CA3141051C - Catalysed membrane - Google Patents
Catalysed membrane Download PDFInfo
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- CA3141051C CA3141051C CA3141051A CA3141051A CA3141051C CA 3141051 C CA3141051 C CA 3141051C CA 3141051 A CA3141051 A CA 3141051A CA 3141051 A CA3141051 A CA 3141051A CA 3141051 C CA3141051 C CA 3141051C
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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
- H01M8/10—Fuel cells with solid electrolytes
- H01M8/1004—Fuel cells with solid electrolytes characterised by membrane-electrode assemblies [MEA]
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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
- H01M4/8605—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
- H01M4/88—Processes of manufacture
- H01M4/8803—Supports for the deposition of the catalytic active composition
- H01M4/881—Electrolytic membranes
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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
- H01M4/88—Processes of manufacture
- H01M4/8803—Supports for the deposition of the catalytic active composition
- H01M4/8814—Temporary supports, e.g. decal
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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
- H01M4/88—Processes of manufacture
- H01M4/8825—Methods for deposition of the catalytic active composition
- H01M4/8828—Coating with slurry or ink
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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
- H01M4/9075—Catalytic material supported on carriers, e.g. powder carriers
- H01M4/9083—Catalytic material supported on carriers, e.g. powder carriers on carbon or graphite
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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
- Y02E60/30—Hydrogen technology
- Y02E60/50—Fuel cells
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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
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P70/00—Climate change mitigation technologies in the production process for final industrial or consumer products
- Y02P70/50—Manufacturing or production processes characterised by the final manufactured product
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- Chemical & Material Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- Electrochemistry (AREA)
- General Chemical & Material Sciences (AREA)
- Engineering & Computer Science (AREA)
- Manufacturing & Machinery (AREA)
- Life Sciences & Earth Sciences (AREA)
- Sustainable Development (AREA)
- Sustainable Energy (AREA)
- Materials Engineering (AREA)
- Inert Electrodes (AREA)
- Fuel Cell (AREA)
- Catalysts (AREA)
- Carbon And Carbon Compounds (AREA)
- Separation Using Semi-Permeable Membranes (AREA)
Abstract
Description
Background of the Invention A fuel cell is an electrochemical cell comprising two electrodes separated by an electrolyte. A fuel, e.g. hydrogen, an alcohol such as methanol or ethanol, or formic acid, is supplied to the anode and an oxidant, e.g. oxygen or air, is supplied to the cathode.
Electrochemical reactions occur at the electrodes, and the chemical energy of the fuel and the oxidant is converted into electrical energy and heat. Electrocatalysts are used to promote the electrochemical oxidation of the fuel at the anode and the electrochemical reduction of oxygen at the cathode.
Fuel cells are usually classified according to the nature of the electrolyte employed.
Often the electrolyte is a solid polymeric ion-conducting membrane, in which the ion-conducting membrane is electronically insulating but ionically conducting. In the proton exchange membrane fuel cell (PEMFC) the ion-conducting membrane is proton conducting, and protons, produced at the anode, are transported across the ion-conducting membrane to the cathode, where they combine with oxygen to form water.
A principal component of the PEMFC is the membrane electrode assembly, which is essentially composed of five layers. The central layer is the polymer ion-conducting membrane. On either side of the ion-conducting membrane there is an electrocatalyst layer, containing an electrocatalyst designed for the specific electrolytic reaction.
Finally, adjacent to each electrocatalyst layer there is a gas diffusion layer. The gas diffusion layer must allow the reactants to reach the electrocatalyst layer and must conduct the electric current that is generated by the electrochemical reactions. Therefore, the gas diffusion layer must be porous and electrically conducting.
Examples of ways in which membrane electrode assemblies can be constructed are as follows:
(i) The electrocatalyst layer may be applied to the gas diffusion layer to form a gas diffusion electrode. A gas diffusion electrode is placed on each side of an ion-conducting membrane and laminated together to form the five-layer membrane electrode assembly:
(iii) A membrane electrode assembly can be formed from an ion-conducting membrane coated on one side with an electrocatalyst layer, a gas diffusion layer adjacent to that electrocatalyst layer, and a gas diffusion electrode on the other side of the ion-conducting membrane.
Typically, tens or hundreds of membrane electrode assemblies are required to provide enough power for most applications, so multiple membrane electrode assemblies are assembled to make up a fuel cell stack. Flow field plates are used to separate the membrane electrode assemblies. The plates perform several functions: supplying the reactants to the membrane electrode assemblies; removing products; providing electrical connections; and providing physical support.
1/Olen preparing an electrocatalyst layer, there are certain desirable features for high performance. In particular, it is desirable to use electrocatalysts which have high activity for the particular electrochemical reaction being catalysed. For example, in the case of PEMFC
cathodes, it is desirable to use an electrocatalyst with high activity for the oxygen reduction reaction. Electrocatalyst layers containing such high activity electrocatalysts will demonstrate high performance when pure oxygen is supplied as the oxidant and electrochemical performance is under kinetic control. However, such electrocatalyst layers may not demonstrate high performance when air is supplied as the oxidant, i.e. under real-world conditions, due to, for example, high density and low permeability of the electrocatalyst layer.
It is important for membrane electrode assemblies to have good performance at high current densities and there is a continued need for membrane electrode assemblies with improved performance. In particular, there is a need for membrane electrode assemblies containing electrocatalyst layers with high kinetic activity which also perform well in real-world conditions. i.e. on air operation.
Summary of the Invention It is an object of the present invention to provide catalysed ion-conducting membranes which demonstrate good performance at high current densities under real-world condition operation of membrane electrode assemblies. Accordingly, the present invention provides a catalysed ion-conducting membrane comprising an ion-conducting membrane, an electrocatalyst layer having two opposing faces, and a layer A, wherein:
the layer A comprises an ion-conducting material IA and a carbon containing material CA;
the electrocatalyst layer comprises an ion-conducting material lb and an electrocatalyst.
The term "catalysed membrane" used herein refers to an arrangement, as defined in the invention, which comprises an ion-conducting membrane, a layer A and an electrocatalyst layer as defined in the invention, regardless of how the arrangement is prepared.
The inventors have surprisingly found that layer A can compensate for the low permeability associated with electrocatalyst layers which have inherently high kinetic activity for the desired electrochemical reaction. The combination of high permeability and kinetic activity results in high levels of electrochemical performance under real-world conditions.
The present invention also provides a membrane electrode assembly comprising the catalysed ion-conducting membrane of the invention, and a fuel cell comprising the catalysed ion-conducting membrane, or the membrane electrode assembly, of the invention.
The fuel cell is preferably a proton exchange membrane fuel cell.
The present invention also provides a method of preparing the catalysed ion-conducting membrane of the invention, the method comprising:
i) applying an electrocatalyst layer ink onto a layer A, or onto a layer of a layer A ink; or ii) applying a layer A ink onto an electrocatalyst layer, or onto a layer of an electrocatalyst layer ink;
wherein the electrocatalyst layer ink comprises an ion-conducting material lb and an electrocatalyst; and the layer A ink comprises an ion-conducting material IA and a carbon containing material CA.
The ion-conducting material IB, electrocatalyst, carbon containing material CA
and ion-conducting material IA referred to in this method aspect of the invention are the same as those referred to in the catalysed ion-conducing membrane aspect of the invention.
Figure 2 is a plot showing voltage versus current density for a membrane electrode assembly comprising a catalysed ion-conducting membrane of the invention, and a membrane electrode assembly comprising a comparative catalysed ion-conducting membrane having no layer A.
Figure 3 is a plot showing voltage versus current density for a membrane electrode assembly comprising a catalysed ion-conducting membrane of the invention, and a membrane electrode assembly comprising a comparative catalysed ion-conducting membrane having no layer A.
Figure 4 is a is a plot showing voltage versus current density for membrane electrode assemblies comprising catalysed ion-conducting membranes of the invention with different carbon containing materials CA in layer A, and a membrane electrode assembly comprising a comparative catalysed ion-conducting membrane having no layer A.
Figure 5 is a temperature sweep at 1.6 A/cm2 for the same membrane electrode assemblies for which data is illustrated in Fig. 4.
Figure 6 is a is a plot showing voltage versus current density for membrane electrode assemblies comprising catalysed ion-conducting membranes of the invention in which the cathode electrocatalyst layers have different permeabilities, and membrane electrode assemblies comprising a comparative catalysed ion-conducting membrane having no layer A.
Figure 7 is a plot showing voltage versus current density for membrane electrode assemblies comprising catalysed ion-conducting membranes of the invention prepared by applying the layer A to a gas diffusion layer prior to application of the electrocatalyst layer and combination with an ion-conducting membrane.
Figure 8 is a temperature sweep at 1.6 A/cm2 for the same membrane electrode assemblies for which data is illustrated in Fig. 7.
Figure 9 shows a cross section prepared by focused ion beam milling imaged in a scanning electron microscope (SEM) in both secondary electron (SE) and back-scattered-electron (BSE) modes, showing a portion of a catalysed ion-conducting membrane of the invention, showing layer A and the electrocatalyst layer.
Figure 11 shows a differential intrusion trace for pores smaller than 1 micron diameter as measured by mercury intrusion porosimetry for a layer A and an electrocatalyst layer containing a Pt electrocatalyst, showing modal pore diameter.
Figure 12 shows a cumulative intrusion trace for pores smaller than 1 micron diameter as measured by mercury intrusion porosimetry for a layer A and an electrocatalyst layer containing a Pt/Ni alloy electrocatalyst.
Figure 13 shows a differential intrusion trace for pores smaller than 1 micron diameter as measured by mercury intrusion porosimetry for a layer A and an electrocatalyst layer containing a Pt/Ni alloy electrocatalyst. Modal pore diameter is provided.
Detailed Description of the Invention Preferred and/or optional features of the invention will now be set out. Any aspect of the invention may be combined with any other aspect of the invention, unless the context demands otherwise. Any of the preferred or optional features of any aspect may be combined, singly or in combination, with any aspect of the invention, unless the context demands otherwise.
The layer A comprises an ion-conducting material IA which, suitably, is a proton conducting ionomer. A skilled person understands that an ionomer is a polymer composed of both electrically neutral repeating units and ionizable repeating units covalently bonded to the polymer backbone via side-chains. The ion-conducting material IA may include ionomers such as perfluorosulphonic acid materials (e.g. Nation (Chemours Company), Aciplex (Asahi Kasei), Aquivion (Solvay Specialty Polymer), Flemion (Asahi Glass Co.)), or ionomers based on partially fluorinated or non-fluorinated hydrocarbons that are sulphonated or phosphonated polymers, such as those available from FuMA-Tech GmbH as the fumapeme P. E or K series of products, JSR Corporation, Toyobo Corporation, and others.
Suitably, the ionomer is a perfluorosulphonic acid, in particular the Naflone range available from Chemours company, especially Nation 1100EW, and the Aquivion IP range available from Solvay, especially Solvay 830EW.
The layer A also comprises a carbon material CA, which is preferably in powder form. The carbon material CAtypically has a surface area of no more than 1300 m2/g, preferably no more than 500 rn2/g as measure by the Brunauer¨Emmett¨Teller (BET)
The carbon material CA may have a modal pore diameter, as determined by mercury intrusion porosimetry, of no more than 100 nm, preferably no more than 75 nm, more preferably no more than 60 run The carbon material may have a modal pore diameter, as determined by mercury intrusion porosimetry, of at least 5 nm, preferably at least 10 nm, more preferably at least 20 nm. The procedure used for mercury intrusion porosimetry is set out in the examples section. In particular, mercury pressure is increased from ¨3.0 to 60,000 psia during a measurement, and the porosity at <1 micron and >3 nm pore diameter is used for calculating porosity characteristics.
The carbon material CA may have a total pore area, as determined by mercury intrusion porosimetry, of no more than 500 m2/g. The carbon material may have a total pore area, as determined by mercury intrusion porosimetry, of at least 30 m2/g, preferably at least 100 m2/g, more preferably at least 150 m2/9. The procedure used for mercury intrusion porosimetry is set out in the examples section. In particular, mercury pressure is increased from ¨3.0 to 60,000 psia during a measurement, and the porosity at <1 micron and >3 nm pore diameter is used for calculating porosity characteristics.
The carbon material CA may be a carbon black or a graphitised carbon black.
Accordingly, the carbon material CA may be, for example, a commercially available carbon black (such as from Cabot Corp. (Vulcan XC72R) or Akzo Nobel (the Ketjen black series)) or a graphitised version of these carbon blacks or other commercially available carbon blacks such as acetylene blacks (e.g. those available from Chevron Phillips (Shawinigan Black) or Denka). The carbon material CA may also be one specifically designed for use in a fuel cell, such as those described in W02013/045894.
The weight ratio of ion-conducting material IA to carbon containing material CA in layer A is suitably in the range of and including 2:1 to 1:2, preferably 1:1 to 1:2.
The layer A may contain other materials such as structuring agents and reactive materials such as peroxide decomposition catalysts or oxygen evolution catalysts. Suitably, the layer A comprises no more than 10 wt% by total weight of the layer A other materials than the ion-conducting material IA and the carbon containing material CA, typically no more than 5 wt%, for example no more than 1 wt%. In one aspect, the layer A
consists of the ion-conducting material IA and the carbon containing material CA. Examples of oxygen evolution catalysts include those disclosed in WO 2011/021034 and W02012/080726. An oxygen evolution catalyst protects against carbon corrosion during high potential events that can occur on the anode during cell reversal, or on the cathode during start-stop cycles.
The layer A preferably has a permeability ki of greater than 15 nm2, more preferably greater than 20 nm2. The upper limit for permeability is not particularly limited. For example, the permeability is suitably no more than 450 nm2, typically no more than 250 nm2, for example no more than 100 nm2. Permeability in this context is calculated from mercury intrusion porosimetry measurements in accordance with the procedure set out in the examples section. In particular, mercury pressure is increased from -3.0 to 60,000 psia during a measurement, and the porosity at <1 micron and >3 nm pore diameter is used for calculating porosity characteristics.
The layer A suitably has a thickness of no more than 15 pm, typically no more than pm, preferably no more than 6 pm. The layer A suitably has a thickness of at least 1 pm, typically at least 2 pm, preferably at least 3 pm. Layer thickness can readily be determined by examining cross sections in SEM images.
Preferably, the layer A is hydrophobic. In other words, the layer A has a contact angle, as measure by water intrusion porosimetry, of at least 90 , typically at least 105 .
Suitably the layer A has a contact angle of no more than 120 , typically no more than 110 .
Water intrusion porosimetry measures the contact angle of water within the interior surface of the pores in the layer. Thus, the layer is hydrophobic because the interior surfaces of the pores in the layer are hydrophobic. The procedure used for water intrusion porosimetry is set out in the examples section. In particular, water pressure is increased from -10 to 10,000 psia during a measurement.
The electrocatalyst layer has two opposing faces i.e. faces separated by the thickness of the electrocatalyst layer. A skilled person will understand thickness to mean the measurement in the through-plane, z-direction. The opposing faces extend perpendicularly to the thickness i.e. in the x-y-plane. Accordingly, the requirement that the ion-conducting membrane and the layer A are adjacent to opposite faces of the electrocatalyst layer means that they are separated by the thickness of the electrocatalyst layer.
Preferably, the layer A
is in contact with one face of the electrocatalyst layer, and the ion-conducting membrane is in contact with the opposite face of the electrocatalyst layer. Alternatively, the layer A is in contact with one face of the electrocatalyst layer and the ion-conducting membrane is adjacent to the opposite face, with one or more, preferably no more than one, layer(s) in between the electrocatalyst layer and the ion-conducting membrane.
Suitably, the ionomer is a perfluorosulphonic acid, in particular the Nation range available from Chemours company, especially Nation -1100EW, and the Aquivion 0 range available from Solvay, especially Solvay 830EW.
The electrocatalyst layer also comprises an electrocatalyst. The electrocatalyst is suitably selected from:
(i) the platinum group metals (platinum, palladium, rhodium, ruthenium, iridium and osmium);
(ii) gold or silver;
(iii) a base metal;
or an alloy or mixture comprising one or more of these metals or their oxides.
A base metal is tin or a transition metal which is not a noble metal. A noble metal is a platinum group metal (platinum, palladium, rhodium, ruthenium, iridium or osmium) or gold.
Suitable base metals in the alloy electrocatalyst are copper, cobalt, nickel, zinc, iron, titanium, molybdenum, vanadium, manganese, niobium, tantalum, chromium and tin.
Typically, the electrocatalyst comprises a platinum group metal or an alloy of a platinum group metal. In particular, the electrocatalyst comprises platinum or an alloy of platinum with a base metal, preferably nickel or cobalt, most preferably nickel. The atomic ratio of platinum to alloying metal is typically in the range of and including 3:1 to 1:3.
The electrocatalyst may be unsupported, or supported on a support material.
The term "supported" will be readily understood by a skilled person. For example, it will be understood that the term "supported" includes the electrocatalyst being bound or fixed to the support material by physical or chemical bonds. For instance, the electrocatalyst may be bound or fixed to the support material by way of ionic or covalent bonds, or non-specific interactions such as van der Waals forces.
Typically, a carbon support material is used which is preferably in powder form. The carbon material, CB, may be a carbon black or a graphitised carbon black.
Accordingly, the carbon support material, GB, may be, for example, a commercially available carbon black
Alternatively, the support material may be a metal oxide or a mixed oxide, in particular a conductive mixed oxide such as niobia-doped titania, phosphorus-doped tin oxide and mixed platinum group metal oxides or mixed metal oxides (as disclosed in W02012/080726), a carbide (e.g. tungsten carbide, molybdenum carbide or titanium carbide, suitably tungsten carbide or titanium carbide), a nitride, in particular a conductive nitride (e.g. titanium nitride or titanium aluminium nitride).
When the electrocatalyst material is supported, the loading of electrocatalyst on the support material may suitably be at least 10 wt%, typically at least 20 wt% by total weight of the electrocatalyst plus the support. The loading of the electrocatalyst may suitably be no more than 90 wt%, typically no more than 60 wt%, for example no more than 40 wt% by total weight of the electrocatalyst plus the support.
The electrocatalyst layer preferably has a permeability k2 as determined by mercury intrusion porosimetry of no more than 25 nm2, more preferably no more than 20 nm2. The lower limit for permeability is not particularly limited. For example, the permeability is suitably at least 5 nre. Permeability in this context is calculated from mercury intrusion porosimetry measurements in accordance with the procedure set out in the examples section.
In particular, mercury pressure is increased from -3.0 to 60,000 psia during a measurement, and the porosity at <1 micron and >3 nm pore diameter is used for calculating porosity characteristics.
Suitably, the electrocatalyst layer is hydrophobic. In other words, the electrocatalyst layer has a contact angle as measured by water intrusion porosimetry of at least 90 , typically at least 105'. Suitably the electrocatalyst layer has a contact angle of no more than 120 , typically no more than 110'. Water intrusion porosimetry measures the contact angle of water within the interior surface of the pores in the electrocatalyst layer. Thus, the layer is hydrophobic because the interior surfaces of the pores in the layer are hydrophobic. The procedure used for water intrusion porosimetry is set out in the examples section. In particular, water pressure is increased from -10 to 10,000 psia during a measurement The electrocatalyst layer may be an anode or a cathode, preferably a proton exchange membrane fuel cell anode or cathode. Preferably the electrocatalyst layer is a
The additional catalyst layer present on the opposite face of the ion-conducting membrane may be an electrocatalyst layer as defined in the invention, along with a layer A
as defined in the invention, in the arrangement described herein. Accordingly, the present invention also provides a catalysed ion-conducting membrane comprising an ion-conducting membrane having two opposing faces, and, at one face of the ion-conducting membrane, a cathode electrocatalyst layer having two opposing faces, and a layer A, wherein:
the layer A and the ion-conducting membrane are adjacent to opposite faces of the cathode electrocatalyst layer, the layer A comprises an ion-conducting material IA and a carbon containing material CA;
the cathode electrocatalyst layer comprises an ion-conducting material IB and an electrocatalyst; and at the opposite face of the ion-conducting membrane, an anode electrocatalyst layer having two opposing faces, and a layer A, wherein:
the layer A and the ion-conducting membrane are adjacent to opposite faces of the anode electrocatalyst layer;
the layer A comprises an ion-conducting material IA and a carbon containing material CA;
the anode electrocatalyst layer comprises an ion-conducting material IB and an electrocatalyst.
The thickness of the electrocatalyst layer is not particularly limited and will depend on the intended use. For example, in a fuel cell cathode, the thickness of the electrocatalyst layer may be at least 0.1 pm, suitably at least 2 pm, typically at least 5 pm.
In a fuel cell cathode, the thickness may be no more than 40 pm, suitably no more than 20 pm, typically no more than 15 pm. Layer thickness can readily be determined by examining cross sections in SEM images.
The electrocatalyst loading will also depend on the intended use. In this context, electrocatalyst loading means the amount of active metal for the desired reaction in the
The electrocatalyst layer may comprise additional components. Such components include, but are not limited to: an oxygen evolution catalyst; a hydrogen peroxide decomposition catalyst; a hydrophobic additive (e.g. a polymer such as polytetrafluoroethylene (PTFE) or an inorganic solid with or without surface treatment) or a hydrophilic additive (e.g. a polymer of an inorganic solid, such as an oxide) to control reactant and water transport characteristics. The choice of additional components is within the capability of a skilled person to determine.
The ion-conducting membrane in the catalysed ion-conducting membrane of the invention has two opposing faces which are separated by the thickness of the ion-conducting membrane. A skilled person will understand thickness to mean the measurement in the through-plane, z-direction. The opposing faces extend perpendicularly to the thickness i.e. in the x-y-plane.
The ion-conducting membrane comprises an ion-conducting material which, suitably, is a proton conducting ionomer. Accordingly, the ion-conducting material may include ionomers such as perfluorosulphonic acid (e.g. Nafion (Chemours Company), Aciplex (Asahi Kasei), Aquivion (Solvay Specialty Polymer), Flemion (Asahi Glass Co.)), or ionomers based on partially fluorinated or non-fluorinated hydrocarbon that are sulphonated or phosphonated polymers, such as those available from FuMA-Tech GmbH as the funnapenne P, E or K series of products, JSR Corporation, Toyobo Corporation, and others.
Suitably, the ionomer is a perfluorosulphonic acid, in particular the Aquivion range available from Solvay, especially Aquivion 790EW.
The thickness of the ion-conducting membrane is not particularly limited and will depend on the intended application of the ion-conducting membrane_ For example, typical fuel cell ion-conducting membranes have a thickness of at least 5 pm, suitably at least 8 pm, preferably at least 10 pm. Typical fuel cell ion-conducting membranes have a thickness of no more than 50 pm, suitably no more than 30 pm, preferably no more than 20 pm.
Accordingly, typical fuel cell ion-conducting membranes have a thickness in the range of and including 5
The ion-conducting membrane may comprise additional components such as peroxide decomposition catalysts and/or radical decomposition catalysts, and/or recombination catalysts. Recombination catalysts catalyse the recombination of unreacted H2 and 02 which can diffuse into the ion-conducting membrane from the anode and cathode of a fuel cell respectively, to produce water. The ion-conducting membrane may also comprise a reinforcement material, such as a planar porous material (for example expanded polytetrafiuoroethylene (ePTFE) as described in USRE37307), embedded within the thickness of the ion-conducting membrane, to provide for improved mechanical strength of the ion-conducting membrane, such as increased tear resistance and reduced dimensional change on hydration and dehydration, and thus further increase the durability of a membrane electrode assembly and lifetime of a fuel cell incorporating the catalysed ion-conducting membrane of the invention. Other approaches for forming reinforced ion-conducting membranes include those disclosed in US 7,807,063 and US 7,867,669 in which the reinforcement is a rigid polymer film, such as polyimide, into which a number of pores are formed and then subsequently filled with the PFSA ionomer. Graphene particles dispersed in an ion-conducting polymer layer may also be used as a reinforcement material.
Any reinforcement present may extend across the entire thickness of the ion-conducting membrane or may extend across only a part of the thickness of the ion-conducting membrane. It will be understood that the thickness of the ion-conducting membrane extends perpendicular to the face of the ion-conducting membrane, e.g. it is in the through plane z-direction. It may further be advantageous to reinforce the perimeter of the first and second surface of the ion-conducting membrane to a greater extent than the central face of the first and second surface of the ion-conducting membrane.
Conversely, it may be desirable to reinforce the centre of the first or second surface of the ion-conducting membrane to a greater extent than perimeter of the first or second surface of the ion-conducting membrane.
In the methods of the invention, the catalysed ion-conducting membrane of the invention is prepared using inks ¨ a layer A ink and an electrocatalyst layer ink. As is readily evident to a skilled person, a layer A ink becomes a layer A when it has been dried, and an electrocatalyst layer ink becomes an electrocatalyst layer when it has been dried. A layer of layer A ink, or a layer of electrocatalyst ink, is a layer of the ink which has not been dried A skilled person is capable of preparing such inks, and as such the method of preparing the inks is not particularly limited. For example, to prepare the layer A ink, ion-
The layer A ink is dried to provide a layer A, for example the layer A ink is heated to a temperature in the range of and including 100 to 300*C, suitably 200 to 250'C
for a sufficient period of time. The drying method is not particularly limited, and a skilled person will be able to identify a suitable method. The electrocatalyst layer ink is dried to provide an electrocatalyst layer, for example the electrocatalyst ink is heated to temperature in the range of and including 100 to 250*C, suitably 150 to 200 C. Drying also has the function of annealing the layers. In the method of the invention, the first ink to be deposited need not be dried before the second ink is applied. In other words, the second ink to be applied may be applied to a pre-formed and dried layer A or electrocatalyst layer, or it may be applied to a still wet application of the layer A ink or the electrocatalyst layer ink.
When the electrocatalyst layer ink is applied to a substrate first, the substrate is preferably the ion-conducting membrane. The layer A ink is then applied to a layer of the electrocatalyst layer ink, or an electrocatalyst layer (after drying of the electrocatalyst layer ink) before being dried to form a layer A. Accordingly, the present invention provides a method for preparing the catalysed ion-conducting membrane of the invention, the method comprising the steps of:
i) applying an electrocatalyst layer ink onto an ion-conducting membrane and then drying the ink to form an electrocatalyst layer;
ii) applying a layer A ink onto an electrocatalyst layer then drying the ink to form a layer A;
wherein the electrocatalyst layer ink comprises an ion-conducting material IB
and an electrocatalyst; and
Alternatively, in step ii), the layer A ink may be applied to a still wet application of the electrocatalyst layer ink. So, alternatively, the ink applied in step i) is not dried before step ii) and the layer A ink is applied in step ii) to a layer of the electrocatalyst layer ink.
Preferably, the layer A ink is applied to a substrate first, then preferably dried to form a layer A (although drying at this stage is not required) before applying an electrocatalyst ink to the layer (either a layer A or a layer of layer A ink) and drying to form an electrocatalyst layer. The combined layers may suitably be combined with an ion-conducting membrane such that the electrocatalyst layer is adjacent to the ion-conducting membrane. Accordingly, the present invention provides a method of preparing a catalysed ion-conducting membrane according to the invention, the method comprising the steps of:
i) applying a layer A ink comprising ion-conducting material IA and carbon containing material CA onto a substrate then drying the ink to form a layer A;
then ii) applying an electrocatalyst layer ink comprising ion-conducting material IB and an electrocatalyst onto the layer A formed in step i) then drying the ink to form an electrocatalyst layer;
iii) combining the layers with an ion-conducting membrane such that the electrocatalyst layer is adjacent to the ion-conducting membrane. The substrate to which the layer A ink is applied may suitably be a decal transfer substrate.
Alternatively, in step ii), the electrocatalyst layer ink may be applied to a still wet application of the layer A ink. So, alternatively, the ink applied in step i) is not dried before step ii) and the electrocatalyst layer ink is applied in step ii) to a layer of the layer A
ink.
The decal transfer used in the invention may be formed from any suitable material from which the electrocatalyst layer can be removed without damage thereto and it is within the capability of a skilled person to be able to select a decal transfer substrate. Examples of suitable materials include a fluoropolyrner, such as polytetrafluoroethylene (PTFE), ethylene tetrafluoroethylene (ETFE), perfluoroalkoxy polymer (PEA), fluorinated ethylene propylene (FEP ¨ a copolymer of hexafluoropropylene and tetrafluoroethylene) and polyolefins, such as biaxially orientated polypropylene (BOPP).
The membrane electrode assembly of the invention comprises a catalysed ion-conducting membrane according to the invention which includes the electrocatalyst layer as
The membrane electrode assembly comprises a gas diffusion layer at each face.
The present invention also provides a method of preparing a membrane electrode assembly of the invention comprising a catalysed ion-conducting membrane of the invention, the method comprising the steps of:
i) applying an electrocatalyst layer ink onto an ion-conducting membrane and then drying the ink to form an electrocatalyst layer then ii) applying a layer A ink onto the electrocatalyst layer then drying the ink to form a layer A;
wherein the electrocatalyst layer ink comprises an ion-conducting material IB
and an electrocatalyst; and the layer A ink comprises an ion-conducting material IA and a carbon containing material CA.
A gas diffusion layer is subsequently applied to the layer A.
Alternatively, in step ii), the layer A ink may be applied to a still wet application of the electrocatalyst layer ink. So, alternatively, the ink applied in step i) is not dried before step ii) and the layer A ink is applied in step ii) to a layer of the electrocatalyst layer ink.
Additionally, the present invention provides a method for preparing a membrane electrode assembly of the invention comprising a catalysed ion-conducting membrane according to the invention, the method comprising the steps of:
I) applying a layer A ink comprising ion-conducting material IA and carbon containing material CA onto a substrate then drying the ink to form a layer A;
then ii) applying an electrocatalyst layer ink comprising ion-conducting material IB and an electrocatalyst onto the layer A formed in step i) then drying the ink to form an electrocatalyst layer; then iii) combining the layers with an ion-conducting membrane such that the electrocatalyst layer is adjacent to the ion-conducting membrane. The substrate to which the layer A ink is applied may suitably be a decal transfer substrate or a gas diffusion layer.
When the substrate to which the layer A ink is applied is a gas diffusion layer, the layer A ink is applied to the microporous layer, if present on the gas diffusion layer. After application of the electrocatalyst layer ink to the layer A to form a gas diffusion electrode, the combined layers are then combined with the ion-conducting membrane, such that the electrocatalyst layer is adjacent to the ion-conducting membrane.
When the substrate to which the layer A ink is applied is a decal transfer substrate, the decal transfer substrate is removed from the layer A after step iii). In that case, a gas diffusion layer may subsequently be added.
Preferably, the combined layers are combined directly with the ion-conducting membrane such that the electrocatalyst layer is in contact with the ion-conducting membrane.
The gas diffusion layer comprises a gas diffusion substrate and, optionally a microporous layer. Preferably, the gas diffusion layer comprises a microporous layer. Typical gas diffusion substrates include non-woven papers or webs comprising a network of carbon fibres and a thermoset resin binder (e.g. the TGP-H series of carbon fibre paper available from Toray Industries Inc., Japan or the H2315 series available from Freudenberg FCCT
KG, Germany, or the Sigracete series available from SGL Technologies GmbH, Germany or AvCare series from AvCarb Material Solutions LLC), or woven carbon cloths. The carbon paper, web or doth may be provided with a pre-treatment prior to fabrication of the electrode and being incorporated into a membrane electrode assembly either to make it more wettable (hydrophilic) or more wet-proofed (hydrophobic). The nature of any treatments will depend on the type of fuel cell and the operating conditions that will be used. The substrate can be made more wettable by incorporation of materials such as amorphous carbon blacks via impregnation from liquid suspensions, or can be made more hydrophobic by impregnating the pore structure of the substrate with a colloidal suspension of a polymer such as PTFE or polyfluoroethylenepropylene (FEP), followed by drying and heating above the melting point of the polymer. A microporous layer may also be applied to the gas diffusion substrate on the face that will contact the layer A. The microporous layer typically comprises a mixture of a carbon black and a polymer such as polytetrafluoroethylene (PTFE). The addition of a
Fig. 1 shows a schematic of a preferred method according to the invention. A
layer A
ink is applied to a PTFE decal transfer substrate and dried, before application of a cathode electrocatalyst layer ink and drying. The combined layers are then transferred to an ion-conducting membrane which either already comprises an anode, or to which an anode will be added subsequently.
Examples Preparation of layer A inks Layer A ink was fabricated by mixing 2 g of carbon powder with 7.07 g aqueous Solvay 830EW ionomer solution (Aquivion, 25 wt%) using a spatula to ensure the carbon powder was fully wetted. 2.85 g of neat propan-1-ol and 4.82 g of water were added to the mixture to achieve a 22 wt% propan-1-ollwater ratio in the solvent mix and stirred well. The ionomer content in the carbon ink was 90 wt% with respect to weight of carbon.
The mixture was processed in a SpeedmixerTM DAC 150 FVZ-K with 10, 5 mm diameter YTZ32) beads until optimum particle break-up was achieved. The ink processing was stopped and stirred after 5 minutes to avoid overheating the ink during processing.
Two different layer A inks were prepared, each containing a different carbon.
Layer A
1 (LA1) ink contained a carbon specifically designed for use in fuel cells, as described in W02013/045894. Layer A 2 (LA2) ink contained Ketjen EC-300J.
Preparation of electrocatalyst layer inks Carbon supported Pt electrocatalysts Electrocatalyst layer ink ELI was fabricated by mixing 2.5 g of 30 wt% Pt supported on carbon black (which was prepared using a method analogous to the general method of preparation of carbon supported Pt catalysts described in WO 2013/045894) with 13.47 g aqueous Nafion 1100EW solution (DuPont, 10-12 wt%) using a spatula to ensure the electrocatalyst powder was fully wetted prior to adding propan-1-ol solvent 3.35 g of neat propan-1-ol was added to the mixture to achieve 22 wt% propan-1-ol/water ratio in the solvent mix and stirred well. The ionomer content in the cathode ink was 90 wt% with respect to the weight of carbon. The mixture was processed in a SpeedmixerTM
FVZ-K with 10, 5 mm diameter YTZO beads until optimum particle break-up was achieved.
The ink processing was stopped and stirred after 5 minutes to avoid overheating the ink
Carbon supported PtAVi catalysts Electrocatalyst layer inks EL2, EL3, EL4 and EL5 were fabricated by mixing 2 g of a carbon black supported nanoparticle Pt/Ni alloy material (electrocatalyst powder) with an amount of aqueous Nafion 1100EW solution (DuPont, 10-12 wt%) to provide 80 to 90%
mass of iononner with respect to the mass of carbon in the electrocatalyst powder. The amount of metal in the electrocatalyst material was assayed using inductively coupled plasma mass spectrometry; the mass of carbon being calculated from the difference in the total mass and the mass of metal. A spatula was used to ensure the electrocatalyst powder was fully wetted prior to propan-1-ol solvent addition. Neat propan-1-ol was added to the mixture to achieve 22 wt% propan-1-ol/water ratio in the solvent mix and stirred well. The mixture was processed in a SpeedmixerTM DAC 150 FVZ-K with 10, 5 mm diameter YTZO
beads until optimum particle break-up was achieved. The ink processing was stopped and stirred after 5 minutes to avoid overheating the ink during processing. The processed ink was then diluted with 22 wt% propan-1-ol/water to a suitable ink solids content to allow the coating process to achieve the target Pt loading in the electrocatalyst layer.
The electrocatalyst in the EL2 ink was 30% Pti.aNi on carbon, the carbon being specifically designed for use in fuel cells, as described in VV02013/045894.
The electrocatalyst in the EL3 ink was 44% Pti aNi on carbon, prepared by the general method disclosed in WO 2017/129982. The electrocatalyst in the EL4 ink was 40%
Pt3.5Ni on carbon, prepared by the general method disclosed in WO 2017/129982. The electrocatalyst in the EL5 ink was 30% Pt2,11sli on carbon, wherein the carbon was Ketjen EC-300J.
Preparation of catalysed ion-conducting membranes Comparative examples (no layer A) Catalysed ion-conducting membranes of 50cm2 active area were prepared by depositing anode and cathode layers onto a PTFE sheet and transferring the appropriate layers to either side of a PFSA reinforced membrane (17 pm thickness) by lamination at a temperature of between 150 C and 200 C. Electrocatalyst layer inks of the invention were used to form the cathode electrocatalyst layer; the anode electrocatalyst layer in each catalysed ion-conducting membrane comprised an anode electrocatalyst (HiSPECOD
with a nominal Pt loading of 60 wt% Pt on the carbon support) at a loading of 0.1 mgPt/cm2.
Then, an electrocatalyst layer ink was printed on top of the dried layer A, dried and annealed (150-200 C). The combined layers were then transferred to one side of a PFSA
reinforced membrane (20 pm thickness), and an anode layer was transferred from a PTFE
sheet onto the other side, by lamination at a temperature of between 150 C to 200 C.
The anode layer in each catalysed ion-conducting membrane comprised an anode electrocatalyst (HiSPECO
9100 with a nominal Pt loading of 60 wt% Pt on the carbon support) at a loading of 0.1 mgPt/cm2.
Preparation 2 Catalysed ion-conducting membranes of 50cm2 active area were prepared by first depositing a layer A ink onto the microporous layer of a gas diffusion layer, drying and annealing (200-250 C). The gas diffusion layer used was a carbon fibre paper with a hydrophobic microporous layer containing carbon and PTFE. Then, an electrocatalyst layer ink was printed on top of the dried layer A, dried and annealed (150-200"C).
The combined layers were then transferred to a side of a PFSA reinforced membrane (17 pm thickness).
and an anode layer was transferred from a PTFE sheet onto the other side, by lamination at a temperature of between 150 C to 200 C. The anode layer in each catalysed ion-conducting membrane comprised an anode electrocatalyst (HiSPECO 9100 with a nominal Pt loading of 60 wt% Pt on the carbon support) at a loading of 0.1 nngPt/cnn2.
Preparation of membrane electrode assemblies A gas diffusion layer was applied to the faces of each catalysed ion-conducting membrane as required to form the complete membrane electrode assembly. The gas diffusion layer used was a carbon fibre paper with a hydrophobic microporous layer containing carbon and PTFE applied to the face in contact with the catalysed ion-conducting membrane.
Membrane electrode assembly performance testing The polarisation (current vs voltage) performance of the 50 cm2 membrane electrode assemblies was measured in H2/air at 80 C under fully humidified and pressurised (100%
RH, 100kPag) conditions and under drier (30% RH) conditions using H2 and air flows both at a stoichionnetry of 2Ø To check for any differences in the kinetic behaviour of the cathode
Modal pore size, total pore volume and permeability - mercury intrusion porosimetry measurements The electrocatalyst layers or layers A to be measured were supported either on ion-conducting membrane or on thin PTFE sheets. The layers to be measured were cut into strips which were stacked and rolled prior to loading into a specialised sample holder known as a penetrometer. The penetrometer containing the strips was mounted into a Micromeritics Autopore IV 9520 mercury porosimeter and the mercury pressure increased from -3.0 to 60,000 psia in small steps, with accompanying measurements of the volume of mercury intruded into the sample, derived from capacitance changes measured along the stem of the penetrometer. The pore size distribution was then calculated from the Washburn equation, assuming a contact angle for Hg of 130 , which relates the applied pressure to the diameter of the pores into which mercury is intruded, thereby giving the amount of porosity in pores from -60 microns to 3 nm in diameter. The intrusion curves were corrected for ion-conducting membrane or PTFE compression by measuring samples of the bare ion-conducting membrane, or bare PTFE, in the penetrometer over the same pressure range (-3.0 to 60,000 psia). The resulting apparent volume of intrusion, due to ion-conducting membrane or PTFE compression, was subtracted from the data for the catalysed ion-conducting membrane or PTFE-supported layers to ensure that no apparent pore volume due to ion-conducting membrane or PTFE compression was assigned to the electrocatalyst layers or layers A.
The porosity at <1 micron and >3 nm pore diameter is selected as the appropriate pore size range for calculating porosity characteristics in the layers of this invention. This avoids misleading information from large, inhomogeneous features such as cracks or voids.
The pore volume fraction and permeability are calculated from the mercury intrusion porosity data at <1 micron and >3 nm pore diameter as follows:
Pore volume fraction:
(I) = Total pore volume Total volume of catalyst layer
Alternatively, it can readily be determined from examination of cross sections in SEM
images.
Permeability:
k= d2 Where k = permeability = pore volume fraction d = pore diameter (in nnn) at the median intrusion volume, for pores at <1 micron and >3 nm pore diameter (i.e. the pore diameter at which half the volume of the porosity, <1 micron and >3 nnn pore diameter, is filled with mercury).
Figs. 10 and 11 show data extracted from mercury intrusion porosimetry measurements carried out on the electrocatalyst layer and layer A in Example 2, which are used to calculate permeability by the method discussed above.
Figs. 12 and 13 show data extracted from mercury intrusion porosimetry measurements carried out on the electrocatalyst layer and layer A in Example 1, which are used to calculate permeability by the method discussed above.
SEM imaging of cross sections Fig. 9 shows scanning electron microscope (SEM) images, secondary electron (SE) and back-scattered-electron (BSE), of part of a cross section of a catalysed ion-conducting membrane of the invention, in which the electrocatalyst layer and the layer A
are clearly identifiable. The electrocatalyst layer appears brighter in the BSE mode due to the presence of Pt, which has a high atomic number. These types of cross-sections were created using a Zeiss Auriga focused ion beam (FIB) instrument operated at 30 kV. A Pt strap was deposited on the surface of the specimen to protect the top surface during the cross-sectioning process. SEM imaging was performed using a Zeiss Ultra 55 SEM equipped with in-lens secondary electron and backscattered detectors, and a Bruker XFlashe 61100 EDX
detector.
High resolution SEM images were acquired using an accelerating voltage of 1.4 kV.
This contact angle shows how hydrophobic the surface of the pore wall is, with a value of 900 indicating a surface that is only just hydrophobic and a value of 110 indicating a very hydrophobic surface. Water intrusion porosimetry can be carried out using commercial instruments such as the Aquapore 30K-A-1 made by Porous Materials Inc. or using instruments of the type described by Fadeev and Eroshenko. Measurements require the sample to be completely immersed in water and pressure applied to the water such that it is forced into the pores of the material in the same manner as for mercury intrusion porosimetry. By measuring the applied pressure and the volume of water intruded into the sample a pressure-volume curve is obtained.
Samples were presented as electrocatalyst layers or as layer A layers supported on ion-conducting membrane or on PTFE sheet. Because the viscosity of water is much lower than that of mercury, much lower pressures are needed for intrusion and no correction for ion-conducting membrane of PTFE compression is needed. The water pressure range used was from 10 to 10,000 psia. The intrusion curves were corrected for ion-conducting membrane or PTFE
compression by measuring samples of the bare ion-conducting membrane, or bare PTFE, in the sample holder over the same pressure range (-10 to 10,000 psia). The resulting apparent volume of intrusion, due to ion-conducting membrane or PTFE
compression, was subtracted from the data for the catalysed ion-conducting membrane or PTFE-supported layers to ensure that no apparent pore volume due to ion-conducting membrane or PTFE
compression was assigned to the electrocatalyst layers or layers A.
A typical contact angle for water within the hydrophobic pores of the material can then be calculated from a comparison of the pressures at which the modal intrusions occur for mercury (Pm) using mercury intrusion porosimetry and for water (Pw) using water intrusion porosimetry, in the same type of porous layer, by plotting the differential of the pressure-volume curves (dVidlogP) against the intrusion pressure for each fluid and reading the modal pressure value for each intruded liquid (water and mercury). The modal pore size occurs at the peak of this curve. The contact angle for water is then calculated from the Washburn equations using the two values for the modal pressure from each intrusion experiment (water and mercury), re-arranged such that:
cosOw = ym.cosOrn.Payw.Pm Date Regue/Date Received 2023-01-10
Comparative Examples Table 1 No. Electrocatalyst layer ink Catalyst loading mgPticm2 1 EL2 0.1 2 ELI 0.1 3 EL3 0.2 4 EL4 0.2 ELI 0.2 6 EL5 0.1 Examples Table 2 No. Electrocatalyst layer Layer A Preparation Pt loading in Electrocatalyst ink ink method Layer mgPticm2 0.1 0.1 0.1 0.1 0.2 0.2 0.1 0.1 Results and discussion Table 3 gives the voltage at 1.8 A/cm2 (high current density) from the polarisation curves recorded under fully humidified conditions (100% relative humidity, Fig. 2), and under drier conditions (30% relative humidity) for Example 1 and Comparative Example 1, which both comprise a Pt/Ni electrocatalyst layer.
Comp. Example 1 453 422 Example 1 508 564 Gain, mV +55 +43 It can be seen that the inclusion of the layer A in Example 1 leads to a marked improvement in performance under both wet and dry conditions.
Table 4 provides some properties of the layers in Example 1 Table 4 Permeability Contact angle Layer thickness a nm2 Fun LA1 layer 63 106 5.3 EL2 layer 19 109 4.4 Table 5 gives the voltage at 1.8 A/cm2 (high current density) from the polarisation curve under fully humidified conditions (100% relative humidity, Fig. 3), and under drier conditions (30% relative humidity) for Example 2 and Comparative Example 2, which both comprise a Pt electrocatalyst layer.
Table 5 1.8 A/cm2 100% RH, 1.8 A/cm2 30% RH, mV mV
Comp. Example 2 366 365 Example 2 486 452 Gain, mV +120 +87 It can be seen that the inclusion of the layer A in Ex. 2 leads to a marked improvement in performance under both wet and dry conditions.
Table 6 Permeability Contact angle Layer thickness nm2 LA1 layer 63 106 5.3 ELI layer 16 108 5.0 Fig. 4 shows polarisation curves for Comparative Example 1, Example 3 and Example 4. The layer A in Example 3 is different from the layer A in Example 4. All three of these examples have Pt/Ni alloy electrocatalysts in the electrocatalyst layer.
Example 3 and 4 both show an improvement in performance at high current densities.
Fig. 5 shows a temperature sweep at 1.6 A/cm2for Comparative Example 1, Example 3 and Example 4. This illustrates the good performance of Example 3 and Example 4 over a range of humidities (indicated in the Figure). Some characteristics of the layers in these examples are provided in Table 7.
Table 7 Permeability Contact angle Layer thickness nm2 LA1 layer 63 106 5.3 LA2 layer 21 101 4.9 EL2 layer 19 109 4.4 Fig. 6 shows polarisation curves for Comparative Examples 3, 4 and 5, as well as Examples 5 and 6. Comparative Examples 3 and 4, as well as Example 5 and 6 contain the same electrocatalyst. Comparative Example 5 contains a high performing Pt electrocatalyst.
As can be seen in Fig. 6, it performs well under air at high current density.
Comparative Examples 3 and 4 perform better under oxygen, showing that these electrocatalysts are kinetically more active than Comparative Example 5. However, they do not perform as well as Comparative Example 5 under air at high current density. For most fuel cell applications, high performance on air is the most important objective to be achieved, whilst using low quantities of Pt to achieve this performance.
The performance at high current density under air of Example 5 is better than that of Comparative Example 3, and close to Comparative Example 5. The electrocatalyst layer in Example 5 has a permeability of 17 nm2. Accordingly, the layer A has improved the performance under air at high current densities of an electrocatalyst layer which has high kinetic performance.
Example 6 corresponds to Comparative Example 4 with the addition of a layer A.
The performance at high current density under air of Example 6 is similar to that of Comparative Example 4. The permeability of the electrocatalyst layer in Example 6 is 21 nm2. Table 8 collates the permeabilities of the layers in these examples.
Table 8 Permeability nm2 LA1 layer 63 EL3 layer 17 EL4 layer 21 Fig. 7 shows polarisation curves for Comparative Example 6 and Examples 7 and 8.
All of these examples contain the same electrocatalyst layer. Examples 7 and 8 both contain a layer A of the same identity. Example 7 was prepared by first applying layer A to the microporous layer of a gas diffusion layer before addition of the electrocatalyst layer to the layer A and subsequent transfer to the ion-conducting membrane. Example 8 was prepared by first applying layer A to a PTFE backing layer before addition of the electrocatalyst layer to the layer A and subsequent transfer to the ion-conducting membrane (i.e.
the same way as the other examples). Both preparation methods result in an improvement in performance.
However, there is an improvement when the electrocatalyst layer and layer A
are prepared by first applying the layer A and the electrocatalyst layer to a backing layer prior to transfer to the ion-conducting membrane.
Fig. 8 shows a temperature sweep at 1.6 A/cm2for Comparative Example 6, Example 7 and Example 8. This illustrates the good, improved, performance of Example 7 and Example 8 over a range of humidities (indicated in the Figure). The permeabilities of the layers in these examples are provided in Table 9.
1. A catalysed ion-conducting membrane comprising an ion-conducting membrane, an electrocatalyst layer having two opposing faces, and a layer A, wherein:
the layer A and the ion-conducting membrane are adjacent to opposite faces of the electrocatalyst layer;
the layer A comprises an ion-conducting material IA and a carbon containing material CA;
the electrocatalyst layer comprises an ion-conducting material Is and an electrocatalyst.
2. A catalysed ion-conducting membrane according to clause 1, wherein the layer A is hydrophobic.
3. A catalysed ion-conducting membrane according to clause 1 or clause 2, wherein the layer A has a permeability, 1(1, of at least 15 nm2, and the electrocatalyst layer has a permeability, k2, of no more than 25 nm2.
4. A catalysed ion-conducting membrane according to any preceding clause, wherein the weight ratio of ion-conducting material IA to carbon containing material CA in layer A is in the range of and including 2:1 to 1:2.
5. A catalysed ion-conducting membrane according to any preceding clause, wherein the electrocatalyst is supported.
6. A catalysed ion-conducting membrane according to clause 5, wherein the electrocatalyst is supported on a carbon containing material CB.
7. A catalysed ion-conducting membrane according to any preceding clause, wherein the electrocatalyst layer is a cathode electrocatalyst layer.
9. A fuel cell comprising the catalysed ion-conducting membrane according to any of clauses 1 to 7, or the membrane electrode assembly according to clause 8.
10. A method of preparing the catalysed ion-conducting membrane according to any of clauses 1 to 7 comprising:
I) applying an electrocatalyst layer ink onto a layer A, or onto a layer of a layer A ink; or ii) applying a layer A ink onto an electrocatalyst layer, or onto a layer of an electrocatalyst layer ink;
wherein the electrocatalyst layer ink comprises an ion-conducting material IB
and an electrocatalyst; and the layer A ink comprises an ion-conducting material IA and a carbon containing material CA.
11. A method according to clause 10, the method comprising the steps of:
I) applying an electrocatalyst layer ink onto an ion-conducting membrane and then drying the ink to form an electrocatalyst layer, then ii) applying a layer A ink onto the electrocatalyst layer then drying the ink to form a layer A.
12. A method according to clause 10, the method comprising the steps of i) applying a layer A ink onto a substrate then drying the ink to form a layer A;
then ii) applying an electrocatalyst layer ink onto the layer A formed in step i) then drying the ink to form an electrocatalyst layer;
iii) combining the layers with an ion-conducting membrane such that the electrocatalyst layer is adjacent to the ion-conducting membrane.
13. A method according to clause 12, wherein the substrate is a decal transfer substrate and step iii) is carried out by transferring the combined layers onto an ion-conducting membrane by decal transfer from the transfer substrate.
i) applying an electrocatalyst layer ink onto an ion-conducting membrane and then drying the ink to form an electrocatalyst layer then ii) applying a layer A ink onto the electrocatalyst layer then drying the ink to form a layer A;
wherein the electrocatalyst layer ink comprises an ion-conducting material IB
and an electrocatalyst; and the layer A ink comprises an ion-conducting material IA and a carbon containing material CA.
15. The method according to clause 14, further comprising applying a gas diffusion substrate to the layer A.
16. A method of preparing a membrane electrode assembly according to clause 8, the method comprising the steps of:
i) applying a layer A ink onto a substrate then drying the ink to form a layer A;
then ii) applying an electrocatalyst layer ink onto the layer A formed in step i) then drying the ink to form an electrocatalyst layer, iii) combining the layers with an ion-conducting membrane such that the electrocatalyst layer is adjacent to the ion-conducting membrane;
wherein the electrocatalyst layer ink comprises an ion-conducting material le and an electrocatalyst; and the layer A ink comprises an ion-conducting material IA and a carbon containing material CA.
17. A method according to clause 16, wherein the substrate is a decal transfer substrate and step iii) is carried out by transferring the combined layers onto an ion-conducting membrane by decal transfer from the transfer substrate.
18. A method according to clause 16, wherein the substrate is a gas diffusion layer.
Claims (9)
the layer A and the ion-conducting membrane are adjacent to opposite faces of the electrocatalyst layer;
the layer A comprises an ion-conducting material IA and a carbon containing material CA;
the electrocatalyst layer comprises an ion-conducting material IB and an electrocatalyst; wherein the layer A does not comprise an electrocatalyst; and the layer A has a permeability, ki, of greater than 20 nm2; and the electrocatalyst layer has a permeability, k2, of no more than 20 nm2; and the weight ratio of ion-conducting material IA to carbon containing material CA in layer A is in the range of and including 2:1 to 1:2;
wherein permeability is calculated from mercury intrusion porosimetry measurements in accordance with the procedure set out in the examples section in which mercury pressure is increased from ¨3.0 to 60,000 psia during a measurement, and the porosity at <1 micron and >3 nm pore diameter is used for calculating porosity characteristics.
Date Recue/Date Received 2023-01-10
i) applying an electrocatalyst layer ink onto an ion-conducting membrane and then drying the ink to form an electrocatalyst layer; then ii) applying a layer A ink onto the electrocatalyst layer then drying the ink to form a layer A.
i) applying a layer A ink onto a substrate then drying the ink to form a layer A;
then ii) applying an electrocatalyst layer ink onto the layer A formed in step i) then drying the ink to form an electrocatalyst layer;
iii) combining the layers with an ion-conducting membrane such that the electrocatalyst layer is adjacent to the ion-conducting membrane;
wherein the substrate is a decal transfer substrate and step iii) is carried out by transferring the combined layers onto an ion-conducting membrane by decal transfer from the transfer substrate.
Date Recue/Date Received 2023-01-10
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2019
- 2019-08-22 GB GBGB1912062.5A patent/GB201912062D0/en not_active Ceased
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2020
- 2020-08-21 KR KR1020227001915A patent/KR102765489B1/en active Active
- 2020-08-21 EP EP20764730.6A patent/EP4018500B1/en active Active
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| Publication number | Publication date |
|---|---|
| CN114080707B (en) | 2023-09-22 |
| US12249744B2 (en) | 2025-03-11 |
| KR102765489B1 (en) | 2025-02-12 |
| CA3141051A1 (en) | 2021-02-25 |
| US20220344694A1 (en) | 2022-10-27 |
| US20230369624A1 (en) | 2023-11-16 |
| WO2021032994A1 (en) | 2021-02-25 |
| EP4018500A1 (en) | 2022-06-29 |
| EP4018500B1 (en) | 2025-05-21 |
| GB201912062D0 (en) | 2019-10-09 |
| JP2022543189A (en) | 2022-10-11 |
| US11705568B2 (en) | 2023-07-18 |
| CN114080707A (en) | 2022-02-22 |
| JP7350971B2 (en) | 2023-09-26 |
| KR20220024743A (en) | 2022-03-03 |
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