred.
- sulfonic acids can be used to produce conductive polymeric nanowires.
- naphthalenesulfonic acids camphorsulfonic acid, naphthoquinone sulfonic acid, and etc
- toluenesulfonic acids such as pyridinium p-toluenesulfonate, hydroxypyridinium p- toluenesulfonate, tetrabutylammonium p-toluenesulfonate, etc.
- multicharged conjugated zwitterionic complexes containing both positive and negatively charged groups on the same molecule
- l-(3-Sulfopropyl)pyridinium hydroxide inner salt 3-(l- Pyridinio)-l-propanesulfonate, etc.
- dopants such as l-(3-Sulfopropyl)pyridinium hydroxide inner salt, 3-(l- Pyridinio)-l
- the oxides should be stable under acidic or basic conditions.
- oxides of titanium, ruthenium, osmium, iridium, platinum, gold, palladium, rhenium, aluminum, indium-tin oxide (ITO) and their binary, tertiary, quaternary combinations can yield conductive nanowires useful for the purposed described herein.
- ITO indium-tin oxide
- These oxides can be modified for this purpose by either conventional synthesis procedures (chemical vapor deposition, ion-plasma based deposition, etc.) or hydrothermal synthesis protocols.
- Examples of conductive whiskers precursors are metal-complexed macrocyclic phtalocyanine or porphine complexes and non-metal complexed various phthalocyanine/porphine species (such as copper phthalocyanine, cobalt phthalocyanine, nickel phthalocyanine, iron phthalocyanine, zinc phthalocyanine, copper porphine, cobalt porphine, ruthenium porphine, palladium porphine, vanadium porphine, zinc porphine, and the like, and combinations thereof.
- Conductive whiskers can be grown using conventional low and high vacuum based deposition techniques (e.g., evaporative, glow-discharge, gas- phase chemical processes, and liquid-phase chemical formation technologies).
- Examples of acid or base stable metallic nanowire precursors include titanium, ruthenium, osmium, iridium, platinum, gold, palladium, rhenium, and their binary, tertiary, or quaternary combinations to manufacture conductive nanowires for direct electron transfer pathways between biological systems and base electrode structure.
- Metallic nanowires/nanowhiskers can be grown using conventional low and high vacuum based deposition techniques (e.g., evaporative, glow-discharge, gas-phase chemical processes, and liquid-phase chemical formation technologies).
- the electrode support fabrication is done prior to enzyme deposition; this process results in two distinct layers.
- enzyme immobilized carbon particles can be incorporated into carbon pastes without the typical enzyme activity loss from solvent and temperature- induced denaturation to provide an integrated enzyme/carbon electrode structure.
- encapsulated enzyme/carbon diffusion electrode supports can be fabricated in a custom tailored fashion to have desirable characteristics for either the anode or cathode.
- the anode can have a more hydrophilic paste that uses a hydrophilic component as discussed below.
- the cathode support can have a greater Teflon content to provide higher hydrophobicity while retaining partial hydrophilicity.
- various components can provide a range of parameters that can be varied to produce electrodes having desired properties.
- the selection of the specific carbon materials (including graphite fibers for rigidity), binder agents, and pore forming agents along with their respective ratios can be varied to provide electrodes with a range of properties.
- Initial testing illustrated retention of activity and good mechanical stability in half cell configurations.
- an enzyme is immobilized on a highly conductive high surface area carbon black such as those given in the table above. Once the enzyme is immobilized, the carbon is dried, and then it is mixed with graphite fibers, carbon blacks, an alcohol solvent, poly(vinylidene fluoride) (PVDF) and/or PTFE binder, and optionally, a hydrophilic agent (i.e., ammonium carbonate, poly(ethylene) glycol, polyvinyl alcohol, or silica gel).
- a hydrophilic agent i.e., ammonium carbonate, poly(ethylene) glycol, polyvinyl alcohol, or silica gel.
- the paste is then spread onto expanded metal, typically nickel or stainless steel (any expanded metal can be used), with a shape conforming frame around it to make the desired electrode size. Any type of tool (e.g., spatula, spoon, trowel, etc.) can be used to form the paste and spread it. After spreading, a paper towel is placed around the electrodes and they are mechanically pressed at 5,000 lbs to compress them and to help remove excess solvent.
- expanded metal typically nickel or stainless steel (any expanded metal can be used
- Any type of tool e.g., spatula, spoon, trowel, etc.
- a paper towel is placed around the electrodes and they are mechanically pressed at 5,000 lbs to compress them and to help remove excess solvent.
- the shape conforming frame is removed.
- a Kimwipe is placed on either side of the electrodes, and they are hot pressed at 5,000 lbs at a temperature of 125 0 C for 20 seconds.
- the greater stability of the enzyme in the immobilization material has allowed development of ink formulations that can be directly painted onto commercial electrode supports or electrode supports described herein for use in fuel cell applications.
- the ink formulation consists of enzyme encapsulated carbon, carbon black filler, and Nafion® solution.
- the enzyme encapsulated carbon consists of a carbon particle surrounded by enzyme that is entrapped within an immobilization polymer.
- Various aspects of the present invention are directed to a particle comprising a core coated with an immobilized enzyme.
- the core can be a material that provides a support for the immobilized enzyme layer that is coated on the core.
- the immobilized enzyme layer comprises an enzyme, an enzyme immobilization material, and an optional electron mediator.
- the immobilized enzyme has an activity of at least about 0.65, 0.7, 0.75, 0.8, 0.85, 0.9, 0.95, or more, relative to its initial activity before AKER 10002.1
- the enzyme retains at least 75% of its initial catalytic activity for at least 5, 10, 15, 20, 25, 30, 45, 60, 75, 90, 105, 120, 150, 180, 210, 240, 270, 300, 330, 365, 400, 450, 500, 550, 600, 650, 700, 730 days or more.
- the components of these particles are described in more detail below.
- Another of the various aspects of the present invention is a process for preparing a particle coated with an immobilized enzyme.
- This process comprises mixing a solution comprising an enzyme with a suspension comprising at least one support particle, an immobilization material, and a liquid medium to form a mixture. This mixture is then spray-dried to produce the coated particles.
- the particle produced can include a core, an optional electron mediator, an enzyme, and an enzyme immobilization material (e.g., polymer matrix) as shown in Figure 47.
- the polymer matrix which functions to stabilize the enzyme and fix it to the support, can be the various enzyme immobilization materials described below.
- various compounds can be added in addition to the enzyme in the matrix that aid enzyme function. For example, electron mediators, cofactors, and coenzymes can be immobilized and will not leach into a liquid upon contact or repeated washes.
- the enzyme is not covalently attached or adsorbed to the core. Further, preferably, the enzyme does not leach from the enzyme immobilization material into a liquid medium that the immobilized enzyme layer contacts.
- the immobilized enzyme particles comprise from about 0.1 wt.% to about 25 wt. % of the core and about 0.1 wt.% to about 70 wt.% of the coating and the coating comprises from about 0.1 wt.% to about 29 wt.% of the enzyme, about 0.1 wt.% to about 43 wt.% of the enzyme immobilization material, up to about 29 wt.% of the electron mediator.
- the total weight percent of the enzyme and the electron mediator can be up to 57 wt.% of the coating.
- the core is any particle that provides a support for the immobilized enzyme layer and that can be spray-dried.
- the core particle can be, for example, a polymer particle, a carbon particle, a zeolite particle, a metal particle, a ceramic particle, a metal oxide particle, or a combination thereof.
- the core particle is an inert AKER 10002.1
- the core particle is not a polymer particle. Preferred core particles do not adversely affect the stability of the enzyme or the chemical transformation involving the enzyme. In some embodiments, the core particles have an average diameter from about 200 nm to about 100 ⁇ m, depending upon the intended use of the particles when coated with the immobilized enzyme.
- the coated particles are prepared by mixing a solution comprising an enzyme or organelle with a suspension comprising at least one core particle, an immobilization material, and a liquid medium and spray-drying the resulting mixture.
- a solution comprising an enzyme or organelle
- a suspension comprising at least one core particle, an immobilization material, and a liquid medium
- spray-drying step are described in more detail below.
- An enzyme solution comprising the enzyme and a solvent is used in the coating procedure.
- an organelle solution comprising the organelle and a solvent is used in the coating procedure.
- the enzyme is combined with a solvent and mixed until a solution is formed.
- Acceptable enzymes and organelles are described in more detail above.
- the solvent can be an aqueous solution, particularly a buffer solution, such as an acetate buffer or phosphate buffer.
- the buffer pH is designed to provide an acceptable pH for the particular enzyme or organelle to be immobilized.
- the enzyme solution can contain an electron mediator as described above.
- a suspension is prepared by combining a core particle, the desired immobilization material and a liquid medium.
- exemplary core particles and immobilization materials are described above.
- the liquid medium can be a solvent or buffer, such as an acetate buffer or phosphate buffer.
- the buffer pH is selected to provide an acceptable pH for the particular enzyme or organelle to be immobilized and coated.
- the enzyme or organelle solution and the suspension are prepared, they are combined and mixed well. The resulting mixture is then dried.
- a preferred drying method is spray-drying because the drying also results in coating of the core particles with the immobilized enzyme layer.
- Conventional spray drying techniques can be used in the methods of the invention.
- Alternatives to spray-drying include other conventional processes for forming coated particles, such as fluidized bed granulation, spray dry granulation, rotogranulation, fluidized bed/spray drying granulation, extrusion and spheronization. AKER 10002.1
- the solution comprises from about 0.1 wt.% to about 15 wt.% of the enzyme and about 85 wt.% to about 99.1 wt.% of a solvent
- the suspension comprises from about 0.1 wt.% to about 50 wt.% of the core particles, from about 4 wt.% to about 10 wt.% of the enzyme immobilization material, and from about 50 wt.% to about 75 wt.% of the liquid medium.
- Other ways to make the casting solution include mixing the particles and the enzyme or organelle together in buffer to form a suspension and then adding solubilized immobilization material to complete the mixture or by combining all of the materials at once to form a suspension.
- a mixture of enzyme, enzyme immobilization material, and optionally, electron mediators can be coated onto supporting particles using a spray coating/drying technique.
- an airbrush e.g., Paasche VL series
- the aerosol is generated using compressed nitrogen gas regulated at about 25 psi.
- the mixture is airbrushed onto a surface such as a polycarbonate shield from a distance of about 40 cm from the tip of the airbrush to the shield.
- the airbrush can be moved in a raster pattern while moving vertically down the polycarbonate target in a zigzag pattern applying the casting solution. This procedure is used to minimize the coating thickness on the shield and minimize the particle-particle interaction while drying.
- the casting solution is allowed to dry on the shield for about 20 minutes before being collected by a large spatula/scraper.
- the MEA was fabricated by hot pressing the platinum anode catalyst and the laccase immobilized cathode onto a solid proton-conducting electrolyte membrane.
- the membrane used was a 0.005 inch thick Nafion® Membrane Nl 15 (from E.I. du Pont de Nemours).
- Kapton polyimide film is then covered above and below the MEA because of its durability at high temperature and also to prevent the MEA from sticking to the steel plates.
- the kapton covered MEA of 5 cm 2 was formed by hot pressing both anode and cathode electrodes simultaneously between the Nafion® membrane at temperature of 125 C at 3000 lbs of pressure using the two steel plates.
- a schematic of the press package for this MEA is shown in Figure 66.
- the MEA was fabricated in a two step process by first pressing the platinum anode catalyst and then pressing the laccase immobilized cathode against each face of a solid proton-conducting electrolyte.
- the membrane used was a 5 mil thick Nafion® Membrane Nl 15 (from E.I. du Pont de Nemours). Kapton polyimide film was then covered above and below the MEA because of its durability at high temperature and also to prevent the MEA from sticking to the steel plates.
- the platinum anode electrode was hot pressed against the Nafion® membrane at temperature of 125 C at 3000 lbs of pressure.
- a schematic of the press package the first step is shown in Figure 67A.
- the second step is the hot pressing of the chitosan immobilized laccase cathode electrode at temperature of 85 C at 3000 lbs of pressure.
- a schematic of the press package the first step is shown in Figure 67B. This two step process is necessary due to the thermal decomposition of chitosan at temperatures above 85 C.
- the fuel cell device 1 comprises a "stack" of eight fuel cells, each cell including a fuel reservoir 41 and associated anode and cathode assemblies.
- the number of such cells can vary from one to any number greater than one.
- Fig. 14 illustrates an embodiment of device 1 in block diagram form.
- one or more fuel cells 321 are electrically connected to the electronic controller 71 via line 323.
- the cells 321 may be stacked as described above. For example, line 323 AKER 10002.1
- the electronic controller 71 controls the output of each cell 321 according to a desired mode of operation.
- the cells 321 are electrically connected in series and controller 71 switches them on and off together at a predetermined duty cycle, such as 25% at 1000 Hz.
- a predetermined duty cycle such as 25% at 1000 Hz.
- operating cells 321 according to the predetermined duty cycle improves fuel cell performance.
- cycling the cells 321 on and off improves stability for long term use as measured by current decay at a set voltage.
- cycling cells 321 in this manner improves the power output of the device 1 by allowing time for cells 321 to go from load to an open circuit condition. In the open circuit condition, cells 321 have a larger reactance available to the catalyst layer without being oxidized, which results in a larger power output when subsequently under load.
- controller 71 controls the output of cells 321 so that one cell is disconnected from load 5 while the remaining cells are connected to load 5 (e.g., one cell off and seven cells on for an eight cell stack).
- load 5 e.g., one cell off and seven cells on for an eight cell stack.
- the supplemental power circuit 81 provides power to supplement the normal output of device 1 , as needed. This is particularly useful during conditions in which load 5 draws a greater amount of current, such as when starting, or powering up, an electronic device.
- supplemental power circuit 81 is implemented as part of controller 71.
- the controller 71 monitors the voltage output of cells 321 and executes a comparator for comparing the voltage output to a minimum output reference voltage, such as 1.5 V. If the monitored voltage output falls below this threshold, controller 71 switches on a battery assist, or hybrid, circuit for supplementing the output power.
- a supplemental power source such as a battery 325 (e.g., a rechargeable lithium ion battery), provides power to controller 71 via line 327 to supplement the output of cells 321.
- a battery 325 e.g., a rechargeable lithium ion battery
- supplemental power circuit 81 may be a separate circuit connected to the battery 325 and controller 71.
- controller 71 disconnects all of the fuel cells 321 from the load 5.
- the third mode may be used for recharging battery 325 with the output voltage of cells 321.
- Fig. 14 also shows a boost circuit 331 for regulating the output of cells 321 (or the hybrid output of cells 321 and battery 325) provided via line 329.
- fuel cell device 1 supplies a relatively constant voltage at its output, generally designated 333 (see also Figs. 2 and 3), that can be used on a variety of load specifications. It is to be understood that the output 333 may be hard-wired to the load 5 and connected to fuel cell device 1 via a plug or the like, or vice versa.
- fuel cell devise 1 includes a capacitor 335, which charges when the system is "dormant.”
- the capacitor 335 provides supplemental power in addition to, or instead of, battery 325.
- the boost circuit 331 comprises a step up DC-DC converter circuit that supplies a regulated 5 V on its output to the load 5.
- a processor such as a first microprocessor 337
- the microprocessor 337 executes computer-executable instructions for operating the cells 321 according to the desired modes of operation.
- the switch circuit 339 is responsive to microprocessor 337 for turning the output of each of the individual cells 321 on or off.
- switch circuit 339 comprises a plurality of single pole double throw switches, each connected to one of the cells 321 for selectively connecting it's output to (or disconnecting it's output from) the load 5.
- the supplemental power circuit 81 comprises a second microprocessor 341 and a second switch circuit, generally designated 343.
- This second microprocessor 341 monitors the voltage output of cells 321 (at line 329 from switch circuit 339) and compares the voltage output to the minimum output reference voltage. If the monitored voltage output falls below the minimum threshold, microprocessor 341 causes the switch circuit 343 to electrically connect the battery 325 to the load 5 and, thus, supplement the output of cells 321.
- microprocessors including, for example, one of the CY8C29XXX family of Programmable System on Chip mixed signal array controller devices available from Cypress Semiconductor Corporation is suitable for use as microprocessor 337 and one of the CY8C21XXX family of Programmable System on Chip mixed signal array controller devices available from Cypress Semiconductor Corporation is suitable for use as microprocessor 341.
- AKER 10002.1 one of the CY8C29XXX family of Programmable System on Chip mixed signal array controller devices available from Cypress Semiconductor Corporation is suitable for use as microprocessor 337 and one of the CY8C21XXX family of Programmable System on Chip mixed signal array controller devices available from Cypress Semiconductor Corporation is suitable for use as microprocessor 341.
- AKER 10002.1 one of the CY8C29XXX family of Programmable System on Chip mixed signal array controller devices available from Cypress Semiconductor Corporation is suitable for use as microprocessor 337 and one of the CY8C21XXX family of Programmable System on Chip
- control functions of monitoring and comparing output voltages, controlling switch circuit 339, controlling switch circuit 343, and so forth, may be performed by a single processor, such as either microprocessor 337 or microprocessor 341.
- a computer executes software for use in programming microprocessor 337 to control switch circuit 339 according to one of the biofuel cell device's operating modes.
- Figs. 16 and 17 illustrate an exemplary user interface displayed on the computer for receiving user input to design and simulate the modes for an eight cell biofuel cell device.
- Outputs 1 to 8 represent the state of each of the cells of the fuel cell device (e.g., cells 321 of device 1).
- Input 1 represents an external push button switch (not shown) for changing among the various operating modes.
- VAR2 is responsive to Input 1 and represents the device's operating mode. For example, pushing Input 1 until the VAR2 value increments to 1 initiates the first mode.
- Output 1 is set to the predetermined duty cycle (e.g., 25% at 1000 Hz). Because cells 321 are electrically connected in series, all of the cells 321 turn on and off together at the predetermined duty cycle.
- the microprocessor 337 controls switch circuit 339 in the second mode when VAR2 has a value of 0.
- Output 1 is set to another predetermined duty cycle (e.g., 10% at 1000 Hz).
- VAR 1 turns on and initiates a phase shift. The phase shift provides sufficient delay when operating at the 10% duty cycle so that seven of the eight cells 321 in the illustrated embodiment are on while one of the eight cells 321 is off.
- the particular cell 321 that is off rotates among the total number of cells so that each cell is off for an approximately equal amount of time.
- the user interface shown in Fig. 17 corresponds to a simulation of this second operating mode in which VAR2 is off and VARl is on.
- the VAR2 value increments to a value of 2, which turns off all of the Outputs 1 to 8.
- the third mode may be used for recharging battery 325 with the output voltage of cells 321.
- an electronics assembly generally designated 345 (see also Fig. 3), includes a first printed circuit board 347 on which electronic controller 71, including supplemental power circuit 81, are mounted.
- a electronics assembly 345 includes a second printed circuit board 349 providing the electrical connections for the battery 325.
- a metal receiver 353 mounted on the second printed circuit board 349 forms a pocket or receptacle in which battery 325 rests when installed.
- receiver 353 has one or more spring members 355 that are biased against the battery 325 to retain the battery in position within the receiver and to form an electrical connection with one of the battery's terminals.
- a conductive pad (not shown) on printed circuit board 349 provides the electrical connection for the other battery terminal.
- a wire (not shown) or other conductive means electrically connects the first and second printed circuit boards 347, 349 to connect battery 325 to controller 71. Additionally, a plurality of wires, generally designated 357, or other conductive means electrically connect controller 71 to the fuel cells 321.
- the housing 91 is desirably of multi-part construction to facilitate assembly and disassembly of the fuel cell device 1.
- the housing comprises first and second parts 9 IA, 9 IB which, when combined, form an enclosure having a volume sufficient to snugly receive the stacked components of the fuel cell device 1.
- the two parts are secured 9 IA, 9 IB together in a releasable manner by one or more fasteners (e.g., hex head bolts 275) or other mechanical means.
- a gasket or other sealing device (not shown) seals the joint between the two parts 9 IA, 9 IB when they are secured together.
- the housing 91 has at least one opening 277 for allowing delivery of fuel fluid from the fuel source 7 to the inlet 29 of the manifold and for allowing delivery of fluid from the outlet 33 of the manifold to the waste destination 9.
- the walls of the housing 91 have holes 281 to permit air flow to and from the interior of the housing for ventilating and cooling components inside the housing.
- the housing may be molded, machined or otherwise fabricated from a suitable material such as acrylic.
- projections 285 on the inside surfaces of the housing parts 9 IA, 9 IB provide support for the electrode structure of the fuel cell device, i.e., the fuel manifold 15, cathode assemblies 51, 53 and anode assemblies 45, 47, to provide proper support and positioning of these components inside of the housing.
- Some of these projections 285 may also define locations, e.g., compartments 289, 291, for receiving the electronic controller 71 and power circuit 81.
- AKER 10002.1 Alternatively or in AKER 10002.1
- recesses may be formed in the interior surfaces of the housing to receive these components.
- fuel is delivered to the fuel cell device 1 from the source 9 by suitable means (e.g., a syringe or pump) until the fuel reservoirs 41 are filled and the fuel fluid contacts respective anodes 157.
- suitable means e.g., a syringe or pump
- the anode is the site for an oxidation reaction of a fuel fluid with a concurrent release of electrons and protons.
- the electrons are directed from the anode through an electrical connector to some power consuming device.
- the protons move through the fuel fluid and polyelectrolyte membrane to the cathode.
- the biofuel cell of the present invention acts as an energy source (electricity) for an electrical load external thereto.
- the electrodes comprise a current collector, a gas diffusion layer (an electron conductor), optionally an electron mediator, optionally an electrocatalyst for the electron mediator, an enzyme, and an enzyme immobilization material.
- the electron mediator is a compound that can accept electrons or donate electrons.
- the oxidized form of the electron mediator reacts with the fuel fluid and the enzyme to produce the oxidized form of the fuel fluid and the reduced form of the electron mediator at the bioanode.
- the reduced form of the electron mediator reacts with the oxidized form of the electrocatalyst to produce the oxidized form of the electron mediator and the reduced form of the electrocatalyst.
- the reduced form of the electrocatalyst is then oxidized at the bioanode and produces electrons to generate electricity.
- the redox reactions at the bioanode can be reversible, so the enzyme, electron mediator and electrocatalyst are not consumed.
- these redox reactions can be irreversible if an electron mediator and/or an electrocatalyst is added to provide additional reactant.
- an electron conductor and an enzyme can be used wherein an electron mediator in contact with the bioanode is able to transfer electrons between its oxidized and reduced forms at unmodified electrodes. If the electron mediator is able to AKER 10002.1
- a fuel cell device of a second embodiment of the present invention is designated in its entirety by the reference number 501 in Fig. 19.
- the fuel cell device 501 is generally similar to the embodiment described above except for some features that will be described in further detail below. Portions of the device 501 of the second embodiment that are similar to features of the device 1 of the first embodiment will be referred to using reference numbers similar to the first embodiment but incremented by 500.
- the fuel cell device 501 of Fig. 19 is separated to illustrate the various components of the device 501.
- the device 501 generally comprises a fuel manifold 515 having a front side 521, a back side 523, an inlet 529 for receiving fuel from a fuel source (not shown) and an outlet 533 (Fig. 20) for exhausting fuel from the manifold to a waste destination (not show).
- the manifold 515 has four fuel reservoirs, each designated 541.
- the fuel cell device 501 also includes an anode assembly, generally designated 545, for reacting with fuel in the fuel reservoirs 541, and a cathode assembly, generally designated 551 adjacent a lid or cover 561.
- An electronic controller (not shown) is provided for controlling operation of the device 501, and a supplemental power circuit (not shown) is included for providing power to supplement the normal output of the fuel cells, as needed.
- a permeable membrane 593 and a protective screen 595 are provided on the back side 523 of the device 501.
- the fuel manifold 515 has an inlet 529 permitting fuel fluid to enter the manifold from a fuel source (not shown) and an outlet 533 permitting fuel fluid to exit the manifold to a waste destination (not shown).
- the inlet 529 and outlet 533 may include tubing nipples similar to those of the manifold 15 of the first embodiment AKER 10002.1
- the manifold 515 has four fuel reservoirs 541.
- the manifold 515 comprises a body or block 601 of suitable dielectric material having a top 605, a bottom 607, opposite ends 609, a front face 611 and a back face 615.
- the block 601 may be made of polymer-based or non-polymer-based materials that are chemically insert to the fuel being used.
- the block 601 is made of acrylic.
- the block 601 is formed (e.g., molded, machined, etc.) to have a rectangular shape and is preferably constructed from a single one-piece member.
- the fuel reservoirs 541 are defined by cavities (also designated 541) in the front face 611 of the block.
- each cavity may be formed in the front face 611 and back face 615 of the block 601.
- each cavity has a volume of about 1.74 cubic centimeters.
- Each inlet port 621 and corresponding outlet port 625 are positioned on opposite ends of passages, generally designated by 627, extending through interior walls 637 separating the cavities 541. As shown in Fig. 20, the elevation of each outlet port 625 is at least as high as a top of each inlet port 621.
- each check valve is a stainless steel check valve having a 0 psi cracking pressure press fit into a 2.5 mm diameter passage.
- the manifold includes a compartment 645 for receiving the electronic controller and power circuit.
- a lip 647 is formed around the front face 611 of the block 601 for engaging the lid 561.
- Openings 649 are provided adjacent a back side of each cavity 541 to exhaust carbon dioxide generated during the reaction.
- Air holes are also provided in the manifold 515 to permit air to enter the fuel cell.
- Fig. 21 illustrates the anode assembly 545, which reacts with fuel in the fuel reservoir 541 and the cathode assembly 551 adjacent the anode assembly.
- the anode assembly 545 includes a printed circuit board frame 651.
- the frame 651 has a plurality of openings 655 configured and arranged to match the configuration and arrangement of fuel reservoirs 541 in the front face 611 of the manifold 615.
- the anode assembly 545 also includes a number of anodes, each generally designated 657, held by the frame 651 in the frame openings 655, one anode per frame opening.
- Each anode 657 comprises a current collector 661 secured in a respective frame opening 655.
- the current collector 661 comprises two gold plated stainless steel mesh panels spot welded together. One panel is sized to precisely fit in the frame opening 655 and the other panel is sized to overlap the opening.
- the collectors 661 are spot welded to pads 663 printed on opposite margins of the openings 655. When the collectors 661 are spot welded to the pads 663, it is important that the welding parameters be set so the welder does not arc. Using a CD250DP Sunspot-b dual pulse spot welders, the following parameters have found to provide acceptable results: energy level - 14; pulse 1 - 12; pulse 2 - 45; and welder energy - 14. These parameters provide a mechanically stable weld without damaging the current collectors 661.
- Each anode 657 also includes a gas diffusion layer 665 on the back face of the current collector 661.
- This diffusion layer 665 may be a carbon paste structure comprising dry components of Monarch 1400 carbon black (Cabot) and Chemsorb 1505 G5 porous, impregnated steam activated carbon (C*Chem), and wet components of Quick Set 2 part epoxy (The Original Super Glue Corp.) dissolved in acetone and 60 % polytetrafluoroethylene (PTFE) dispersion in water (Sigma).
- the dry components are ground in a food grinder and the wet components are mixed with an ultrasonic homogenizer, then the dry and wet components are combined and mixed with a putty knife until the mixture is the consistency of toothpaste.
- a catalyst layer (not shown) is then added to the gas diffusion layer 665 by applying a cast mixture of enzyme in buffer solution and tetrabutylammonium-modified Nafion ® ionomer.
- the catalyst layer is allowed to dry before joining it to the anode assembly.
- the enzyme used in the catalyst layer is pyrroloquinoline quinone-dependent alcohol dehydrogenase (PQQ-ADH).
- QQ-ADH pyrroloquinoline quinone-dependent alcohol dehydrogenase
- a layer of hot melt 675 and a vinyl frame 677 are applied to the anode as shown. AKER 10002.1
- Each cathode assembly 551 is constructed using a similar method as described above with respect to the anode assembly 545.
- the cathode assembly 551 also includes a layered catalyst structure on the back face of its current collector.
- This layered catalyst structure comprises a gas diffusion layer, a catalyst layer, and a polyelectrolyte membrane (Nafion ® ). Upon assembly, this layered catalyst structure is affixed to the back face of the current collector.
- the catalyst layered structure is prepared by applying an ink comprising a platinum black catalyst and Nafion ® ionomer to one side of the gas diffusion layer (e.g., E-T ek as LT2500W Low Temperature Elat with microporous layer on either side).
- the catalyst layered structure is assembled by placing the gas diffusion layer on top of the current collector with platinum black catalyst side up, then placing the polyelectrolyte membrane (e.g., Nafion ® ) on top of the gas diffusion and catalyst layers.
- This assembly is soaked with water and then fixed together by hot pressing, resulting in a stand alone cathode fixture (e.g., at 125°C at 3000 pounds for 35 seconds.
- the polyelectrolyte membrane e.g., Nafion ® ionomer
- the polyelectrolyte membrane is impermeable to the fuel fluid, but is able to conduct electrons and protons.
- anode assembly 545 and the cathode assembly 551 are prepared as described above, they are assembled together by coating connector pads 731 on each of the printed circuit board frames 651 with solder paste or ordinary spooled solder.
- An eight conductor ribbon cable 735 is then tacked down to one board with about 0.020 inch of bare conductor hanging off the edge of the board.
- the second board is then aligned with the first board and cable and held in place with firm pressure.
- Each conductor is then touched with a soldering iron to reflow/melt the solder paste/solder on the upper and lower boards making good electrical contact between the boards and the cable.
- Continuity is then checked between the far end of the flat flex cable and each of the individual mounting pads for the expanded metal on the frames. Shorts between the conductors are also checked. The assembly/conductors are reflowed as needed until proper operation is achieved.
- the connector pads 731 are offset from center so that the pads of one board are not aligned with the pads of the other board but so they all align with one conductor of the cable 735.
- solder mask is removed prior to assembly in order to assure a leak- free stack.
- the solder mask removal may be accomplished by soaking the printed circuit boards in a dichloromethane solution until the entire solder mask is loose and easily removable. Once the solder mask is removed, the circuit boards are taken out of the AKER 10002.1
- dichloromethane solution and rinsed thoroughly with dichloromethane. The boards are then allowed to dry while the other components necessary are prepared.
- anode and cathode assemblies 545, 551, respectively are assembled and soldered together, they are pressed (e.g., at 125°C and 1000 pounds for about 10 to about 20 seconds).
- the completed stack is trimmed as needed and sealed to the casing by adhesive bonding (e.g., with hot melt and pressing at 2000 pounds until cooled). Once cooled, the anode reactant can be added to the fuel reservoirs.
- the carbon dioxide permeable membrane 593 covers the openings 649 at the back sides of the reservoirs 541.
- the membrane 593 selectively permits passage of carbon dioxide to remove gas generated in the reservoirs 541 to remove the gas from reservoirs without allowing unreacted fuel to exit the reservoirs.
- polymer membranes that are selectively carbon dioxide permeable are silicone, styrenic thermoplastic elastomers, polyamide based thermoplastic elastomers, polybutadiene based thermoplastic elastomers, EPDM rubber based thermoplastic elastomers. Due to very high selective carbon dioxide permeability, during the fuel cell operation the generated carbon dioxide gas vents through porous structure while acting as a barrier for alcohol fuel.
- Particles coated with immobilized enzymes can be used as catalysts for a variety of chemical transformations. Enzymes can be immobilized in enzyme immobilization materials and coated on particles using processes described herein and deposited on various substrates. These immobilized enzyme particles can then contact reaction mixtures and catalyze the desired chemical transformation.
- the particles of the invention can replace enzymes in the embodiments as described below.
- immobilized enzyme particles can be used for catalyzing a reaction wherein the enzyme immobilization material immobilizes and stabilizes the enzyme, is permeable to a compound smaller than the enzyme and is a micellar hydrophobically modified polysaccharide.
- the micellar hydrophobically modified polysaccharide is a hydrophobically modified chitosan or a hydrophobically modified alginate.
- immobilized enzyme particles can be used for detecting an analyte.
- the enzyme immobilization material immobilizes and stabilizes the enzyme, is permeable to a compound smaller than the enzyme and is a micellar hydrophobically AKER 10002.1
- micellar hydrophobically modified polysaccharide is a hydrophobically modified chitosan or a hydrophobically modified alginate.
- enzymes are used to degrade stains in laundry soil, such as in detergents to break down and remove proteins from clothes.
- the enzymes used in detergents are proteases, amylases, carbohydrases, cellulases, and lipases.
- These enzymes can be immobilized and stabilized in enzyme immobilization materials described herein and dispersed in a detergent or in an aqueous carrier to provide a laundry soil treatment.
- the enzyme immobilization materials could stabilize the enzyme to the other components of the detergent and improve storage stability.
- Various detergent products containing enzymes are described in US Patent Nos. 7,179,780, 6,894,013, and 6,827,795; these patents are herein incorporated by reference.
- enzymes are used in wastewater treatment to break down various wastes in the stream.
- lipases, cellulases, amylases, and proteases are used in addition to bacteria to eliminate various wastes.
- the components in specific waste streams and the appropriate enzymes used to degrade such waste streams are known to a person skilled in the art.
- various enzymes used in wastewater treatment are disclosed in U.S. Patent Nos. 7,053,130, 6,802,956, 5,531,898, and 4,882,059; these patents are herein incorporated by reference. These enzymes can be replaced with the particles of the invention containing such enzymes to improve enzyme stability.
- enzymes are used in three steps of high fructose corn syrup processing; these steps are liquefaction of the corn or cereal, saccharification of corn or other cereals to convert starch into sugars, and isomerization of glucose to fructose.
- glucose isomerase is used to convert glucose to fructose.
- the enzymes used could be advantageously immobilized in the enzyme immobilization materials described herein. This immobilization of the enzymes would be advantageous because the enzymes would be stabilized to denaturation and the enzymes could be easily removed resulting in a more controlled process.
- enzymes are used in food processing because these processes require enzymes that catalyze various reactions of proteins.
- fungal amylases in baking processes, fungal amylases, hemicellulase, pentosanases, xylanases, proteases, pullulanases, and acid proteinases are used for various purposes.
- fungal amylase is used to modify flours for baking and produce more uniform dough and products.
- maltogenic amylases are used to extend shelf-life of various types of bread and pullulanase is used as an antistaling agent in baked goods.
- amylases, proteases, ⁇ -glucanase, and acetolactate decarboxylase are used in various steps.
- proteases e.g., pepsin
- lipases are used in the milk curdling and cheese ripening steps and lactase is used for production of whey syrup.
- ⁇ -glucosidase transforms isoflavone phytoestrogens in soymilk.
- Each of these enzymes can be immobilized in an edible immobilization material by the processes described herein and be advantageously used as catalysts for these reactions. These processes are described in more detail in U.S. Patent Nos. 7,014,878, 6,936,289, 6,830,770, 4,358,462, and 6,372,268; these patents are herein incorporated by reference.
- Various chemical synthesis processes use enzymes for esterifications, chiral synthesis, and interesterification and degumming of oils.
- various carboxylic acid compounds including polymers having pendant carboxylic acid groups can be esterified with alcohols using various enzymes.
- the enzymes used to catalyze an esterification reaction are generally hydrolytic enzymes, specifically lipases, proteases, and esterases.
- Illustrative enzymes include Candida antarctica Lipase B (manufactured by Novozyme), Mucor meihei Lipase IM, Pseudomonas Cepacia Lipase PS-30, Pseudomonas aeruginosa Lipase PA, Pseudomonas fluoresenses Lipase PF, Aspergillus niger lipase, and Candida cylinderacea lipase from porcine pancreatic lipase. These reactions are described in more detail in U.S. Patent Nos. 7,183,086 and 6,924,129; these patents are herein incorporated by reference. These enzymes can be replaced with the particles of the invention containing such enzymes to improve enzyme stability.
- a variety of enzymes can catalyze various chemical transformations.
- glutaminase is used to convert glutamine to glutamates
- penicillin acylase is used in chemical synthesis
- chloroperoxidase is used in steroid synthesis
- aspartic ⁇ -decarboxylase is use to make L-alanine from L-aspartic acid
- cyclodextrin glycosyltransferase is used to make cyclodextrins from starch.
- synthesis of various chiral compounds use enzymes. Subtilisin is used for the chiral resolution of chemical compounds or pharmaceuticals, aminoacylase can optically resolve amino acids, alcohol dehydrogenase is used in the chiral synthesis of chemicals and amino acid oxidase is used for resolution of racemic amino acid mixtures. Some of these reactions are described in more detail in U.S. Patent Nos. 6,036,983, 5,358,860, 6,979,561, 5,981,267, 6,905,861, and 5,916,786; these patents are herein incorporated by reference. These enzymes can be replaced with the particles of the invention containing such enzymes to improve enzyme stability during chemical synthesis.
- Oils can be interesterified or degummed using various enzymes.
- enzymatic interesterification is an efficient way of controlling the melting characteristics of edible oils and fats. This is done by controlling the degree of conversion/reaction. No chemicals are used in the process and no trans fats are formed as in other production methods.
- An immobilized lipase can be used to interesterify fatty acids on oils and fats used in the production of margarine and shortening.
- enzymatic processes can be used to remove gums in vegetable oil; this process is typically called degumming.
- Enzymatic degumming using a phospholipase enzyme converts non- hydratable lecithin (gums) to water-soluble lyso-lecithin, which is separated by centrifugation.
- Gums non-hydratable lecithin
- water-soluble lyso-lecithin which is separated by centrifugation.
- Many of these processes are described in U.S. Patent Nos. 6,162,623, 6,608,223, 7,189,544, and 6,001,640; these patents are herein incorporated by reference. These enzymes can be replaced with the particles of the invention containing such enzymes to improve enzyme stability in such interesterification or degumming processes.
- immobilized enzyme particles can be used in biosensors.
- these biosensors are used in diagnostic methods to sense various analytes in complex mixtures such as body fluids and industrial mixtures.
- various sensors can be used to detect urea, uric acid, and cholesterol in various body fluids.
- Various sensors are described in U.S. Patent No. 5,714,340; this patent is herein incorporated by reference.
- Immobilized enzyme particles can be used in various assay methods to determine the presence and/or concentration of various compounds or organisms in body fluids (e.g., saliva, blood, or urine). These assay methods use various enzymes to interact with an analyte and an enzyme inhibitor; these interactions allow for a large number of molecules to be formed or transformed from detection of one or a few analyte molecules or AKER 10002.1
- the enzyme activity is proportional to the analyte concentration and allows low concentrations of analyte to be detected.
- Analytes can range from small molecule pesticides and other toxins to microbes.
- Various assay probes having a high specificity for capture and detection of particular analytes can be used. Assay methods using enzyme amplification are described in U.S. Patent Nos. 6,171,802, 6,383,763, and 4,067,774; these patents are herein incorporated by reference.
- immobilized enzyme particles can be used for purification of substances and separation of components in mixtures.
- enzymes can be used to separate chiral molecules and isomers from racemic mixtures, to remove sulfur from oils, gases, and other industrial materials, to break down and separate lignocellulose components from plants, to treat and purify wastewater, and for food processing to remove undesirable compounds.
- Desulfurization of oils, gases, and other industrial materials use various enzymes. These enzymes are generally known as desulfurization enzymes.
- One important desulfurization enzyme is desulfinase. These desulfurization enzymes decompose thiophene in various petroleum products and remove sulfur atoms from the petroleum feed stocks prior to combustion. These processes are described in U.S. Patent Nos. 6,461,859 and 7,045,314; these patents are herein incorporated by reference. These enzymes can be replaced with the particles of the invention containing such enzymes to improve enzyme stability during desulfurization.
- Lignin from various plants can be degraded by lignin peroxidase.
- Lignin peroxidase catalyzes a variety of oxidations to result in various cleavage and other oxidation products. These oxidation reactions include carbon-carbon bond cleavage of the propyl side chains of the lignin, hydroxylation of benzylic methylene groups, oxidation of benzyl alcohols to corresponding aldehydes or ketones, and phenol oxidation.
- lignin peroxidase can be immobilized according to the invention to improve enzyme stability.
- Fruit juice is processed using pectinases, amylases, and cellulases that break down various structures of the fruit cells and enhance the juice extraction process. Polysaccharides released from cells during the fruit processing are insoluble in the juice and make the juice cloudy. To clarify the juice, pectinases and amylases are used to break down these insoluble polysaccharides to make soluble sugars. This process results in a AKER 10002.1
- Active surface films are coatings that include reactive substances and/or enzymes that can react with undesired contaminants to be self-cleaning or to remove various toxins from the surface.
- active surface films can be included in food wraps, fibers, surface layers, bandages, or filters to break down toxins or kill bacteria.
- enzymes that degrade various toxins could be included in fibers to destroy toxins used as biological weapons.
- these same fibers could be coated with enzymes that kill or disrupt bacteria to prevent the wearer from contracting a bacterial infection.
- These enzymes can be replaced with the particles of the invention containing such enzymes to improve enzyme stability in such active surface films.
- more than one enzyme can be immobilized to provide a multifunctional material that is able to catalyze more than one reaction.
- a combination of the above described enzymes could be immobilized in one or more enzyme immobilization materials to provide a product that can catalyze more than one reaction.
- the immobilized enzymes described herein it is possible to prepare electrode inks similarly to conventional fuel cell inks.
- the enzyme is encapsulated by an immobilization material using a spray drying technique described herein.
- the stabilized enzyme coated carbon is mixed with carbon filler, 5 % Nafion® solution and then painted onto an electrode support.
- the dried electrode is then pressed to an exchange membrane with a corresponding anode that can be run as a H 2 /O 2 fuel cell.
- an immobilized enzyme for catalyzing a reaction wherein the enzyme is immobilized in an enzyme immobilization material.
- the enzyme immobilization material immobilizes and stabilizes the enzyme, is permeable to a compound smaller than the enzyme, and is a micellar hydrophobically modified polysaccharide.
- an immobilized enzyme for detecting an analyte wherein the enzyme is immobilized in an enzyme immobilization material.
- the enzyme immobilization material immobilizes and stabilizes the enzyme, is permeable to a compound smaller than the enzyme, and is a micellar hydrophobically modified polysaccharide.
- an immobilized enzyme for catalyzing a reaction wherein the enzyme is immobilized in an enzyme immobilization material.
- the enzyme immobilization material immobilizes and stabilizes the enzyme and is permeable to a compound smaller than the enzyme.
- the reaction catalyzed is selected from (a) esterification of a carboxylic acid with an alcohol; (b) liquefaction of corn or other cereals; (c) saccharification of corn or other cereals to convert starch into sugars; (d) isomerization of glucose to fructose; (e) synthesis of chiral compounds; (f) interesterification of oils; (g) degumming oil; (h) treating wastewater (reaction); (i) clarifying fruit juice; (j) producing glucose by the starch process; (k) producing glucose and galactose from lactose; (1) synthesizing compounds having peptide bonds; (m) producing 6-aminopenicillic acid from penicillin G; (n) converting sugars to alcohol; (o) removing sulfur from petroleum fractions; (p) converting acrylonitrile to acrylamide; (q) converting 3-cyanopyridine to nicotinamide; and (r) degrading stains in a laundry soil.
- a further aspect is an improvement in an enzyme -catalyzed reaction selected from esterification of a carboxylic acid with an alcohol, liquefaction of corn or other cereals, saccharification of corn or other cereals to convert starch into sugars, isomerization of glucose to fructose, synthesis of chiral compounds, interesterification of oils, degumming oil, treating wastewater, clarifying fruit juice, producing glucose by the starch process, producing glucose and galactose from lactose, synthesizing compounds having peptide bonds, producing 6-aminopenicillic acid from penicillin G, converting sugars to alcohol, removing sulfur from petroleum fractions, converting acrylonitrile to acrylamide, converting 3-cyanopyridine to nicotinamide or degrading stains in a laundry soil.
- the improvement comprises immobilizing the enzyme in an enzyme immobilization AKER 10002.1
- an immobilized enzyme for detecting an analyte wherein the enzyme is immobilized in an enzyme immobilization material.
- the enzyme immobilization material immobilizes and stabilizes the enzyme and is permeable to a compound smaller than the enzyme.
- the analyte detected comprises urea, uric acid, cholesterol, a pesticide, a toxin, or a microbe.
- an immobilized enzyme for separation or removal of a substances from a mixture wherein the enzyme is immobilized in an enzyme immobilization material.
- the enzyme immobilization material immobilizes and stabilizes the enzyme and is permeable to a compound smaller than the enzyme.
- an immobilized enzyme in a chemically active film surface that reacts with at least one substance contacting the film surface wherein the enzyme is immobilized in an enzyme immobilization material.
- the enzyme immobilization material immobilizes and stabilizes the enzyme and is permeable to a compound smaller than the enzyme.
- the plot represented by the triangles is performance of a prior best cell using a commercial GDL.
- GDL gas diffusion layer
- One of the main factors influencing bioanode performance is the enzyme catalyst support layer, as shown in the previous section. The best performance was from an anode with a dried carbon paste support layer. A picture of this type of cell is shown in Figure 7. This structure acts as a catalyst support, reactant diffusion layer, and an electrical contact layer between the current collector and the catalyst layer. This layer was a mixture of carbon black, meso porous carbon, PTFE, two part epoxy and was applied as a paste to a current collector and frame as a paste made with water and acetone. This paste was allowed to dry prior to the catalyst and modified Nafion layer being applied. This type of material has many advantages as a catalyst support, in the terms of fine tuning the properties.
- This GDL can be made more hydrophobic or hydrophilic by adjusting the ratios of PTFE and meso porous carbon.
- An example of this is shown in Figure 26.
- the GDL material was made more hydrophilic through the inclusion of carbon sieves (represented as diamonds), resulting in improved performance over that of vulcanized carbon alone (represented as triangles).
- the rest of the cell consisted of stainless steel expanded metal current collectors with Au plating for the cathode, Nl 12 as the membrane, cathode is 4 mg/cm Pt black, and 1 % ethanol as the fuel.
- ADH enzyme played another role in the bioanode performance.
- a representative plot of 7 ADH enzymes, including 6 in-house purified PQQ-dependent and 1 commercial NAD-dependent ADH enzymes is given in Figure 27.
- the worst performing enzyme is TBl, which was the oldest enzyme of the lot tested (6 weeks at 4 0 C).
- the best was MLlO, a high purity and concentration enzyme and the freshest of all enzymes when tested.
- the commercial NAD-dependent ADH was shown in this diagram as a point of reference.
- the commercial enzyme's performance was comparable to four of the in-house produced enzymes.
- FIG. 28 An example of the bioanode performance, power densities, in a half cell configuration is shown in Figure 28.
- the anode in this figure has an area of 1 cm and was tested in a 1 M H 2 SO 4 solution with 5 % ethanol.
- the maximum power density achieved with this cell was 15 mW/cm 2 .
- This level of performance was dependent on the quality and type of enzyme used (best performance seen with enzymes purified by applicant), operating conditions (acidic), and type of metal ion activators present in proximity of the mobilized enzyme (nickel).
- FIG. 29A and 29B A representative current versus voltage curve and power curve for a 4 cell stack in series is shown in Figures 29A and 29B.
- the graph on the left represents the performance of a 4 cell (4.5 cm area per cell) biofuel cell stack with a bioanode and an air-breathing platinum cathode.
- the graph on the right represents the average cell voltage and power density of the individual cells of this stack.
- the anode enzyme used in these cells was prepared and purified in-house.
- FIG. 30A and 30B A representative current versus voltage curve and power curve for an 8 cell stack in series is shown in Figures 30A and 30B.
- This stack was the combination of 2 four cell stacks, like the one shown in the previous slide, connected in series.
- the graph on the left represents the performance of a 8 cell (4.5 cm 2 area per cell) biofuel cell stack with a bioanode and an air-breathing platinum cathode.
- the graph on the right represents the average cell voltage and power density of the individual cells of this stack. As the number of cells in the stack was increased, a lower individual cell performance was noticed. AKER 10002.1
- the catalyst support layer used for the anode electrodes was made from a mixture of carbon materials, Teflon, two-part epoxy, and solvents. By varying the ratio of these components, the properties of the structure could be fine tuned. Examples of such properties included: (1) electronic conduction, (2) hydrophobic/hydrophilic nature, (3) surface area, and (4) drying time. This mixture was made up as a paste and then pressed into a Kapton masked frame/current collector structure with excess doctor bladed off. The frame was masked on both sides with cutouts on one side to reveal the exposed current collector. Prior to complete drying and setting of this paste, the Kapton tape mask was removed and the entire structure was allowed to dry under a halogen heating lamp.
- the formulation for GDL paste was prepared from dry components of 3.57 g Monarch 1400 carbon black (Cabot) and 1.43 g Chemsorb 1505 G5 porous, impregnated steam activated carbon (C*Chem). These dry components were charged in a food grinder for 60 seconds. The wet components were prepared separately and were 5.00 g Quick Set 2 part epoxy (The Original Super Glue Corp.), 4.00 g acetone, and 2.00 mL 60 % PTFE dispersion in water (Sigma). The epoxy was dissolved in the acetone before adding the PTFE dispersion. The wet components were mixed with an ultra sonic homogenizer for 15 seconds. The dry and wet mixtures were combined and mixed with a putty knife until the mixture had the consistency of toothpaste.
- C*Chem carbon black
- the wet components were prepared separately and were 5.00 g Quick Set 2 part epoxy (The Original Super Glue Corp.), 4.00 g acetone, and 2.00 mL 60 % PTFE dispersion
- the enzyme catalyst layer was applied to the surface of the dried GDL structure as a cast mixture of enzyme in buffer solution and TBAB modified Nafion immobilization material. The solution was allowed to dry and cure prior to joining with a corresponding cathode structure.
- a volume of casting solution was made to provide enough for eight cells (4.5 cm 2 ) and from this casting solution an aliquot of 0.45 mL is cast to each electrode.
- the casting solution was 2.1 mL of PQQ dependent ADH (- 10 mg/mL) in PBS buffer and 2.1 mL of 5 % by volume tetrabutyl ammonium bromide modified Nafion immobilization material. AKER 10002.1
- FIG. 8 The components for the anode current collector and frame assembly are shown in Figure 8.
- the construction starts by melting two pieces of urethane hot melt pieces to one side of each vinyl frame cutout. The melting was done by exposing the frame with the hot melt pieces laid out on top to 128°C temperatures for 30 seconds. The pieces were then removed and allowed to cool until the adhesive was just tacky to touch. Expanded metal current collectors with wires woven and pressed (8 metric tons) were arranged onto one of the frame structures in a configuration shown in Figure 8 with the wire leads fixed along the sides of the frame in the hot melt glue. The other frame was set on top of the current collector/frame/adhesive structure with the glue side towards the expanded metal current collector. This whole assembly was then pressed at minimal pressure and 128°C temperature for 30 seconds to seal the structure.
- the catalyst support layer used for the anode electrodes was a commercially available carbon cloth GDL material.
- the material was designated by E-Tek as LT2500W Low Temperature Elat with a microporous layer on either side.
- the current collector used for this cathode was a 0.007" thick expanded stainless steel material that was cut to size with a 28 gauge insulated wire woven and pressed along one edge to make a flag-like structure.
- the exposed conductive portions of this cathode flag were acid etched (5 M HCl) and gold electroplated using an Orthotherm HT RTU rack gold bath (Technic Inc.) prior to assembly of the cathode electrode.
- the cathode catalyst layer consisted of platinum black catalyst and Nafion ionomer with respective loadings of 4 mg/cm 2 and 8.5 weight %.
- the catalyst was prepared as an ink and painted onto a piece of Elat that was big enough for 8 electrodes (36 cm 2 ) and was allowed to dry. When the catalyst layer was dry, the sheet was cut into individual electrodes with and area of 4.5 cm (3 x 1.5 cm) and set aside until final assembly.
- a volume of casting solution sufficient for preparation of eight cells (4.5 cm 2 ) was prepare.
- the casting solution was made up of 158.4 mg of HiSPECTM 1000 AKER 10002.1
- the cathode was fabricated as one piece including the current collector, GDL/catalyst layer, and Nafion immobilization material.
- the Nafion immobilization material Nafion 212 (Sigma Aldrich) was cut into pieces slightly larger than the GDL layer and then wetted with DI water.
- the catalyst/GDL layer was positioned on top of the expanded metal current collector, painted with a thin coat of 5 wt.% Nafion solution, and wetted with DI water. A top of this assembly was placed the wetted Nafion membrane and the whole structure was placed between 2 sheets (3 x 3") of Kapton, 0.010" thick (McMaster-Carr).
- the Kapton film served as a press package and release film.
- the whole package was pressed at a pressure of 3 metric tons and 128°C for 90 seconds and then cooled between two 1" thick aluminum plates.
- the Kapton films were removed and the cathode was trimmed to size (3.75 x 1.7 cm) prior to placement in the frames.
- FIG. 8 The components for the cathode current collector and frame assemble are shown in Figure 8.
- Four prefabricated cathodes were arranged onto one of the frame structures in a configuration shown in Figure 8 with wire leads fixed along the sides of the frame in the hot melt glue.
- the other frame was set on top of the current collector/frame/adhesive structure with the glue side being towards the expanded metal current collector. This whole assembly was then pressed at minimal pressure and 128°C temperature for 30 seconds to seal the structure.
- the fuel delivery manifold designed for this device offered advantages for this type of fuel cell with an electrolyte fuel solution that would short cells in a conventional liquid fuel cell (i.e., direct methanol fuel cell). Fuel was delivered to AKER 10002.1
- the fuel reservoir system for this device was designed to eliminate fuel/electrolyte contact between cells by using individual reservoirs for each cell. Unique features of this tank was the stepped top of the reservoir, shown in Figures 4 and 5. This allowed for the complete filling of the stack and eliminated trapped air bubbles from coming in contact with the anodes. Fuel was brought in the lower step of the tank and exited out of the upper step where any trapped air was pushed out of electrode contact. A set of four fuel cells were attached to the reservoir with the anode side towards the fuel, using 0.005" thick hot melt urethane adhesive melted at 128 0 C at a minimal pressure.
- the housing for the eight-cell biofuel cell stack is shown in Figures 2 and 13.
- the final housing design was machined out of 0.600" thick acrylic and featured support pedestals for the electrode structure in the center of the housing half, fuel manifold system cutouts on the side of the housing, and cutouts on either end for electronics and IO interface.
- the stack was inserted between two housing halves and the housing was bolted together with 1" liing 8/32 hex head bolts in each of the four corners of the stack.
- the two halves were seal together using a 0.020" thick PTFE gasket that surrounded the perimeter.
- CoPcF deposited in carbon supported polypyrrole (typically, 5-60% by weight) exhibited exceptional activity for oxygen reduction once it was appropriately pyrolyzed at high temperatures.
- the combination of CoPcF - carbon supported polypyrrole composite and appropriate pyrolysis made the composite catalyst CoPcFPPy very unique. These catalysts were evaluated in an air-breathing half cell with 1.0 M sulfuric acid solution (with or without phosphotungstic acid (PTA) promoter), at AKER 10002.1
- CPPy - carbon supported polypyrrole CoPc - cobalt phthalocyanine
- CoPcF Cobalt(II) 1,2,3,4,8,9,10,1 l,15,16,17,18,22,23,24,25-hexadecafluoro-29H,3 IH- phthalocyanine (CoPcF) (100 mg, Sigma) and 200 mg carbon-supported polypyrrole (PPy/C) (Sigma) were dispersed in 4 mL tetrahydrofuran (Sigma) in an ultrasonic bath for 10 minutes and then the solvent was evaporated in a vacuum oven at room temperature for 1 hour. The dry powder was then placed in a crucible and heat-treated in nitrogen atmosphere furnace at 600 0 C for 1 hour.
- CoPcFCPPy 10 mg
- 60 mg Nafion solution 5%, Sigma
- ELAT 1 cm gas diffusion layer
- PTA phosphotungstic acid
- 1 mg PTA was dissolved and 10 mg CoPcFCPPy and 60 mg Nafion solution (5%, Sigma) were dispersed in 200 ⁇ L isopropanol in an ultrasonic bath for 10 minutes and the mixture was slowly coated onto the active side of a 1 cm 2 gas diffusion layer (ELAT, A7NCV2.1) and then placed in a vacuum oven at room temperature for 30 minutes.
- ELAT 1 cm 2 gas diffusion layer
- CoPcFPPy prepared as described in example 1 exhibited no activity loss (Figure 32) when the electrolyte solution contained 15 or 30% ethanol that was saturated by oxygen. This indicated that the catalyst exhibited good alcohol tolerance. Better AKER 10002.1
- the CoPcFCPPy cathode had a much higher current density for the oxygen reduction (see Figure 34); it was about 65 mA/cm 2 initially and decayed to 58 mA/cm 2 in an hour.
- the CoPcFCPPy with PTA catalyst resulted in a cathode that had an even higher current density than that of CoPcFCPPy without PTA.
- the current density decayed from 82 to 73 mA/cm 2 in an hour.
- CoPcFCPPy with or without PTA did not catalyze ethanol oxidation, as shown in figures B.3 and B.7, and had high selectivity for the oxygen reduction reaction.
- CoPcFCPPy catalysts An increase in catalytic activity was observed after high-temperature heat treatment of CoPcFCPPy catalysts, as shown in Figure 37.
- the carbon supported PPy provided a carrier with high electronic conductivity and high surface area for immobilizing CoPcF for enhancing electrocatalytic activity.
- PPy may provide nitrogen atoms to coordinate with cobalt atoms in CoPcF.
- porphyrin consists of four pyrrole units
- the coordination of the Co atom in CoPcF with nitrogen atoms of the pyrrole unit in PPy may mimic catalytic function of Co porphyrin. Consequently, the CoPcFCPPy catalyst composite may integrate CoPcF function and Co Porphyrin function. Heat treatment at high temperatures may partially break down the CoPcF structure and the PPy chain, providing more opportunity for Co atoms to coordinate with nitrogen atoms of the pyrrole units.
- CoPcF (3.3 mg, Sigma), 6.7 mg PPy/C (Sigma) and 60 mg Nafion solution (5%, Sigma) was dispersed in 200 ⁇ L isopropanol in an ultrasonic bath for 10 minutes and the mixture was slowly coated onto the active side of a 1 cm 2 gas diffusion layer (ELAT, A7NCV2.1) and then placed in a vacuum oven at room temperature for 30 minutes.
- ELAT 1 cm 2 gas diffusion layer
- Example 13 Carbon black supported CoPcF pyrolyzed at 600 0 C
- CoPcF catalyst containing PPy exhibited increased oxygen reduction activity as compared to a CoPcF catalyst supported only on carbon black (Monarch 1000).
- the activity for the oxygen reduction reaction is lower than CoPcFCPPy ( Figure 31) even AKER 10002.1
- the catalyst is pyrolyzed at 600 0 C ( Figure 38). Also, the catalyst without PPy does not have good ethanol tolerance.
- CoPcF 100 mg, Sigma
- 200 mg carbon black (Monarch 1000) was dispersed in 4 mL tetrahydrofuran (Sigma) in an ultrasonic bath for 10 minutes and then the solvent was evaporated in a vacuum oven at room temperature for 1 hour.
- the dry powder was placed in a crucible and heat treated in a nitrogen atmosphere furnace at 600 0 C for 1 hour.
- the resulting catalyst was designated CoPcF/C.
- CoPcF/C (10 mg) and 60 mg Nafion solution (5%, Sigma) was dispersed in 200 ⁇ L isopropanol in an ultrasonic bath for 10 minutes and the mixture was slowly coated onto the active side of a 1 cm 2 gas diffusion layer (ELAT, A7NCV2.1) and then placed in a vacuum oven at room temperature for 30 minutes.
- ELAT 1 cm 2 gas diffusion layer
- CoPc cobalt phthalocyanine
- CoPcCPPy Preparation of CoPcCPPy.
- CoPc 100 mg, Sigma
- 200 mg PPy/C 200 mg
- THF THF
- the dry powder was placed in a crucible and heat treated in a nitrogen atmosphere furnace at 600 0 C for 1 hour.
- the resulting catalyst was designated as CoPcCPPy.
- CoPcCPPy (10 mg) and 60 mg Nafion solution (5%, Sigma) was dispersed in 200 ⁇ L isopropanol in an ultrasonic bath for 10 minutes and the mixture was slowly coated onto the active side of a 1 cm 2 gas diffusion layer (ELAT, A7NCV2.1) and then placed in a vacuum oven at room temperature for 30 minutes.
- ELAT 1 cm 2 gas diffusion layer
- the pH 5 acetate buffer was prepared by dissolving 12.0 g acetic acid and 28.7 g sodium acetate in 1 liter D.I. water.
- BOD bilirubin oxidase
- MWCNT/Torey carbon paper electrode Direct electron transfer between bilirubin oxidase (BOD) and MWCNT/Torey carbon paper electrode was observed in nitrogen saturated acetate buffer solution, as shown in Figure 40.
- the redox potential of BOD is about 0.4 V.
- a catalytic current of oxygen reduction reaction starts appearing at about 0.8 V and rapidly increases at the potential close to the redox potential of BOD.
- laccases There are three groups of laccases that are classified by the redox potential of the Tl site and their primary structures, namely low, middle, and high redox potential enzymes.
- the values of the redox potentials of the Tl site vary between 430 and 790 mV vs. NHE. Since the direct electron transfer behaviors of the enzymes have been successfully observed, one expects that an appropriate laccase may catalyze oxygen reduction reaction at a higher potential that is good for fuel cell voltage.
- CNTs carbon nanotubes
- BOD bilirubin oxidase
- SWCNTs single wall carbon nanotubes
- hydroxyl-functionalized MWCNTs outperform original MWCNTs and carboxyl-fuctionalized MWCNTs for BOD-catalyzed oxygen reduction reaction (ORR) at the air-breathing cathode, as shown in Figure 43.
- Carbon blacks also facilitate direct electron transfer of enzymes.
- BOD-catalyzed ORR at XE2 -based gas diffusion electrode (GDE) is comparable with the one at MWCNT -based GDE in low current density region, and better than ones at XE2B and XPB F138-based GDEs, as shown in Figure 44.
- E-Tek carbon cloth double sided waterproofing, DS
- water-proofing materials coated on both sides is one of the best- performing commercially available GDE materials.
- This GDE (E-Tek , DS) only has water-proofing treatment, which can be used in polymer electrolyte membrane (PEM) fuel cells to protect the cathode from flooding.
- PEM polymer electrolyte membrane
- the cathode enzyme activity must be maintained to facilitate direct electron transfer and the GDE comes into direct contact with the electrolyte solution so there is ionic conductivity in the GDE, and concurrently allow sufficient ambient air to naturally diffuse (breath) through the GDE.
- the solvent in the coated film was evaporated by hot-pressing the film at a pressure of 50 - 10000 pounds at 50 - 120 0 C.
- the PTFE content in the coated film was varied from 0 wt.% to 80 wt.%.
- a more important step was that the pore distribution in the coated film was controlled by adding a pore- forming reagent (e.g. 0.1 - 20 wt.% ammonium carbonate solution) in the film and then heat-decomposing the reagent at 40 - 90 0 C. Finally, a desired GDE was obtained.
- a pore- forming reagent e.g. 0.1 - 20 wt.% ammonium carbonate solution
- laccase-catalyzed ORR can be obtained by immobilized laccase onto functionalized MWCNTs, which is coated on GDEs.
- Functional groups in carbon nanotubes include hydroxyl, carboxyl, thiol, and amino.
- BOD adsorbed on a plain carbon cloth does not exhibit efficient direct electron transfer and hence BOD-catalyzed ORR current at the cloth electrode is less than 0.1 mA/cm 2 at 0.2 V.
- the cloth can be activated by heating the cloth at temperatures between 500 and 900 0 C for 1 - 20 AKER 10002.1
- the BOD-activated cloth electrode exhibited a significantly high ORR current (1.7 mA/cm ) at 0.2 V ( Figure 46).
- the activation technique provided a useful means for facilitating direct electron transfer of enzymes.
- Example 16 CuPCTSA-TBAB coated poly(styrene-co-divinylbenzene)
- poly(styrene-co-divinylbenzene) particles were coated with a mixture of tetrabutylammonium bromide (TB AB)-modified Nafion® immobilization material and a water soluble dye that acts as an electron mediator for enzymatic reduction of oxygen to water.
- TB AB tetrabutylammonium bromide
- a dye solution of 0.080 g copper (II) phthalocyanine tetrasulphonic acid (CuPCTSA) in 4.00 mL TBAB modified Nafion® (5 wt%) in ethanol was combined with a particle suspension of 2.00 g poly(styrene-co- divinylbenzene) particles in 4.00 mL 0.5 M phosphate buffer, pH 7.2.
- the dye solution was added to the particle suspension and vortex mixed for several seconds until a substantially uniform mixture was achieved.
- the entire mixture was then airbrushed onto a polycarbonate shield. The mixture was allowed to dry on the shield for 20 minutes before being collected and stored dry in a scintillation vial.
- the resulting coated particles were blue in color and retention of the dye was confirmed by packing the coated particles in a column and passing several hundred mL of water across them. No detectable levels of dye were found in the mobile phase eluting from the column.
- the thickness of the coating layer was designed to be 0.07 micron thick and the average diameter of the particles before coating was 8 microns.
- the surface area of the particles (pre-coated) was calculated to be 0.75 m/g 2 .
- the resulting loading of the electron mediator was 4 wt%.
- Example 17 Alcohol dehydrogenase-TBATFB coated doped polypyrrole/carbon black composite
- Doped polypyrrole/carbon black composite (Sigma, catalog number 530573) particles were coated with a mixture of tetrabutylammonium tetrafluoroborate (TBATFB)- modified Nafion® immobilization material and alcohol dehydrogenase enzyme.
- TBATFB tetrabutylammonium tetrafluoroborate
- the resulting coated particles were black in color and retention of the enzyme activity was confirmed using standard spectrophotometric assay and electrochemical evaluation. The evaluation was made versus a normal hydrogen reference electrode (NHE). See Figure 49. The resulting loading of the enzyme was 6.25 wt%.
- Example 18 Alcohol dehydrogenase-Ru(II)(NH 3 ) 6 -TBATFB coated doped polypyrrole/carbon black composite
- a suspension containing 6.00 mL 0.5 M phosphate buffer (pH 7.2), 2.00 mL TBATFB modified Nafion (5 wt%) in ethanol, and 2.00 g doped polypyrrole/carbon black composite was also prepared.
- the solution and suspension were combined and vortex mixed for several seconds to form a substantially uniform mixture.
- the entire mixture was then airbrushed onto a polycarbonate shield in a process similar to Example 16.
- the resulting product was stored dry in a scintillation vial at 4 0 C.
- the resulting coated particles were black in color and retention of the enzyme activity was confirmed using standard spectrophotometric assay. The coating thickness was not calculated due to the unknown surface area of the particles. The resulting loading of the enzyme and electron mediator was 10.3 and 12.8 wt%, respectively.
- Enzyme immobilization materials tested were Nafion® modified with tetrapropropylammonium bromide (TPAB), tetrabutylammonium bromide (TBAB), triethylhexylammonium bromide (TEHA), trimethylhexylammonium (TMHA), trimethyloctylammonium (TMOA), trimethyldecylammonium (TMDA), trimethyldodecylammonium (TMDDA), trimethyltetradecylammonium (TMTDA), trimethylhexyldecylammonium (TMHDA), trimethyloctyldecylammonium (TMODA), butyl modified chitosan suspended in acetate buffer (Chitosan AB), and butyl modified chitosan suspended in t-amyl alcohol (Chitosan TB).
- the enzyme immobilization material that provided the greatest relative activity for the starch consuming amylase
- Example 20 Maltose consuming amylase enzyme activity
- Example 19 The procedure described in Example 19 was used to determine the activity of maltose consuming amylase immobilized in various enzyme immobilization materials. The published procedure was modified as described in Example 19 and further modified by substituting maltose for starch. Enzyme immobilization materials tested were Nafion® modified with tetrapropropylammonium bromide (T3A), tetrabutylammonium bromide (TBAB), tetrapentylammonium bromide (T5A), triethylhexylammonium bromide (TEHA), trimethylhexylammonium (TMHA), trimethyloctylammonium (TMOA), trimethyltetradecylammonium (TMTDA), medium molecular weight decyl modified chitosan (Decyl M), low molecular weight butyl modified chitosan (Butyl L), low molecular weight octyl modified chitosan (O
- a bioanode catalyst support electrode with an expanded metal support and current collector and a polymer pore forming agent was prepared.
- the expanded metal support was used in preparing this formulation; the ratio of graphite fibers to conductive carbon black (1:4) and the ratio of polymeric binder to carbon solids (0.8:2.5) results in a structure that is highly conductive but is not self-supporting. Without the expanded metal, the carbon electrode could break during handling and thus, could not be considered for MEA fabrication.
- the materials used for this electrode are the preferred materials, but other substitutions can be made for the carbon black and binder materials (Tables 1 and 3).
- the dry components of the GDL paste were 4.00 g Monarch 1400 carbon black (Cabot), 1.00 g Milled XN-100 graphite fibers, 150 micron long (Nippon Graphite Fiber), 1.60 g poly(vinylidene fluoride) powder as polymeric binder (Sigma), and 2.00 g poly(ethylene glycol) 8,000 molecular weight as the polymeric pore forming agent (Sigma).
- the dry components were mixed in a food processor for 1 minute.
- the solvent of the GDL paste was 4.00 mL ethanol and was added incrementally until the desired consistency was reached.
- a bioanode catalyst support electrode with an expanded metal support and current collector and a polymer pore forming agent was prepared.
- the expanded metal support was unnecessary for this formulation due to the equal ratio of graphite fibers to conductive carbon black and the higher ratio of polymeric binder to carbon solids (1 :2).
- This formulation resulted in a structure that is slightly less conductive than the bioanode catalyst support Example 21, but unlike that support, it was self-supporting.
- This electrode material can be wet but does not adsorb electrolyte like the previous example due to the lack of pore forming agents in the formulation.
- This type of electrode can be handled in a similar fashion as commercial GDL and can be considered for MEA fabrication.
- the materials used for this electrode are the preferred materials, but other substitutions can be made for the carbon black and binder as detailed in (Tables 1 and 3).
- the dry components of the GDL paste were 3.00 g Monarch 1400 carbon black (Cabot), 3.00 g DKDX graphite fibers, 150 micron long (Cytec Carbon Fibers), 3.00 g poly(vinylidene fluoride) powder (Sigma).
- the dry components were mixed in a food processor for 1 minute.
- the solvent of the GDL paste was 3.00 mL n-propanol and was added incrementally until the desired consistency was reached.
- a bioanode catalyst support electrode with a mesoporous carbon inclusion and pore forming agent was prepared to promote greater electrolyte/electrode interaction and to increase the available electrode surface area for enzyme catalyst loading.
- This formulation used a ratio of graphite fibers to conductive carbon black to mesoporous carbon of 2: 1: 1 and a ratio of polymeric binder to carbon solids of 1:3.
- the resulting structure that was comparable in electrical conductivity to that of bioanode catalyst support 2.
- This electrode material could be wetted and absorbed electrolyte and enzyme casting inks better than other examples and listed commercial GDL materials due to the pore forming agents and mesoporous carbon in the formulation.
- This type of electrode could be handled similarly to commercial GDL and could be used in MEA fabrication.
- the materials used for this electrode were the preferred materials, but other substitutions could be made for the carbon black and binder (Tables 1 and 3). AKER 10002.1
- the dry components of the GDL paste were 1.50 g Monarch 1400 carbon black (Cabot), 3.00 g DKDX graphite fibers, 150 micron long (Cytec Carbon Fibers), 1.50 g Chemsorb 1505 G5 porous, impregnated steam activated carbon (C*Chem), 2.00 g poly(vinylidene fluoride) powder (Sigma), and 1.50 g poly(ethylene glycol) 8,000 molecular weight (Sigma).
- the activated carbon was briefly ground by hand using a ceramic mortar and pestle before its incorporation and the dry components were mixed in a food processor for 1 minute.
- the solvent was -3.00 mL n-propanol and was added incrementally until the desired consistency was reached.
- the dry components were combined with a spatula in a small beaker until the mixture reached a consistency of toothpaste.
- the paste was then spread into the frame structure and PTFE coated fiberglass sheet structure and sintered at 200 0 C for 20 minutes.
- the frames were removed and the electrodes were soaked in DI water for 30 minutes with periodic water replacements to remove the poly(ethylene glycol).
- the electrodes were then sintered again at 200 0 C for 10 minutes.
- the electrodes were cooled to room temperature and were ready for use as a bioanode catalyst support and electrode.
- the resulting electrodes were rigid, could be cut with scissors, and acceptably soaked up water and electrolyte.
- the in-plane conductivity was ⁇ 50 % relative to that of commercial GDL materials.
- This bioanode catalyst support includes a doped conductive polymer that is chemically grafted onto the carbon black material and a pore forming agent that thermally decomposes during sintering. The use of the new pore forming agent reduces the process time for fabrication and eliminates the water soak and second sintering steps.
- This electrode material could be wetted, adsorbed electrolyte like the previous examples, and could participate in the electron transfer reaction between the enzyme and the electrode. This type of electrode could be handled similarly to a commercial GDL and could be used in MEA fabrication. The materials used for this electrode were the preferred materials, but other substitutions could be made for the carbon black and binder (Tables 1 and 3). AKER 10002.1
- the dry components of the GDL paste were 3.00 g Monarch 1400 carbon black grafted with 8-hydroxypyrene trisulfonic acid doped poly(pyrrole), 3.00 g DKDX graphite fibers, 150 micron long (Cytec Carbon Fibers), 3.00 g poly(vinylidene fluoride) powder (Sigma), and 2.00 g ammonium carbonate (Sigma). These dry components were mixed in a food processor for 1 minute. The solvent in the GDL paste was -4.00 mL ethanol and was added incrementally until the desired consistency was reached.
- a biocathode catalyst support electrode using a polymer pore forming agent to increase the surface area of the electrode for enzyme interaction and to improve mass transport of products and reactants of the cathode reaction was prepared.
- the use of an expanded metal support was not needed for this formulation because the ratio of graphite fibers to conductive carbon black and the higher ratio of polymeric binder to carbon solids ( ⁇ 1 :2) resulted in a structure that is self-supporting. This structure also exhibits conductivity similar to commercial carbon cloth GDL materials.
- This electrode material was very hydrophobic but could be wetted by alcohol mixtures of enzyme and ionomer during enzyme deposition.
- a micro pore forming agent in this electrode was used to improve surface area for better enzyme electrode interaction.
- the dry components of the GDL paste were 4.00 g Monarch 1400 carbon black (Cabot), 4.00 g DKDX graphite fibers, 150 micron long (Cytec Carbon Fibers), 1.50 AKER 10002.1
- a biocathode catalyst support electrode that was similar in physical properties as Biocathode Catalyst Support 1 but differed in the use of carbon black conductivity component and the ratios of PVDF to PTFE.
- This support material incorporated a doped conductive polymer that was chemically grafted onto the carbon black material. This doped conductive polymer was carefully grafted in such a way that it formed nano-whisker structures that were useful in interacting with the metal center of the enzyme where electron transfer occurs for greatly improved direct electron transfer rates.
- Example 25 When this modified carbon was used, the 300 0 C sintering temperature step in Example 25 was removed to prevent softening or melting the polymer nanostructures and the ratio of binders were altered to increase the PVDF and decrease the PTFE because PTFE required higher sintering temperatures.
- This electrode material was hydrophobic with partial hydrophilicity, had a high surface area, and facilitated the direct electron transfer reaction between the enzyme and the electrode. This type of electrode was handled similarly to commercial GDL and was used in MEA fabrication. The materials used for this electrode were preferred materials, but other substitutions could be made for the carbon black, pore forming agents, and binder (Tables 1 and 3).
- the dry components of the GDL paste were 4.00 g Monarch 1400 carbon black grafted with l-(3-Sulfopropyl)pyridinium hydroxide inner salt doped poly(pyrrole) nano-whiskers, 4.00 g DKDX graphite fibers, 150 micron long (Cytec Carbon Fibers), 3.00 AKER 10002.1
- a bi-layer biocathode catalyst support electrode having air-breathing and enzyme sides and having an expanded metal support as a current collector was prepared.
- the expanded metal support was necessary for this formulation due to the combinations of electrode layers and the low ratio of polymeric binder to carbon solids (e.g., 1 : 10) on the enzyme side of the electrode.
- a preferred configuration is having a microporous and slightly hydrophilic structure on the enzyme side of the electrode to increase the interaction between the enzyme and electrolyte, but also providing a dense, air permeable, and hydrophobic structure on the air side in order to manage water and retain electrolyte in the cell. This was accomplished by using a bi-layer structured electrode. This bi-layer electrode required a multi-step fabrication and sintering process. The materials used for this electrode were the preferred materials, but other substitutions could be made for the carbon black and binder (Tables 1 and 3).
- the dry components of the GDL paste for the air-breathing side of the electrode were 4.00 g Monarch 1400 carbon black (Cabot), 1.00 g Milled XN-100 graphite fibers, 150 micron long (Cytec Carbon Fibers), and 2.50 g polytetrafluoroethylene powder (Sigma). These dry components were mixed in a food processor for 1 minute. The solvent used in the GDL paste was -4.00 mL 1-propanol and was added incrementally until the desired consistency was reached.
- the dry components of the GDL paste for the enzyme side of the electrode were 2.00 g Conductive Polymer Modified Monarch 1400 carbon black (Cabot), 0.50 g AKER 10002.1
- Milled XN-100 graphite fibers 150 micron long (Cytec Carbon Fibers), 0.25 g polytetrafluoroethylene powder (Sigma), and 1.00 g ammonium carbonate (Sigma). These dry components were mixed in a food processor for 1 minute. The solvent used in the GDL paste was -4.00 mL 1-propanol and was added incrementally until the desired consistency was reached.
- Biocathode Catalyst Support 1 A comparison of Biocathode Catalyst Support 1 and a commercial cathode GDL of Double Sided Elat (BASF), is given in Figure 54 for a laccase based biocathode with oxygen as the oxidant and a platinum black on Elat anode fueled with hydrogen. Nafion 115 was used as the polymer electrolyte membrane in this hot-pressed MEA. The activity of the biocathode was based on DET and there was no electron transfer mediator present in the catalyst layer. The two systems compared similarly across the polarization range. The biocathode support layer was a uniform biocathode support layer and was not optimized for mass transport of products or reactants. Further, no pore forming agents were used, which resulted in a decreased surface area.
- BASF Double Sided Elat
- Example 29 l-(3-Sulfopropyl)pyridinium hydroxide doped polyaniline nanowires grafted on carbon black particles
- reaction medium temperature should not rise above 5 0 C at this stage, otherwise, macroscopic fibers will be obtained instead of nanowires.
- Example 30 1,5-Naphthalenedisulfonic acid doped polyaniline nanowires grafted on carbon black particles
- Deionized water 300 mL was transferred into a one-liter size beaker and the beaker was placed in an ice-bath.
- Glacial acetic acid (10 mL, 99%) was added into the beaker and continuously stirred for 20 minutes to lower the temperature of the liquid in the beaker, preferably close to 5°C.
- 40 grams of Monarch 1400 (Cabot) carbon black was added into the acidic solvent. This carbon slurry was continuously stirred for 10 minutes. Then, a mixture of 8 grams of 1,5- naphthalenedisulfonic acid tetrahydrate (97%, Sigma) dissolved in 50 mL deionized water was added.
- Example 31 2-Naphthalenesulfoniuc acid doped polyaniline nanowires grafted on carbon black particles
- Example 32 l-(3-Sulfopropyl)pyridinium hydroxide doped polyaniline nanowires grafted on carbon black particles
- Deionized water 300 mL was transferred into a one-liter size beaker and the beaker was placed on a stir plate. Glacial acetic acid (10 mL, 99%) was added into the beaker and continuously stirred for 20 minutes at room temperature (approximately 24 0 C). Black Pearls 2000 carbon black (20 grams, Cabot) was added into the acidic solvent. This carbon slurry was continuously stirred for 30 minutes. Then, a mixture of 8 grams of l-(3- Sulfopropyl)pyridinium hydroxide inner salt (Sigma) dissolved in 50 mL deionized water was added.
- aniline monomer was added dropwise to the above mixture and the whole mixture was stirred for another 20 minutes.
- a mixture of 10 grams of ferric (III) chloride dissolved in 60 mL deionized water was added dropwise over the course of two hours. Once all of the ferric chloride solution was added, the slurry was continuously stirred for two hours at room temperature. The carbon slurry was vacuum filtered and washed with copious amounts of water to remove the acid. Then, the modified carbon was dried under vacuum at 100 0 C for 10 hours.
- Example 33 Sulfonated l-(3-Sulfopropyl)pyridinium hydroxide doped polyaniline nanowires grafted on carbon black particles for high power output biocathode
- Deionized water 300 mL was transferred into a one-liter size beaker and the beaker was placed in an ice-bath.
- Glacial acetic acid (10 mL, 99%, Sigma) was added into the beaker and continuously stirred for 20 minutes to lower the temperature of the liquid in the beaker, preferably close to 5°C.
- 40 grams of Monarch 1400 (Cabot) carbon black was added into the acidic solvent. This carbon slurry was continuously stirred for 10 minutes. Then, a mixture of 8 AKER 10002.1
- the slurry was continuously stirred for 24 hours in the ice bath. After the first 24 hours stirring, a mixture of 6 mL concentrated sulfuric acid (97%) and 12 mL of glacial acetic acid (97%) were added dropwise while the beaker was still in the ice-bath. The slurry was stirred for one hour, and then vacuum filtered and washed with copious amounts of water. Finally, the modified carbon was dried under vacuum at 100 0 C for 10 hours.
- Example 34 Encapsulated Enzyme/Carbon Diffusion Electrode 1 : ADH immobilized Anode half cell
- Alcohol dehydrogenase was encapsulated onto a carbon black powder, dried, and pasted into an electrode via the procedure described above.
- PVDF was used as binder
- DKDX graphite fibers were used to give the electrode rigidity
- Printex XE 2 was used as filler
- poly(ethylene) glycol was the hydrophilic agent.
- the paste formulation was 0.5 g ADH encapsulated carbon, 0.45 g Printex XE 2, 0.25 g DKDX, 0.25 g PVDF, and 0.5 g Poly(ethylene) glycol.
- Methanol was mixed into the paste in a sufficient quantity to give it a thick consistency and electrodes were made according to the procedure described in Example 21. The half cell was then tested for enzymatic response to methanol to verify enzyme activity, which showed positive response. The results are given in Figure 58.
- Example 35 Encapsulated Enzyme/Carbon Diffusion Electrode 2: Mediated ADH immobilized Anode half cell AKER 10002.1
- Alcohol dehydrogenase was encapsulated onto a carbon black powder, dried, and pasted into an electrode via the procedure described above.
- the components were the same as described for Encapsulated Enzyme/Carbon Diffusion Electrode 1 in example 34.
- the paste formulation was 1.09 g ADH encapsulated carbon, 0.5 g DKDX, 0.5 g PVDF, and 0.5 g Poly (ethylene) glycol. Methanol was mixed into the paste in a sufficient quantity to give it a thick consistency and electrodes were made according to the procedure described above. Without the Printex XE 2 carbon filler in the formulation, it was necessary to use a mediator to observe enzymatic response. For this example, Hexamine ruthenium(III) chloride (Sigma) was used in solution. It was also possible to encapsulate soluble mediators with the enzyme and observe a response. The results are shown in Figure 59.
- the electrode was able to show a catalytic response at the mediator peak around 0.65 V versus NHE.
- Example 36 Biocathode Ink Formulation 1: Immobilized enzyme onto an ELAT GDL support
- Electrodes were painted onto an ELAT support structure using enzyme encapsulated carbon.
- plain carbon black particles were used as filler material in the ink, where the other formulation simply had enzyme encapsulated carbon and Nafion solution.
- the carbon filler-based ink formulation included 160 mg Laccase encapsulated carbon, 320 mg Monarch 1400, and 2.0 mL of 5 % Nafion solution.
- the ink formulation with no carbon filler included 160 mg Laccase encapsulated carbon and 0.667 mL of 5% Nafion solution.
- the enzyme encapsulated solution was added to a plastic vial.
- the carbon filler was added and vortexed for approximately 30 seconds.
- Nafion solution was added and the slurry was stirred with a spatula until all of the particles were wet.
- the ink was mixed with a Fisher Scientific Sonicating Dismembrator for as little time as necessary to make an even consistency ink.
- the inks were painted onto double sided ELAT and they were then pressed onto Nafion 115 membrane opposing a platinum black electrode at 125 0 C for 35 seconds.
- Example 37 Biocathode Ink Formulation 2: Varying the amount of carbon filler in the ink formulation
- Increasing the amount of carbon black increased the performance of the electrode as shown in Figure 61 until a critical enzyme based catalyst layer thickness was reached where the performance began to degrade due to reactant and proton transport limitations.
- Three electrode formulations were chosen, using 320 mg, 240 mg, and 400 mg of Monarch 1400 carbon to help support direct electron transfer to the enzyme.
- the 320 mg Carbon Filler Ink Formulation was prepared from 160 mg Laccase encapsulated carbon, 320 mg Monarch 1400, and 2.0 mL of 5 % Nafion solution.
- the 240 mg Carbon Filler Ink Formulation was prepared from 160 mg Laccase encapsulated carbon, 240 mg Monarch 1400, and 2.0 mL of 5 % Nafion solution.
- the 400 mg Carbon Filler Ink Formulation was prepared from 160 mg Laccase encapsulated carbon, 400 mg Monarch 1400, and 2.0 mL of 5 % Nafion solution.
- Example 36 The ink formulations were prepared as described in Example 36 where the dry carbon was vortexed with the enzyme encapsulated carbon prior to adding the Nafion solution. The inks were then sonicated and painted onto ELAT. They were pressed onto Nafion 115 membrane opposing a platinum black electrode at 125 0 C for 35 seconds.
- Example 38 Biocathode Ink Formulation 3: Varying the type of carbon black used as filler
- the Monarch 1400 carbon filler ink formulation was prepared from 80 mg Laccase encapsulated carbon, 80 mg Monarch 1400, and 1.0 mL of 5 % Nafion solution.
- the polypyrrole doped carbon black carbon filler ink formulation was prepared from 80 mg Laccase encapsulated carbon, 80 mg polypyrrole doped carbon black, and 1.0 mL of 5 % Nafion solution.
- the Pure Black 115 ink formulation was prepared from 80 mg Laccase encapsulated carbon, 80 mg Pure Black 115, and 1.0 mL of 5 % Nafion solution.
- Example 39 Biocathode Ink Formulation 4: Immobilization layer thickness evaluation AKER 10002.1
- the 17% Immobilized Enzyme Recipe was prepared from 1 g Nanowire grafted carbon, 200 mg Laccase in 0.5 M Phosphate buffer solution at pH 7.2, and 4 mL of 5 % tetrabutylammonium bromide modified Nafion.
- the 8.5% Immobilized Enzyme Recipe was prepared from 1 g Nanowire grafted carbon, 100 mg Laccase in 0.5M Phosphate buffer solution at pH 7.2, and 2 mL of 5 % tetrabutylammonium bromide modified Nafion.
- the 4.2% Immobilized Enzyme Recipe was prepared from 1 g Nanowire grafted carbon, 50 mg Laccase in 0.5M Phosphate buffer solution at pH 7.2, and 1 mL of 5 % tetrabutylammonium bromide modified Nafion.
- Laccase enzyme was dissolved in phosphate buffer solution (pH 7.2, 0.5 M) and then mixed with 1 g nanowire grafted carbon sample (for example: Example 29, 1- (3-sulfopropyl)pyridinium hydroxide doped polyaniline grafted on carbon black particles). This enzyme/carbon slurry was vortexed for 5 minutes. Then, tetrabutylammonium bromide modified Nafion solution (5 wt% in Ethanol) in 1 mL increments was added and vortexed for 1 minute after every 1 mL addition. This mixture was spray dried at room temperature (open to ambient air). This yielded immobilized enzyme supported on nanowire grafted carbon.
- phosphate buffer solution pH 7.2, 0.5 M
- 1 g nanowire grafted carbon sample for example: Example 29, 1- (3-sulfopropyl)pyridinium hydroxide doped polyaniline grafted on carbon black particles. This enzyme/carbon slurry was vortexed for 5
- a separate ink formulation was created for each immobilized enzyme recipe and follows.
- the 17 % enzyme encapsulated carbon ink formulation was prepared from 20 mg 17 % immobilized enzyme recipe, 460 mg Monarch 1400, and 1.6 mL of 5 % Nafion solution.
- the 8.5 % enzyme encapsulated carbon ink formulation was prepared from 40 mg 8.5 % immobilized enzyme recipe, 440 mg Monarch 1400, 1.6 mL of 5 % Nafion solution.
- the 4.2 % enzyme encapsulated carbon ink formulation was prepared from 80 mg 17 % immobilized enzyme recipe, 400 mg Monarch 1400, and 1.6 mL of 5 % Nafion solution.
- the ink formulations had the immobilized enzyme carbon and carbon filler mixed by vortexing before adding the Nafion solution. Upon addition of the Nafion solution, the slurry was mixed with the spatula and AKER 10002.1
- Figure 63 illustrates the trade off associated with decreasing the amount of carbon filler in order to hold enzymatic loading constant at 0.136mg/cm 2 .
- the enzyme used in the encapsulation procedure had an activity of 120U/mg.
- Example 40 Biocathode Ink Formulation 5: Comparison of performance for commercial GCL (ELAT) and in house manufactured GDL
- the immobilized enzyme carbon and carbon filler were mixed by vortexing before addition of the Nafion solution.
- the slurry was mixed with the spatula and then sonicated with the sonicating dismembrator prior to painting on the ELAT support material.
- the electrode was dried, it was pressed to 115 Nafion membrane and a corresponding platinum black anode at 125 0 C for 35 seconds.
- the inks were painted using the same batch of enzyme immobilized carbon and the resulting data is shown in Figure 64.
- the electrode inks were fabricated using enzyme with 120 Units/mg activity.
- the in house developed GDL demonstrated higher performance for equivalent conditions as compared to the ELAT GDL.
- Example 41 Ink Formulation 6: Chitosan immobilized Laccase painted onto ELAT
- the modified chitosan was incorporated during the spray drying step. Once the enzyme encapsulated carbon was dry, it was incorporated into the following ink formulation.
- the chitosan immobilized enzyme ink formulation was prepared from 80 mg chitosan immobilized enzyme encapsulated carbon, 400 mg Monarch 1400, and 1.6 mL of 5 % Nafion solution.
- the ink painting steps were the same as described in previous examples, however, the press step changed. Chitosan has a lower melt and decomposition temperature, therefore it is unstable at temperatures higher than 85 0 C. Thus, the chitosan electrode was pressed at 85 0 C for 35 seconds.
- Hydrophobically modified chitosan illustrated slightly lower performance as compared to the tetrabutylammonium bromide modified Nafion encapsulated Laccase. (See Figure 65).
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US12/513,718 US20110039164A1 (en) | 2006-11-06 | 2007-11-07 | Bioanode and biocathode stack assemblies |
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Also Published As
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EP2080243A2 (en) | 2009-07-22 |
CA2668685A1 (en) | 2008-05-15 |
WO2008058165A3 (en) | 2008-11-20 |
US20110039164A1 (en) | 2011-02-17 |
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