WO2019136037A1 - Isothermal electricity for energy renewal - Google Patents
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- WO2019136037A1 WO2019136037A1 PCT/US2019/012002 US2019012002W WO2019136037A1 WO 2019136037 A1 WO2019136037 A1 WO 2019136037A1 US 2019012002 W US2019012002 W US 2019012002W WO 2019136037 A1 WO2019136037 A1 WO 2019136037A1
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Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J45/00—Discharge tubes functioning as thermionic generators
-
- 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 to a series of methods and systems for creating and using asymmetric function-gated isothermal electricity power generator systems to isothermally utilize environmental heat energy to generate electricity to do useful work.
- Dy is the electrical potential difference across the membrane; R is the gas constant; T is the absolute temperature in Kelvin (K); F is the Faraday constant; pH nB is pH of the cytoplasmic (negative n side) bulk phase; [H + pB ] is the proton concentration in the periplasmic (positive p side) bulk aqueous phase such as in the case of alkalophilic bacteria; C/S is the specific membrane capacitance; / is the thickness for localized proton layer; K Pi is the equilibrium constant for non-proton cations to exchange for localized protons; and
- is the concentration of non-proton cations in liquid culture medium (Lee 2015 Bioenergetics 4: 121. doi: 10.4172/2167-7662.1000121).
- the core concept of the proton-electrostatics localization hypothesis is based on the premise that a biologically-relevant water body, such as the water within a bacterium, can act as a proton conductor in a manner similar to an electric conductor with respect to electrostatics. This is consistent with the well-established knowledge that protons can quickly transfer among water molecules by the“hops and turns” mechanism. From the charge translocation point of view, it is noticed that hydroxyl anions are transferred in the opposite direction of proton conduction. This understanding suggests that excess free protons in a biologically-relevant water body behave like electrons in a perfect conductor. It is well known for a charged electrical conductor at static equilibrium that all extra electrons reside on the conducting body’s surface.
- the protonic capacitor concept is used to calculate the effective concentration of the ideal localized protons [H ] 0 at the membrane-water interface in a pure water-membrane-water system assuming a reasonable thickness (/) for the localized proton layer using the following equation:
- C/S is the membrane capacitance per unit surface area
- F is the Faraday constant
- k is the dielectric constant of the membrane
- e 0 is the electric permittivity
- d is the thickness of the membrane
- / is the thickness of the localized proton layer.
- the membrane potential Dy can now be expressed as a function of the effective concentration of the ideal localized protons [Hi ]° at the membrane-water interface in an idealized pure water-membrane-water system using the following equation:
- the dielectric constant (K) of a lipid bilayer was determined to be about 3 units, which is in the expected range of 2 ⁇ 4 units (Grames et al, Biophysical Journal 104: 1257-1262; Heimburg 2012 Biophysical Journal 103: 918-929.).
- Table 1 lists the calculation results for localized protons for an idealized pure water-membrane-water system with Eq. 2a using a lipid membrane dielectric constant k of 3 units, membrane thickness d of 4 nm, trans-membrane potential difference Dy of 180 mV, and three assumed values for the proton layer thickness of 0.5, 1.0, and 1.5 nm.
- the ideal localized proton density per unit area was calculated to be 1.238 x 10 8 moles H + /m 2 .
- the calculated effective concentration of ideal localized proton ([ ⁇ L ]°) was in a range from 8.25 mM to 24.76 mM if the localized proton layer is aroundl.0 ⁇ 0.5 nm thick.
- the calculated effective pH of localized proton layer (pH L °) was 1.61, 1.91, and 2.08 assuming that the ideal localized proton layer is 0.5, 1.0, and l.5-nm thick, respectively.
- the present invention discloses a series of methods on the creation and use of asymmetric function-gated isothermal electron power generator systems for isothermal electricity production by isothermally utilizing environmental heat energy which is also known as the latent (existing hidden) heat energy from the environment without requiring the use of conventional energy resources such as a high temperature gradient.
- a special energy- recycling and renewing technology is provided with the associated methods and systems to extract environmental heat energy including molecular and/or electron thermal motion energy for producing isothermal electricity to do useful work, which may have seminal scientific and practical implications for energy and environmental sustainability on Earth.
- the present invention specially discloses an energy renewal method for generating isothermal electricity with making and using a special asymmetric function-gated isothermal electricity power generator system comprising at least one pair of a low work function thermal electron emitter and a high work function electron collector across a barrier space installed in a container (such as a vacuum tube, bottle or chamber) with electric conductor support to enable a series of energy recycle process functions with isothermal utilization of environmental heat energy for at least one of: a) utilization of environmental heat energy for energy recycling and renewing of fully dissipated waste heat energy from the environment to generate electricity with an output voltage and electric current to do useful work; b) providing a novel cooling function for a new type of freezer/refrigerator without requiring any of the conventional refrigeration mechanisms of compressor
- the present invention teaches the making and using of an asymmetric function-gated isothermal electron-based power generator system that has a low work function (0.7 eV) Ag-O-Cs emitter and a high work function Cu metal (4.56 eV) collector installed in a chamber-like vacuum tube comprising: an Ag-O-Cs film coated on the dome-shaped top end inner surface of the chamber-like vacuum tube to serve as the emitter; a vacuum space allowing thermally emitted electrons to fly through ballistically between the emitter and collector; a Cu film coated on the inversed-dome-shaped bottom end inner surface of the chamber-like vacuum tube to serve as the collector; a first electricity outlet (such as an electric conductive wire and/or lead) connected with the emitter; and a second electricity outlet connected with the collector.
- a low work function (0.7 eV) Ag-O-Cs emitter and a high work function Cu metal (4.56 eV) collector installed in a chamber-like vacuum tube comprising: an Ag-O
- the present invention teaches the making and using of an integrated isothermal electricity generator system that has a narrow inter electrode space gap size for each of three pairs of emitters and collectors installed in a vacuum tube chamber set up vertically comprising: a low work function film coated on the first electric conductor plate bottom surface to serve as the first emitter; a first narrow space allowing thermally emitted electrons to flow through ballistically between the first pair of emitter and collector; a high work function film coated on the second electric conductor top surface to serve as the first collector; a low work function film coated on the second electric conductor bottom surface to serve as the second emitter; a second narrow space allowing thermally emitted electrons to flow through ballistically between the second pair of emitter and collector; a high work function film coated on the third electric conductor top surface to sever as a collector; a low work function film coated on the third electric conductor bottom surface to serve as the third emitter; a third narrow space allowing thermally emitted
- the effect of an asymmetric function gated isothermal electricity production is additive.
- Pluralities (n) of asymmetrically function gated isothermal electricity generator systems may be employed in parallel and/or in series.
- the total steady-state electrical current ( I st(t o t ai ) ) is the summation of the steady-state electrical current (/ st (i)) from each of the asymmetrically function-gated isothermal electricity generator systems while the total steady-state output voltage (E st(totai) ) remains the same.
- the total steady-state output voltage (E st(totai) ) is the summation of the steady-state output voltages (V st (l) ) from each of the asymmetrically function gated isothermal electricity generator systems while the total steady-state electrical current (4t (total)) remains the same.
- the present invention teaches the making and using of an integrated isothermal electricity generator system that employs three pairs of exceptionally low work function Ag-O-Cs (0.5 eV) emitters and high work function Au metal (5.10 eV) collectors working in series comprising: an Ag-O-Cs film coated on the dome shaped top end inner surface of the vacuum tube chamber to serve as the first emitter that has an electricity outlet; a first vacuum space allowing thermally emitted electrons to flow through ballistically across the first pair of emitter and collector; a Au film coated on the first middle electric conductor top surface to serve as the first collector; an Ag-O-Cs film coated on the first middle electric conductor bottom surface to serve as the second emitter; a second vacuum space allowing thermally emitted electrons to flow through ballistically across the second pair of emitter and collector; an Au film coated on the second middle electric conductor top surface to serve as the second collector; an Ag-O-Cs film coated on the second middle electric conductor top surface to serve as the second collector; an Ag-
- the present invention teaches the making and using of an asymmetric function-gated isothermal electricity generator system that has a pair of an exceptionally low work function Ag-O-Cs (0.5 eV) emitter and a high work function graphene (4.60 eV) collector is employed to provide cooling for a new type of novel freezer/refrigerator by isothermally extracting environmental heat energy from inside the freezer/refrigerator while generating isothermal electricity.
- an exceptionally low work function Ag-O-Cs (0.5 eV) emitter and a high work function graphene (4.60 eV) collector is employed to provide cooling for a new type of novel freezer/refrigerator by isothermally extracting environmental heat energy from inside the freezer/refrigerator while generating isothermal electricity.
- Fig. 13 presents an asymmetric function-gated isothermal electron power generator system 1000 comprising an asymmetric electron-gating function across a membrane-like barrier space that separates two electric conductors.
- Fig. 14a presents a basic unit of an asymmetric function-gated isothermal electron power generator system 1100 comprising a barrier space such as a vacuum space that separates a pair of electric conductors: one of them has a low work function film to act as a thermal electron emitter and the other has a high work function plate surface to serve as an electron collector.
- a barrier space such as a vacuum space that separates a pair of electric conductors: one of them has a low work function film to act as a thermal electron emitter and the other has a high work function plate surface to serve as an electron collector.
- Fig. 14b illustrates certain characteristics in the asymmetric function-gated isothermal electricity generator system 1100 such as the excess holes (positive charges) left at the emitter will also electrostatically spread to the surface, and likewise so do the excess electrons at the collector under the“open circuit” condition.
- Fig. 14c illustrates a preferred practice to ground the emitter with an Earth ground at the electricity outlet 1106 terminal of the asymmetric function-gated isothermal electricity generator system 1100.
- Fig. 15 presents the energy diagrams of the asymmetric function-gated isothermal electron power generator system 1100.
- Fig. 16a presents an example for a pair of silver (Ag) and molybdenum (Mo) electrodes installed in a vacuum tube as part of a fabrication process to create an asymmetric function-gated isothermal electricity generator system.
- Fig. 16b presents an example of a prototype isothermal electricity generating system using a low work function Ag-O-Cs film coated on the silver electrode surface to serve as a thermal electron emitter.
- Fig. 17a presents examples of the isothermal electricity current density (A/cm 2 ) as a function of operating temperature T at various output voltage V(c) from 0.00 to 3.86 V, as calculated using Eq. 12 for a pair of low work function (0.70 eV) emitter and high work function (4.56 eV) collector; in which the emitter was grounded.
- Fig. 17b presents examples of the isothermal electricity current density curves as a function of output voltage V(c) from 0.00 to 3.86 V at an operating temperature of 273, 293, 298, or 303 K for a pair of low work function (0.70 eV) emitter and high work function (4.56 eV) collector; in which the emitter was grounded.
- Fig. 17c presents examples of the isothermal electricity current density (A/cm 2 ) curves at an output voltage V(c) of 3.00 V as a function of operating environmental temperature T for a series of emitters with a low work function of 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, or 1.2 eV; each of these emitters is grounded and paired with a high work function (4.56 eV) collector.
- A/cm 2 isothermal electricity current density
- Fig. 18a presents examples of the isothermal electricity current density (A/cm 2 ) curves as a function of output voltage V(c) from 0.00 to 5.31 V at an operating environmental temperature of 273, 293, 298, and 303 K for a pair of low work function (0.6 eV) emitter and high work function (5.91 eV) collector; in which the emitter was grounded.
- A/cm 2 isothermal electricity current density
- Fig. 18b presents examples of the isothermal electricity current density (A/cm 2 ) as a function of operating environmental temperature T for a series of emitters with low work function values including 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.8, 2.0, or 2.2 eV; each of these emitters is grounded and paired with a high work function (5.91 eV) collector.
- A/cm 2 isothermal electricity current density
- Fig. 18c presents examples of the isothermal electricity current density (A/cm 2 ) at an output voltage V(c) of 4.00 V as a function of operating environmental temperature T for a series of emitters with low work function values including 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.8, or 2.0 eV; each of these emitters is grounded and paired with a high work function (5.91 eV) collector.
- A/cm 2 isothermal electricity current density
- Fig. 18d presents examples of the isothermal electricity current density (A/cm 2 ) at an output voltage V(c) of 5.00 V as a function of operating environmental temperature T for a series of emitters with low work function values including 0.4, 0.5, 0.6, 0.7, 0.8, or 0.9 eV; each of these emitters is grounded and paired with a high work function (5.91 eV) collector.
- Fig. 19a presents examples of the isothermal electricity current density (A/cm 2 ) curves as a function of output voltage V(c) volts from 0.00 to 4.10 V at an operating environmental temperature of 273, 293, 298, or 303 K for a pair of emitter work function (0.50 eV) and collector work function (4.60 eV), with the emitter grounded.
- Fig. 19b presents examples of the isothermal electricity current density (A/cm 2 ) curves as a function of output voltage V(c) volts from 0.00 to 4.10 V at freezing/refrigerating temperature of 253, 263, 273, or 277 K for a pair of emitter work function (0.50 eV) and collector work function (4.60 eV), with the emitter grounded.
- Fig. 19c presents examples of the isothermal electricity current density (A/cm 2 ) as a function of operating environmental temperature T for a series of emitters with low work function values including 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.8, 2.0, 2.2, 2.4, 2.6, 2.8, 3.0, or 3.5 eV; each of these emitters is grounded and paired with a high work function (4.60 eV) collector.
- A/cm 2 isothermal electricity current density
- Fig. 20 presents an example of an integrated isothermal electricity generator system 1300 that comprises multiple (e.g., three) pairs of emitters and collectors working in series.
- Fig. 21a presents an example of a prototype for an isothermal electricity generator system 1400A that has a pair of emitter (work function 0.7 eV) and collector (work function 4.36 eV) installed in a container such as a vacuum tube chamber.
- Fig. 21b presents an example of a prototype for an isothermal electricity generator system 1400B that has two pairs of emitters (work function 0.7 eV) and collectors (work function 4.36 eV) installed in a vacuum tube chamber.
- Fig. 21c presents an example of a prototype for an integrated isothermal electricity generator system 1400C that comprises three pairs of emitters (work function 0.7 eV) and collectors (work function 4.36 eV) installed in a vacuum tube chamber.
- Fig. 22 presents an example of an integrated isothermal electricity generator system 1500 that has a narrow inter electrode space gap size for each of three pairs of low work function emitters and high work function collectors installed in a vacuum tube chamber set up vertically.
- Fig. 23 presents an example of an integrated isothermal electricity generator system 1600 that has three pairs of low work function emitters and high work function collectors installed in a vacuum tube chamber set up vertically to utilize the gravity to help pull the emitted electrons from an emitter down to a collector.
- Fig. 24a presents an example of an isothermal electricity generator system 1700A that has a pair of low work function Ag-O-Cs (0.6 eV) emitter and high work function protonated polyaniline (4.42 eV) collector installed in a chamber-like vacuum tube container.
- a pair of low work function Ag-O-Cs (0.6 eV) emitter and high work function protonated polyaniline (4.42 eV) collector installed in a chamber-like vacuum tube container.
- Fig. 24b presents an example of an integrated isothermal electricity generator system 1700B that has two pairs of low work function Ag-O-Cs (0.6 eV) emitters and high work function of protonated polyaniline (4.42 eV) collectors working in series as installed in a chamber-like vacuum tube container.
- Fig. 24c presents an example of an integrated isothermal electricity generator system 1700C that has three pairs of low work function Ag-O-Cs (0.6 eV) emitters and high work function protonated polyaniline (4.42 eV) collectors operating in series as installed in a vacuum tube container.
- Fig. 25a presents another example of an isothermal electricity generator system 1800A that has a pair of low work function Ag-O-Cs (0.7 eV) emitter and high work function Cu metal (4.56 eV) collector installed in a chamber-like vacuum tube container.
- Fig. 25b presents another example of an integrated isothermal electricity generator system 1800B that has two pairs of low work function Ag-O-Cs (0.7 eV) emitters and high work function of Cu metal (4.56 eV) collectors operating in series as installed in a chamber-like vacuum tube container.
- Fig. 25c presents another example of an integrated isothermal electricity generator system 1800C that has three pairs of low work function Ag-O-Cs (0.7 eV) emitters and high work function Cu metal (4.56 eV) collectors operating in series as installed in a vacuum tube container.
- Fig. 26 presents an example of an integrated isothermal electricity generator system 1900 that employs three pairs of exceptionally low work function Ag-O-Cs (0.5 eV) emitters and high work function Au metal (5.10 eV) collectors operating in series as installed in a vacuum tube container.
- exceptionally low work function Ag-O-Cs 0.5 eV
- high work function Au metal 5.10 eV
- Fig. 27 presents an example of an integrated isothermal electricity generator system 2000 that employs three pairs of low work function doped-graphene (l.OleV) emitters and high work function graphite (4.60 eV) collectors operating in series as installed in a vacuum tube container.
- l.OleV low work function doped-graphene
- 4.60 eV high work function graphite
- Fig. 28 presents an example of an integrated isothermal electricity generator system 2100 that has three pairs of low work function doped-graphene (l.OleV) emitters and high work function graphene (4.60 eV) collector operating in series as installed in a vacuum tube container.
- l.OleV low work function doped-graphene
- 4.60 eV high work function graphene
- Fig. 29a presents photographs for a pair of parallel aluminum plate-supported silver (Ag) and copper (Cu) electrode plates (size: 40 mm x 46 mm) held together with electric- insulating plastic spacers (washers), screws and nuts at the four comers for each of the two electrode plates to make a pair of Ag-O-Cs type emitter (CsOAg) and Cu collector with or without oxygen plasma treatment.
- Fig. 29b presents photographs for a pair of parallel aluminum plate-supported silver (Ag) and copper (Cu) collector electrode plates (size: 40 mm x 46 mm) held together with electric-insulating plastic spacers (washers), heat-shrink plastic tube-insulated metal screws and nuts at the comers of the electrode plates.
- the silver (Ag) plate and copper (Cu) collector plate were connected by soldering with a red insulator coated copper wire and a blue insulator coated copper wire, respectively.
- the silver (Ag) electrode plate surface was coated with a thin molecular layer of cesium oxide (Cs 2 0) through painting with a dilute cesium oxide solution followed by drying to form a type of Ag-O-Cs emitter (CsOAg) with or without oxygen plasma treatment.
- Cs 2 0 cesium oxide
- CsOAg Ag-O-Cs emitter
- Fig. 30 presents a photograph of the parts for a prototype CsOAg-Cu electrobottle that comprise a pair of parallel aluminum plate-supported silver (Ag, coated with Cs 2 0) and copper (Cu) plates installed with the red and blue insulator coated copper wires passing through a screw bottle cap. Two blue plastic air tubes were installed through two additional holes in the screw bottle cap. Electric-insulating and air-tight Kafuter 704 RTV silicone gel (white) was used to seal the joints for the wires and tubes passing through the bottle cap.
- Kafuter 704 RTV silicone gel white
- Fig. 31a presents a photograph showing four prototype CsOAg-Cu electrobottles that were fabricated using crew bottle caps.
- Each electrobottle comprises a pair of parallel aluminum plate-supported CsOAg (a type of Ag-O-Cs emitter) and Cu collector electrode surfaces installed with red and blue insulator coated wires passing through a screw bottle cap.
- CsOAg a type of Ag-O-Cs emitter
- Cu collector electrode surfaces installed with red and blue insulator coated wires passing through a screw bottle cap.
- Kafuter 704 RTV silicone gel white
- Fig. 31b presents a photograph of 17 prototype CsOAg-Cu electro-bottles that were made using non-screw bottle caps and sealed with electric-insulating and air-tight Kafuter 704 RTV silicone gel (white) material.
- Fig. 32a presents a photograph showing a prototype CsOAg-Cu electrobottle that was placed into a Faraday box for isothermal electricity production testing by connecting its red and blue insulator coated copper wires (passing across the non-screw bottle cap) with Keithley 6514 electrometer system’s Model 237-ALG-2 low noise cable-alligator clips.
- Fig. 32b presents a photograph of a Faraday box made of heavy-duty aluminum foils containing a prototype CsOAg-Cu electrobottle inside for isothermal electricity production testing with a Keithley 6514 system electrometer.
- Fig. 33a presents a photograph of a prototype CsOAg-Cu electrobottle placed inside a Faraday box and tested in normal polarity (Keithley 6514 red alligator connector to CsOAg emitter plate and black alligator connector to Cu collector plate), showing an electric current reading of“11.888 pA.CZ”.
- Fig. 33b presents a photograph of a prototype CsOAg-Cu electrobottle placed inside a Faraday box and tested in reverse polarity (Keithley 6514 black alligator connector to CsOAg emitter plate and red alligator connector to Cu collector plate), showing an electric current reading of“-11.030 pA.CZ”
- Fig. 34a presents a photograph of a prototype CsOAg-Cu electrobottle placed inside a Faraday box and tested in normal polarity (Keithley 6514 red alligator connector to CsOAg emitter plate and black alligator connector to Cu collector plate), showing an electric voltage reading of“0.10051 V.CZ”
- Fig. 34b presents a photograph of a prototype CsOAg-Cu electrobottle placed inside a Faraday box and tested with an electric shorting wire between the terminals (outlets) of CsOAg emitter and Cu collector, showing an electric voltage reading of“-0.00001 V.CZ”.
- Fig. 34c presents a photograph of a prototype CsOAg-Cu electrobottle placed inside a Faraday box and tested in reverse polarity (Keithley 6514 black alligator connector to CsOAg emitter and red alligator connector to Cu collector, showing an electric voltage reading of “-0.11329 V.CZ”
- Fig. 35 presents a photograph of two prototype CsOAg-Cu electrobottles connected in parallel in normal polarity (Keithley 6514 red alligator connector to CsOAg emitter plates and black alligator connector to Cu collector plates) inside a Faraday box, showing an electric current reading of“22.230 pA.CZ”.
- Fig. 36 presents a photograph of three prototype CsOAg-Cu electrobottles connected in parallel with their normal polarity (Keithley 6514 red alligator connector to CsOAg emitter plates and black alligator connector to Cu collector plates) inside a Faraday box, showing an electric current reading of“26.166 pA.CZ”.
- the present invention discloses a series of methods on the creation and use of asymmetric function-gated isothermal electron power generator systems for isothermal electricity production by isothermally utilizing latent (existing hidden) heat energy from the environment without requiring the use of conventional energy resources such as a high temperature gradient.
- the present invention discloses an energy renewal method for generating isothermal electricity with making and using a special asymmetric function-gated isothermal electricity power generator system comprising at least one pair of a low work function thermal electron emitter and a high work function electron collector across a barrier space installed in a container such as a bottle with electric conductor support to enable a series of energy recycle process functions with utilization of environmental heat energy isothermally for at least one of: a) utilization of environmental heat energy for energy recycling and renewing of fully dissipated waste heat energy from the environment to generate electricity with an output voltage and electric current to do useful work; b) providing a novel cooling function for a new type of freezer/refrigerator without requiring any of the conventional refrigeration mechanisms of compressor, condenser, evaporator and/or radiator by isothermally extracting latent energy from inside the freezer/refrigerator while generating isothermal electricity; and c) combinations thereof.
- this electron-based energy renewal method teaches how to isothermally extract environmental heat energy to generate electricity by teaching the making and using of an asymmetric function-gated isothermal electron-based power generator such as the asymmetric electron-gated system 1000 illustrated in Fig. 13.
- the system 1000 (Fig. 13) comprises an asymmetric electron-gating function 1003 across a membrane-like barrier space 1004 that separates two electric conductors 1001 and 1002 acting as a pair of a thermal electron emitter and an electron collector, two electrically conducting leads 1006 and 1007 connected with each of these electrodes 1001 and 1002 as the two power outlet terminals that may be connected with an electrical load 1008.
- the barrier space 1004 is preferably a special electric insulator which contains no electric conduction materials (does not conduct electrons through any molecular orbital-associated conduction bands) but allows the thermally emitted electrons to fly through ballistically across the emitter and collector.
- the barrier space 1004 comprises a vacuum space that has no electric conductive materials and/or molecules with molecular orbital-associated electric conduction bands but allows the thermally emitted electrons to fly and/or flow through ballistically.
- the asymmetric electron-gating function 1003 effectively allows freely emitted thermal electrons 1005 to ballistically fly predominantly from the electric conductor (emitter) 1001 through the barrier space 1004 to the electric conductor (collector) 1002 although the two electric conductors 1001 and 1002 are under the same temperature and pressure conditions.
- the barrier space 1004 is an electrical insulating space without the conventional conductor-based electrical conduction but has a unique property that allows thermal electrons to fly through ballistically, it prevents the excess thermal electrons captured by the collector 1002 from conducting back to the emitter except the minimal back emission from the collector that may be controlled by the asymmetric electron-gating function 1003. As a result, the excess thermal electrons captured by the collector 1002 may accumulate, thermally equilibrate and electrostatically distribute themselves mostly to the collector 1002 electrode surface. Similarly, the excess positive charges (‘holes”) left in the emitter may also accumulate and electrostatically distribute themselves mostly to the emitter 1001 electrode surface.
- holes excess positive charges
- the asymmetric electron-gating function comprise a pair of a low work function film 1103 formed on the surface of electric conductor 1101 to serve as the emitter, a high work function plate 1109 as part of electric conductor 1102 to serve as the collector, a barrier space 1104 that separates the emitter and the collector, two electrically conducting leads 1106 and 1107 that are connected with each of these electrodes 1101 and 1102 to serve as the two power terminals that may be connected with an electrical load 1108.
- Fig. l4a illustrates a basic unit of an asymmetric function-gated isothermal electron power generator system 1100 comprising a barrier space 1104 such as a vacuum space that separates a pair of electric conductors 1101 and 1102: one of them has a low work function film 1103 surface and the other has a high work function plate 1109 surface.
- the film 1103 is made of a low work function material such as Ag-O-Cs that has a work function as low as about 0.7 eV to serve as the emitter.
- the barrier space 1104 is a special electric insulator space such as vacuum space that does not conduct electricity by the regular electric conduction but allow free thermal electrons 1105 to fly or flow through ballistically.
- barrier space 1104 and low work function film 1103 enable significant amounts of the ambient temperature thermal electrons to emit from the film surface into the barrier space 1104 and fly ballistically towards the collector that is a high work function plate 1109 such as a copper plate which has a work function as high as about 4.65 eV.
- a high work function plate 1109 such as a copper plate which has a work function as high as about 4.65 eV.
- At ambient temperature around 298 K, such a high work function plate 1109 practically has nearly zero emission of thermal electrons from its surface whereas it can accept the thermal electrons flying through the barrier space from the emitter 1101.
- the excess electrons in the collector electrode with such an output voltage V output can drive an electric current through an external circuit, which comprises an electric outlet 1107 (-) wire connected with an electrical load 1108 that is connected with another electric wire as electric outlet 1106 (+) back to the emitter 1101 as shown in Fig. l4a.
- an external circuit which comprises an electric outlet 1107 (-) wire connected with an electrical load 1108 that is connected with another electric wire as electric outlet 1106 (+) back to the emitter 1101 as shown in Fig. l4a.
- a portion of the environmental heat energy (thermal motion energy) associated with the thermal electrons is utilized to perform work through use of an electrical load 1108 in this example.
- Fig. 15 presents the energy diagrams of the asymmetric function-gated isothermal electron power generator system 1100.
- the work function (WF(e)) of the emitter 1101 (Fig. l4a) is the energy level difference between the Fermi energy level (E(F, e)) of the emitter and the vacuum energy level (E(vacuum, ⁇ ) of a free electron that is considered“infinitely” ( ⁇ ) far away from the emitter and collector surfaces; while the work function (WF(c)) of the collector 1102 is the difference between the collector’s Fermi energy level (E(F, c)) and the vacuum energy level (E(vacuum, ⁇ ).
- an emitter with a work function as low as possible such as about 0.7 eV so that significant amounts of the ambient temperature thermal electrons can emit from the emitter surface into the vacuum barrier space 1104 and fly ballistically with kinetic energy (E(k)) towards the collector 1109 that has a work function (WF(c)) much larger than that of the emitter (WF(e)).
- a work function as low as possible such as about 0.7 eV
- E(k) kinetic energy
- WF(c) work function much larger than that of the emitter
- the activity of the asymmetric function-gated thermal electron power generation process will result in the accumulation of excess electrons in the collector thus generating a negative voltage V(c) there; Meanwhile, this may also result in the accumulation of excess positive charges at the emitter thus generating a positive voltage V(e) there.
- the negative voltage V(c) at the collector will push up its effective Fermi level by the absolute value of V(c) to that of E(F, c) minus the negative voltage V(c) (labeled as“E(F, c) - V(c)” in the 1100 (b) of Fig. 15); whereas the positive voltage V(e) at the emitter will push down its effective Fermi level to a lower level of (E(F, e) - V(e)) as shown in the 1100 (b) of Fig. 15 (middle).
- the effective work function of the emitter at the equilibrated state (WF(e)eq) is increased by the product e V(e) of the election charge e and V(e) to a higher value (WF(e) + e V(e)) while the effective work function of the collector (WF(c)eq) is decreased by the absolute value of e-V(c) to a lower (smaller) value (WF(c) + e-V(c)).
- the ambient-temperature electron emission at the emitter 1101 will continue until the effective Fermi level of the collector (E(F, c) - V(c)) will rise so much by the absolute value of V(c) that will match at the same level of the emitter E(F, e) with WF(e) as shown in the 1100(c) of Fig. 15 (right).
- the back emission flow of the ambient-temperature electrons from the collector 1102 to the emitter 1101 will cancel the flow of the ambient-temperature electrons from the emitter 1101 to the collector 1102 at an equal rate.
- V(c) will equal to the difference between the collector work function WF(c) and emitter work function WF(e) over the electronic unit charge ( e for electron e ).
- This asymmetric function-gated isothermal electron power generator system 1100 (Fig. 14) is fundamentally different from the conventional temperature gradient-driven thermionic converter reported previously by Hatsopoulos and Gyftopoulos 1973 (Thermionic Energy Conversion, Volume I: Processes and Devices, The MIT Press, Cambridge, Massachusetts, and London, England).
- the conventional thermionic converter converts heat to electricity by boiling electrons from a very hot emitter surface (-2000 K) across a small inter electrode gap ( ⁇ 0.5 mm) to a cooler collector surface (-1000 K), which requires a large temperature gradient and clearly is not an isothermal operation in contrast to the isothermal electricity generation disclosed in the present inventions.
- the thermionic converter is a form of heat engine which runs by using a temperature gradient, it is believed to be limited by the Carnot efficiency, at best.
- a high work function electrode is typically used as the emitter that is heated up by a high temperature heat source while a low work function electrode is used as the collector that is cooled by a cold heat sink so that the conventional thermionic electricity generation is believed to be driven by the temperature difference between the heated emitter and the cooled collector in“following the second law of thermodynamics”.
- both the emitter 1101 and the collector 1102 can be used at the same ambient temperature ( isothermal conditions) without requiring the use of a significant temperature gradient between the emitter and the collector.
- the isothermal electron power generator system which isothermally extracts latent heat energy from the environment for generating useful electricity perfectly follows the first law of thermodynamics but without being constrained by the second law of thermodynamics owning to the use of the special asymmetric function-gated mechanisms.
- a conducting electrode (emitter) is heated to high temperatures so that it emits electrons (Wanke et al 2017 MRS Bulletin 42: 518-524). These thermionic electrons overcome the electrode’s work function and generate a thermionic emission current. It typically requires the emitter being heated by using an external energy/heat source such as focused solar irradiation, intensified chemical combustion, or nuclear decay reaction heat to a temperature as high as 2000K while the collector is cooled to below about 600K using a heat sink (Sandia Report, SAND2004-0555).
- an external energy/heat source such as focused solar irradiation, intensified chemical combustion, or nuclear decay reaction heat
- Air- breathing chemical heat sources such as common hydrocarbon burners, cannot achieve the desired thermionic temperatures (-2000K) unless substantial air-preheat is used. That is, the thermionic converter operation is based on an exceptionally high temperature at the emitter with a large temperature difference between the two electrodes (thermionic emitter and collector). The elevated high temperatures required by the thermionic converter impose formidable technical problems concerning the structure of the fuel elements and the means of transferring heat to the converters.
- the Camot efficiency here is believed to represent the ultimate efficiency limit (Khalid et al 2016 IEEE Transactions on Electron Devices 63: 2231-2241).
- the asymmetric function-gated isothermal electron power generator system disclosed in the present invention does not require such an elevated high temperature and is not constrained by the Camot efficiency, since it can generate electricity by isothermally utilizing the ambient temperature latent heat energy from the surrounding environment without requiring any of such energy-intensive heating and/or cooling energy resources.
- the asymmetric electron-gating function 1003 (Fig. 13) that comprises the utilization of low work function emitter 1103 (Fig. l4a) typically coated on the surface of an electric conductor 1101, which is able to emit thermal electrons even at the ambient temperature (such as 293 K (20 °C)) and the utilization of higher work function collector 1109 on an electric conductor plate 1102 surface under the ambient temperature conditions that essentially will not emit electrons but be able to collect the thermal electrons from the emitter 1103.
- this asymmetric electron gating function that enables the flow of thermal electrons 1105 through the vacuum barrier space 1104 from the emitter 1103 to the collector 1109 under the isothermal conditions, generating an electricity output with a voltage difference across the two outlets 1106 (+) and l007(-) without being constrained by the second law of thermodynamics. Therefore, this asymmetric function- gated isothermal electron power generator system 1100 (Fig. 14) represents a special Anti- Second-Law energy technology function that is capable of energy renewal by extracting the latent (existing hidden) heat energy from the ambient environment through the use of thermal electrons associated with the emitter and the collector and converting it to useful energy in the form of electricity under the isothermal conditions. Fundamentally, this is somewhat similar to the Anti-Second-Law energy renewal function disclosed previously with the systems of localized protons (WO2017/007762 Al, US 2017/0009357 Al).
- an asymmetric function-gated isothermal electricity generator system is designed to isothermally operate at a temperature or temperature range selected from a group consisting of 193K (-80 °C), 200K (-73 °C), 21 OK (-63 °C), 220K (-53 °C), 230K (-43 °C), 240K (-33 °C), 250K (-23 °C), 260K (-13 °C), 270K (-3 °C), 273K (0 °C), 278K (5 °C), 283K (10 °C), 288K (15 °C), 293K (20 °C), 298K (25 °C), 303K (30 °C), 308K (35 °C), 3l3K (40 °C), 3l8K (45 °C), 323K (50 °C), 328K (55 °C), 333K (60 °C), 338K (
- the words“to isothermally operate” here means that both the emitter and collector are placed at the same temperature and no temperature difference between the emitter and collector is required for the asymmetric function-gated isothermal electricity generation to run in accordance with one of the various embodiments of the present invention.
- the work function of the emitter is preferably selected to be less than 1.0 eV, more preferably less than 0.8 eV, even more preferably less than 0.7 eV or 0.6 eV, and most preferably less than 0.5 eV.
- exceptionally low work function materials should be selected for use as the emitters.
- the work function of the emitters for the purpose of extracting environmental heat to generate electricity may be selected from the group consisting of 0.2 eV, 0.3 eV, 0.4 eV, 0.5 eV, 0.6 eV, 0.7 eV, 0.8 eV, 0.9 eV, 1.0 eV, 1.1 eV, 1.2 eV, 1.3 eV, 1.4 eV, 1.5 eV, 1.6 eV, 1.7 eV, 1.8 eV, 1.9 eV, 2.0 eV, 2.1 eV, 2.2 eV, 2.4 eV, 2.6 eV, 2.8 eV, 3.0 eV and/or within a range bounded by any two of these values.
- the collector electrode 1102 is preferable to have a work function higher than that of its pairing emitter 1101 (Fig. 14) so that no appreciable isothermal electron emission occurs at the collector surface.
- the work function of the collectors for the purpose of extracting environmental heat to generate isothermal electricity is selected from the group consisting of 1.0 eV, 1.1 eV, 1.2 eV, 1.3 eV, 1.4 eV, 1.5 eV, 1.6 eV, 1.7 eV, 1.8 eV, 1.9 eV, 2.0 eV, 2.1 eV, 2.2 eV, 2.4 eV, 2.6 eV, 2.8 eV, 3.0 eV, 3.2 eV, 3.4 eV, 3.6 eV, 3.8 eV,
- the work function represents the energy barrier for an electron at the Fermi level from escaping the solid (such as the metal conductor) to free space.
- the work function commonly comprises two components: a bulk component and a surface component. The dominant one is the bulk component which corresponds to the chemical potential that derives from the electronic density and density of states with relation to the nuclear (positive) charge force in the solid.
- the surface component also known as the surface dipole component
- the surface component originates with a redistribution of charges at the surface of a metal, which give rise to the surface dipole that is generally resulted from the“spill out” of electrons into vacuum over some small distance (Angstroms), creating negative sheet of charges outside the solid and leaving a positive sheet of uncompensated metal ions in the surface and sub-surface atomic planes. It is this double sheet of charges (surface dipoles) that create a potential step which raises the electron potential just out the surface, effectively also raising the electron vacuum energy level at the emitter electrode surface Evac (S).
- This surface dipole-associated component may correspond to the energy difference between the Evac (S) (the vacuum energy level at the emitter electrode surface) and the Evac ( ⁇ ) in vacuum space far away from the surface.
- the surface dipole- associated negative charge could repel an electron away the electrode. Consequently, the electrons leaving the emitter surface could be accelerated towards the collector by this repulsive force from the emitter’s surface dipole, which may be beneficial to the isothermal electricity generation.
- the collector also has a surface dipole-associated negative charge component that could potentially impede the reception of the electrons emitted from the emitter by repelling them away from the collector surface.
- a collector electrode that has no or minimized surface dipole-associated negative charge component.
- the surface dipole-associated negative charge component on the collector surface, it needs to be nearly equal to or smaller than that of the emitter surface for the isothermal electricity generator to more efficiently operate. That is, it is beneficial to use a work function that originates predominately from the nuclear (positive) charge force with no or minimal surface dipole- associated negative charge force for the collector to better collect the electrons emitted from the emitter.
- the emitter is a layer or film of a special lower work function material 1103 coated on a conductive electrode 1101 while the collector 1109 is a film of higher work function coated on conductive electrode 1102 and/or is simply a plate of higher-work-function conductor.
- the emitter material is selected from a group consisting of Ag-O-Cs, Cs20-coated Ag plate surface, K-O/Si(l00), Cl2A7:e-, K on WTe2, P-doped diamond, P-doped diamond, Ca24Al 2 8064, Cs/O doped graphene, Sri -x Ba x V03, Ba-coated SiC, O-Ba on W, Cs on Pt metal and combinations thereof.
- the collector material is selected from a group consisting of platinum (Pt) metal, silver (Ag) metal, gold (Au) metal, copper (Cu) metal, molybdenum (Mo) metal, aluminum (Al) metal, tungsten, rhenium, molybdenum, niobium, nickel, graphene, graphite, polyaniline film, ZnO metal oxide, ITO metal oxide, FTO metal oxide, 2-dimensional nickel, PEDOT:PSS, protonated-polyaniline film and combinations thereof.
- platinum (Pt) metal silver (Ag) metal, gold (Au) metal, copper (Cu) metal, molybdenum (Mo) metal, aluminum (Al) metal, tungsten, rhenium, molybdenum, niobium, nickel, graphene, graphite, polyaniline film, ZnO metal oxide, ITO metal oxide, FTO metal oxide, 2-dimensional nickel, PEDOT:PSS, protonated-polyaniline film and combinations thereof.
- the materials for making the electric conductors 1191 and 1102 that support the emitter and/or collector, and that may also directly serve as the collector are selected from the group consisting of: heat-conducting electric conductors, heat-conducting metallic conductors, refractory metals, metal alloys, stainless steels, aluminum, copper, silver, gold, platinum, molybdenum, conductive M0O3, tungsten, rhenium, molybdenum, niobium, nickel, titanium, graphene, graphite, heat-conducting electrically conductive polymers, polyaniline film, protonated-polyaniline film and combinations thereof.
- a conductor with no or minimized surface dipole-associated work function component to serve as a collector electrode to facilitate the collection of the electrons from the emitter.
- nonpolar organic conductors typically have no significant“spilling” of electrons at the surface and can thus be selected to use as a collector electrode.
- a major problem that has been hindering the performance of the conventional thermionic converter is the formation of the static electron space-charge clouds in the inter electrode space (Physics of Plasmas 21, 023510 (2014); doi: 10.1063/1.4865828).
- This“space charge problem” is minimized in the asymmetric function-gated isothermal electricity generation system (Fig. 14), for example, by its design to operate at a significantly lower current density (/) across the interelectrode space (often in a range from sub Amp/cm 2 to no more than a few Amp/cm 2 ) than that of the conventional thermionic converter which typically is on the order of over 10-100 A/cm 2 (temperatures 1000-2000 K).
- the“space charge problem” is minimized by a number of ways selected from the group consisting of: 1) by operating the isothermal electricity generation system (Fig. 14) naturally at a relatively lower current density (/) across the interelectrode space (in a range from sub Amp/cm 2 to no more than a few Amp/cm 2 ); 2) by grounding the emitter as shown in Fig.
- a series of capacitors can be used across each of pairs of the emitters and the collectors with the isothermal electricity outlets (illustrated in the example of Fig. 20 below) to increase the capacitance across each pair of the emitter and collector to improve the stability and efficacy of the isothermal electricity generator system.
- the capacitance across each pair of the emitter and collector is increased by properly narrowing the space separation distance between the emitter surface and the collector surface (illustrated in the example of Fig. 22 below) to improve the stability and efficacy of the isothermal electricity generator system.
- a smaller and highly evacuated interelectrode space gap distance can limit the number of electrons travelling within it. Excessive numbers of electrons in transit will form an electron cloud, causing decreased efficiency due to the space charge effect. Therefore, it is a preferred practice to properly minimize the separation distance between the emitter surface and the collector surface to increase capacitance and limit the formation of the static electron space-charge clouds in the inter electrode space for enhanced isothermal electricity generation.
- the barrier space separation distance between the emitter surface and the collector surface should be big enough (somewhat larger than the electron tunneling distance (2 or 3 nm)) to avoid electricity current leaking loss due to the possible electron tunneling.
- the electron density of a metal actually extends outside the surface of the metal.
- the distance outside the surface of the metal at which the electron probability density drops to 1/1000 of that just inside the metal is on the order of 0.1 to 1 nanometer (nm) for electron tunneling which is strongly dependent on the distance.
- the electron tunneling distance is also depending on the property of the materials and barrier space.
- the inter electrode space separation distance (gap size d) across a pair of emitter and collector is selected from the group consisting of 2 nm, 3 nm, 4 nm, 5 nm, 6nm.
- a barrier space composition is selected from the group consisting of vacuum space, semi-vacuum space, gaseous space, inertial gas space, special gas space, ballistic-electron-permeable porous material space, perforated two- dimensional (2D) materials, perforated insulator film such as perforated Teflon film, and combinations thereof.
- emitter(s) and collector(s) are installed in a vacuum container such as a vacuum electrotube (Fig. 16), vacuum bottle, vacuum chamber, and/or vacuum box with certain vacuum space.
- the vacuum container wall is made with a varieties of heat-conducting materials in combination of electric insulating materials that are selected from the group consisting of heat-conducting metals including stainless steels, aluminum, copper and metal alloys, vacuum-tube glass, vacuum lamp-bulb glass, electric insulating materials, carbon fibers composite materials, vinyl ester, epoxy, polyester resin, air tight electric-insulating Kafuter 704 RTV silicone gel material, thermoplastic, highly heat- conductive graphene, graphite, cellulose nanofiber/epoxy resin nanocomposites, heat-conductive and electrical insulating plastics, heat-conductive and electrical insulating ceramics, heat- conductive and electrical insulating glass, fiberglass-reinforced plastic materials, borosilicate glass, Pyrex glass, fiberglass, sol-gel, silicone gel,
- the interfacing contact/seal between the container wall and the electrode plates and/or electric wires is made with heat-conductive and electrical insulating material(s).
- the interfacing contact/seal material (s) is selected from the group consisting of heat-conductive and electrical insulating plastics, epoxy, polyester resin, air-tight electric-insulating Kafuter 704 RTV silicone gel material, thermoplastic, heat-conductive and electrical insulating ceramics, heat-conductive and electrical insulating glass, highly heat- conductive graphene, graphite, clear plastics, for example, Acrylic (polymethyl methacrylate, PMMA), Butyrate (cellulose acetate butyrate), Lexan (polycarbonate), and PETG (glycol modified polyethylene terephthalate), polypropylene, polyethylene, and polyethylene HD, thermally conductive transparent plastics, heat conductive glues, electric insulating glues, heat conductive paint, electric insulating
- an asymmetric function-gated isothermal electrons-based environmental heat energy utilization system comprises a low work function of Ag-O-Cs coated on an Ag metal electrode surface to serve as an emitter and a high work function of a Cu metallic conductor to serve as a collector in a vacuum condition.
- a prototype of an asymmetric function gated isothermal electrons-based environmental heat energy utilization system comprises a pair of a low work function Ag-O-Cs film 1203 (coated on a silver electrode 1201 surface) and a high work function Mo metallic conductor 1202 separated by a vacuum space 1204 in a vacuum tube (Fig. 16).
- the Ag-O-Cs film 1203 coated on the silver electrode 1201 is used as the emitter while the Mo metallic conductor 1202 is used as the collector.
- a Mo-O-Cs film sometimes co-produced may also be used as the collector since it typically has a work function higher (bigger) than that of the Ag-O-Cs film.
- Figure 16 illustrates an example of how such a prototype system can be fabricated and tested for isothermal electricity generation.
- a pair of silver and molybdenum electrodes was installed in a vacuum tube as shown in Fig. l6a.
- a cesium (Cs) vapor with a small amount of oxygen was introduced into the vacuum electrotube.
- the molybdenum electrode was used as a temporary anode to oxidize the silver electrode surface by a type of oxygen plasma discharge with the Cs vapor and subsequently resulted in the formation of an Ag-O-Cs film on the silver electrode 1201 surface as shown in Fig. l6b.
- this fabrication process also results in the co-generation of a Mo-O-Cs film on the molybdenum electrode 1202.
- a prototype of an asymmetric function gated electrotube system like the one shown in Fig. l6b can isothermally generate electricity that can be measured at an ambient temperature such as 25 °C (298 K) using the input resistance of an electrometer as the load. It is predicted that when the outlet terminal 1206 of emitter 1201 is connected with a Model 237-ALG-2-type low-noise-cable positive (red) input connector of an electrometer while the output terminal 1207 of collector 1202 is connected with the negative (black) input connector, it will measure a positive electric current that is generated by the isothermal electricity generating system (Fig. l6b).
- the isothermal electricity generating system (Fig. l6b) is expected to give a measurable negative current to the electrometer.
- the isothermal electricity power generation density cross-section area of the interelectrode space was calculated to be about 6.78 x 10 1 Watt/cm 2 in this example of an experimental prototype system (Fig. l6b).
- Table 7 presents more examples of experimental data on the isothermal electricity current density of the asymmetric work function-gated electrotubes similar to that of Fig. l6b as measured in both the normal and reverse orientations. It was noticed that the amplitude of the isothermal electricity current density measured in the normal orientation occasionally was somewhat larger than that measured in the reverse orientation.
- the values of the isothermal electricity current density measured in the normal orientation were 5.17, 4.90, 7.06 and 9.62 pA/cm 2 which appeared to be slightly larger than the absolute values of those (-4.50, -1.63, -2.72, and -5.52 pA/cm 2 ) in the reverse orientation.
- the isothermal electricity current density averaged from the absolute values measured in both orientations was 3.26, 4.87, and 7.57 pA/cm 2 for the asymmetric work function-gated electrotube samples 2, 3 and 4, respectively.
- the corresponding averaged voltage output was 94, 141 and 218 mV.
- the isothermal electricity power density calculated as the product of the isothermal electricity current density and corresponding voltage output was 3.07 x 10 13 , 6.90 x 10 13 , and 1.65 x 10 12 Watt/cm 2 for the asymmetric work function-gated electrotube samples 2, 3 and 4, respectively, under the given experimental conditions without any optimization efforts.
- Table 7 lists more examples of experimental data on the isothermal electricity current density (pA/cm 2 ) of asymmetric work function-gated electrotubes similar to that of Fig. l6b as measured in normal and reverse orientations and the observed output voltage (mV) and isothermal electricity power density (Watt/cm 2 ).
- the ideal net flow density (flux) of the emitted electrons 1105 from the emitter 1101 to the collector 1102 which is defined also as the ideal isothermal electron flux ( Ji soT ) normal to the surfaces of the emitter and collector (also named as the ideal isothermal electricity current density defined as amps (A) per square centimeters of the cross-section area of the emitter-collector interelectrode space), can be calculated based on the Richardson- Dushman formulation using the following ideal isothermal current density (J LSO T ) equation:
- T is the absolute temperature in Kelvin (K) for both the emitter and the collector; WF(e) is the work function of the emitter surface; the term of e V (e) is the product of the electron unit charge e and the voltage V (e) at the emitter; k is the Boltzmann constant in (eV/K); WF(c ) is the work function of the collector surface; and e V(c) is the product of the electron unit charge e and the voltage V (c) at the collector.
- the ideal net isothermal electrons flow density across the vacuum space from the emitter 1101 to the collector 1102 can be calculated using the following modified ideal isothermal current density (Ji S0T ⁇ gnd ) ) equation:
- the“open circuit” ideal saturation output voltage ( V sat ) at the equilibrium between the emitter and collector terminals (1106 and 1107) as shown in Fig. l4c can be expressed as the difference in the work functions:
- e is the electron charge which is 1 (an electron charge unit); and WF ⁇ and WF (e) are the collector work function and the emitter work function, respectively, as illustrated in the 1100 (c) of Fig. 15 (right).
- the steady-state operating output voltage (F st ) between the emitter and collector terminals (1106 and 1107) can be expressed as:
- V st V ⁇ c) - V (e) [15]
- V (c) and V (e ⁇ are the steady-state operating voltages at the collector and emitter, respectively, as illustrated in the 1100 (b) Fig. 15 (middle).
- the ideal saturation electrical current (hat) across the inter electrode space between the emitter and collector as shown in Fig. l4a can be expressed as the product of the interelectrode space cross section (emitter surface) area (S) and the ideal saturation isothermal electron flux as known as the saturation current density (J isoT(sat) ) with the following equation:
- the ideal steady-state operating electrical current (/ st ) through the electrical load 1108 as shown in Fig. l4a can be expressed as:
- Ri is the resistance of the electrical load and R m is any possible miscellaneous resistance from the circuit including the electrodes and wire materials;
- V st is the steady-state operating output voltage as of Eq. [15]
- the effect of the asymmetric function- gated isothermal electricity generating activity is additive. That is, the asymmetric function- gated isothermal electricity generator systems like the one shown in Fig. 14 can be used in series and/or in parallel. When a plurality (n) of the asymmetric function-gated isothermal electricity generator systems like the one shown in Fig. 14 are used in the series, the total steady-state output voltage is the summation of the steady-state output voltages as of Eq.
- V S at(totai) is the summation of the saturation output voltages as of Eq. [14]) from each of the asymmetric function-gated isothermal electricity generator systems operating in series:
- the total ideal electrical current ( hat(totai ) ) is the summation of the ideal electrical current (/ sat(i) as of Eq.
- the asymmetric function-gated isothermal electricity production is additive.
- Pluralities (n) of the asymmetric function-gated isothermal electricity generator systems may be used in parallel and/or in series, depending on a given specific application and its associated operating conditions such as temperature conditions, and the properties of the barrier spaces such as their thickness and compositions, the properties of the emitter and collector electrodes and other physical chemistry properties.
- the total steady-state electrical current ( I s t(totai ) ) is the summation of the steady-state electrical current (/ st(i) ) from each of the asymmetric function-gated isothermal electricity generator systems while the total steady-state output voltage (V st(t0tai) ) remains the same.
- WF(e) 0.70 eV
- WF(c) 4.56 eV, copper Cu(l lO)
- the ideal isothermal electricity power production density (W/cm 2 ) at various output voltage V(c) volts can be expressed as:
- WF(e) 0.70 eV
- the isothermal power production density (W/cm 2 ) at output voltage V(c) of 3.50 V is strongly dependent on temperature T, which is in a range from 7.24xlO n (W/cm 2 ) at 203 K (-70 °C) to 5.41x10 5 (W/cm 2 ) at 298K (25 °C), and to as much as 1090 (W/cm 2 ) at 673 K (400 °C).
- Fig. l7c presents the examples of the ideal isothermal electricity current density
- emitter with a low work function that is selected from the group consisting of 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1 and 1.2 eV and/or within a range bounded by any two of these values for isothermal electricity generation in a temperature range from 250 K to 673 K.
- Fig. l8a presents the examples of the ideal isothermal electricity current density
- WF(e) emitter work function
- emitter with a low work function that is selected from the group consisting of 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.8, 2.0, and 2.2 eV and/or within a range bounded by any two of these values for isothermal electricity generation in a temperature range from 250 to 1500 K.
- Fig. l8c presents the examples of the ideal isothermal electricity current density
- emitter with a low work function that is selected from the group consisting of 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, and 1.8 eV and/or within a range bounded by any two of these values for isothermal electricity generation with an output voltage V(c) of 4.00 V in a temperature range from 250 to 1500 K.
- Fig. 18d presents the examples of the ideal isothermal electricity current density
- emitter with a low work function that is selected from the group consisting of 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, and 0.9 eV and/or within a range bounded by any two of these values for isothermal electricity generation with an output voltage V(c) of 5.00 V in a temperature range from 250 to 900 K.
- WF(e) 0.50 eV
- WF(c) 4.60 eV, graphene and/or graphite
- WF(e) 0.50 eV
- WF(c) 4.60 eV, graphene and/or graphite
- WF(e) emitter work function
- an emitter with a lower work function to utilize environmental heat to generate isothermal electricity. Therefore, according to one of various embodiments, it is a preferred practice to employ an emitter with a low work function that is selected from the group consisting of 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.8, 2.2, 2.4, 2.6, 2.8, and 3.0 eV and/or within a range bounded by any two of these values for isothermal electricity generation in a temperature range from 200 to 2000 K.
- Fig. 20 presents an example of an integrated isothermal electricity generator system 1300 that comprises multiple pairs of emitters and collectors working in series. As illustrated in Fig. 20, the system 1300 comprises four parallel electric conductor plates 1301, 1302, 1321 and 1332 set apart with barrier spaces (such as vacuum spaces) 1304, 1324, and 1334 in between the conductor plates.
- barrier spaces such as vacuum spaces
- the first electric conductive plate 1301 has its right side surface coated with a thin layer of low work function (LWF) film 1303 serving as the first emitter;
- the second electric conductive plate 1302 has its left side surface coated with a thin layer of high work function (HWF) film 1309 serving as the first collector while its right side surface coated with a thin layer of low work function (LWF) film 1323 serving as the second emitter;
- the third electric conductive plate 1321 has its left side surface coated with a thin layer of high work function (HWF) film 1329 serving as the second collector while its right side surface coated with a thin layer of low work function (LWF) film 1333 serving as the third emitter;
- the fourth electric conductive plate 1332 has its left side surface coated with a thin layer of high work function (HWF) film 1339 serving as third (terminal) collector;
- the first barrier space 1304 allows the thermal electron flow 1305 to pass through ballistically between the first pair of emitter 1303 and collector 1309;
- a first capacitor 1361 connected in between the first and second electric conductor plates 1301 and 1302; a second capacitor 1362 linked in between the second and third conductor plates 1302 and 1321; a third capacitor 1363 used in between third and the fourth conductor plates 1321 and 1332 as illustrated in Fig. 20.
- the use of capacitors in this manner can typically provide better system stability and robust isothermal electricity delivery.
- isothermal electricity can be delivered through outlet terminals 1306 and 1376 or 1377 depending on the specific output power needs.
- the steady-state operating output voltage equals to V(c), which typically can be around 3 ⁇ 4 V depending on the system operating conditions including the load resistance and the difference in work function between the emitter and the collector.
- V(c) typically can be around 3 ⁇ 4 V depending on the system operating conditions including the load resistance and the difference in work function between the emitter and the collector.
- the steady-state operating output voltage is 3xVc, which typically can be about 9-12 V in this example.
- the isothermal electricity of the 1300 system can be delivered also through outlet terminalsl376 and 1377.
- the V(c) voltage at the second electric conductor plate 1302 generated by the activity of the first emitter (conductor 1301 with LWF film 1303) and first collector (HWF plate 1309) may serve as a bias voltage for the second emitter (LWF film 1323 on the right side surface of the second electric conductor plate 1302) so that the second emitter 1323 will more readily emit thermal electrons towards the second collector 1329 on the left side surface of the third conductor plate 1321 which has the third emitter 1333.
- the V(c) created at the second collector 1329 of the third conductor plate 1321 can serve as a bias voltage for the third emitter 1333 to more readily emit thermal electrons towards the terminal collector 1339 at the fourth conductor plate 1332 to facilitate the generation of isothermal electricity for delivery through the outlet terminalsl376 and 1377. Therefore, use of this special feature can help better extract environmental energy especially when the operating environmental temperature is relatively low or when the work function of certain emitters alone may not be entirely low enough to function effectively.
- the steady-state operating output voltage is 2xVc, which typically can be about 6-8 V in this case.
- Fig. 21 a presents an example of a prototype for an isothermal electricity generator system 1400A that has a pair of emitter (work function 0.7 eV) and collector (work function 4.36 eV) installed in a vacuum tube chamber. As illustrated in Fig.
- the system 1400A comprises a thin layer of low work function Ag-O-Cs film 1403 coated on the right side surface of electric conductor plate 1401 to serve as the emitter, a vacuum space 1404 allowing the thermal electron flow 1405 to pass through ballistically between the emitter and collector, a high work function Mo film/plate 1439 coated on the left side surface of the second electric conductor plate 1432 facing the emitter 1403 to serve as the collector, a vacuum tube wall 1450 that is in contact with the edges of the electric conductor plates 1401 and 1432 to allow environmental heat to transfer between the tube wall and the electric conductor plates 1401 (emitter) and 1432 (collector), a first electricity outlet 1406 connected with the first electric conductor plate 1401, an second electricity outlet 1477 connected with the second electric conductor plate 1432, a capacitor 1461 that is connected in between the two electricity outlets 1406 and 1477, and an Earth ground 1410 that is connected with the first electricity outlet 1406.
- the isothermal electricity generator system 1400A (Fig. 2la) is similar to the prototype of Fig. l6b, except that the effective heat-conduction contact of vacuum tube wall 1450 with the edges of the two electric conductor plates 1401 and 1432 in the system 1400A allow more efficient transfer of environmental heat from the tube wall to both the emitter and collector system than the prototype of Fig. l6b. Furthermore, the use of Earth ground 1410 and capacitor 1461 with the electricity outlets 1406 and 1477 as illustrated in Fig. 2la provides more stable and better system performance for isothermal electricity generation and delivery than the prototype of Fig. l6b as well.
- the work function of Mo film is about 4.36 eV and the work function of Ag-O-Cs film can be made to be anywhere between 0.5 and 1.2 eV.
- the work function of Ag-O-Cs film was selected to be 0.7 eV for use as the emitter while the work function of Mo film was 4.36 eV for use as the collector as illustrated in Fig. 21 a. Accordingly, when the isothermal electricity is delivered through the outlet terminalsl406 and 1477, the steady-state operating output voltage can typically be about 3.5 V in this case.
- Its saturation isothermal electricity current density (at output voltage of 3.5 V) is T55xlO 5 (A/cm 2 ) at the standard ambient temperature of 298 K (25 °C).
- the characteristic pattern of the ideal isothermal electricity current density (A/cm 2 ) as a function of operating temperature T at various output voltage V(c) for this system is also similar to that of the system with a pair of emitter work function (0.70 eV) and collector work function (4.56 eV, copper Cu(l 10)) presented in Fig. l7b.
- Fig. 2lb presents an example of a prototype for an isothermal electricity generator system 1400B that has two pairs of emitters (work function 0.7 eV) and collectors (work function 4.36 eV) installed in a vacuum tube chamber. As illustrated in Fig.
- the system 1400B comprises: the thin layer of low work function (0.7 eV) Ag-O-Cs film 1403 coated on the first electric conductor plate 1401 right side surface to serve as the first emitter; the first vacuum space 1404 allowing the thermal electron flow 1405 to pass through ballistically between the first pair of emitter and collector; the high work function (4.36 eV) Mo film/plate 1409 coated on the second electric conductor platel402 left side surface facing the first emitter to serve as the first collector; the thin layer of low work function Ag-O-Cs film 1423 coated on the second electric conductor plate 1402 right side surface to serve as the second emitter; the second vacuum space 1424 allowing the thermal electron flow 1425 to pass through ballistically between the second pair of emitter and collector; the high work function Mo film/plate 1439 coated on the third electric conductor plate 1432 left side surface facing the second emitter to serve as the terminal collector; the vacuum tube wall 1450 that is in contact with the edges of the three electric conductor plates 1401, 1402 and 14
- the isothermal electricity generator system 1400B (Fig. 2lb) is similar to the system 1400A (Fig. 2la), except that the middle electrode plate 1402 is coated with a Mo film 1409 on its left side surface and with Ag-O-Cs film at its right side surface to simultaneously serve as the first collector and the second emitter, respectively. Consequently, this system has two pairs of emitters and collectors working in series. According to Eq. 18, when a plurality (n) of the asymmetrically gated isothermal electricity generators are used in the series, the total steady- state output voltage (V s ⁇ total ⁇ ) is the summation of the output voltages from each of the asymmetrically gated isothermal electricity generators.
- the total steady-state output voltage (E st(totai) ) of the system 1400B is about 2 x 3.5 V in this example.
- the total saturation isothermal electricity current density (at output voltage of 7 V) is still about 1.55x10 5 (A/cm 2 ) at the standard ambient operating temperature of 298 K (25 °C).
- this system 1400B is designed to provide an option to deliver the isothermal electricity through the outlet terminals 1476 and 1477, leaving the V(c) voltage (about 3.5 V) generated by the first pair of emitter (Ag-O-Cs film 1403) and collector (Mo film/plate 1409) to serves as a bias voltage for the second emitter (Ag-O-Cs film 1423 on the second conductor plate 1402 right side surface) to more readily emit thermal electrons towards the terminal collector (Mo film/plate 1439) of the third conductor plate 1432.
- this option can help better extract environmental heat energy especially when the operating environmental temperature is relatively low or when the work function of certain emitters alone may not be low enough to function effectively.
- the steady-state operating output voltage is typically about 3.5 V in this example.
- Fig. 2lc presents an example of a prototype for an integrated isothermal electricity generator system 1400C that has three pairs of emitters (work function 0.7 eV) and collectors (work function 4.36 eV) installed in a vacuum tube. As illustrated in Fig.
- the system 1400 comprises: a thin layer of low work function (0.7 eV) Ag-O-Cs film 1403 coated on the first electric conductor plate 1401 right side surface to serve as the first emitter; a first vacuum space 1404 allowing the thermal electron flow 1405 to pass through ballistically between the first pair of emitter and collector; a (high work function 4.36 eV) Mo film/plate 1409 coated on the second electric conductor plate 1402 left side surface facing the first emitter to serve as the first collector; a thin layer of low work function (0.7 eV) Ag-O-Cs film 1423 coated on a second electric conductor plate 1402 right side surface to serve as the second emitter; a second vacuum space 1424 allowing the thermal electron flow 1425 to pass through ballistically between the second pair of emitter and collector; a (high work function 4.36 eV) Mo film/plate 1429 coated on a third electric conductor plate 1421 left side surface facing the second emitter to serve as the second collector; a thin layer of low work function (0.7
- a first electricity outlet 1406 connected with the first electric conductor plate 1401; a second electricity outlet 1476 connected with the second electric conductor plate 1402; a third electricity outlet 1477 connected with the fourth electric conductor plate 1432; a first capacitor 1461 that is connected in between the first and second electric conductor plates 1401 and 1402; a second capacitor 1462 that is connected in between the second and third electric conductor plates 1402 and 1421; a third capacitor 1463 that is connected in between the third electric conductor plate 1421 and the fourth electric conductor plate 1432; and an Earth ground 1410 that is connected with the first electric conductor plates 1401.
- the isothermal electricity in this example can be delivered through outlet terminals 1406 and 1476 or 1477 depending on the specific output power needs.
- the steady-state operating output voltage equals to V(c), which typically can be around 3.5 V depending on the system operating conditions including the load impedance and the difference in work function between the emitter and the collector.
- the saturation isothermal electricity current density is about 1.55x10 5 (A/cm 2 ) at the standard ambient temperature of 298 K (25 °C).
- the steady-state operating output voltage typically can be as high as about 10.5 V.
- the total saturation isothermal electricity current density (at output voltage of 10.5 V) remains to be about 1.55x10 5 (A/cm 2 ) at the standard ambient temperature of 298 K (25 °C) in this example.
- the activity of the first emitter (1401 with Ag-O-Cs film 1403) and the first collector (Mo film/plate 1409) can be used to generate a V(c) of about 3.5 V to serves as a bias voltage for the second emitter (Ag-O-Cs film 1423) on the surface of the second conductor plate 1402.
- the second emitter (Ag-O-Cs film 1423) will more readily emit thermal electrons towards the second collector (Mo film/plate 1429) of the third conductor plate 1421.
- the enhanced generation of V(c) at the third collector 1429 of the third conductor plate 1421 can serve as a bias voltage for the third emitter to more readily emit thermal electrons towards the terminal collector 1439 at the fourth conductor plate 1432. Therefore, use of this special feature can help better extract environmental heat energy especially when the operating environmental temperature is relatively low or when the work function of certain emitters alone may not be entirely low enough to function effectively.
- the steady-state operating output voltage can typically be about 7 V according to Eq. 18.
- the total saturation isothermal electricity current density (at output voltage of 7 V) remains to be about 1.55x10 5 (A/cm 2 ) at the standard ambient temperature of 298 K (25 °C) in this example.
- the system capacitance for a pair of parallel emitter and collector plates is inversely dependent on their separation distance ( d ). It is a preferred practice to increase the capacitance across each pair of emitter and collector by properly narrowing the space separation distance (d) between the emitter surface and the collector surface to a selected space gap size in a range from as big as 100 mm to as small as in a micrometer and/or sub-micrometer scale based on specific application and operation conditions. In this way, the need of using external capacitors may be eliminated.
- Fig. 22 presents an example of an integrated isothermal electricity generator system 1500 that has a narrow inter electrode space gap size (separation distance d) for each of the three pairs of emitters and collectors installed in a vacuum tube chamber set up vertically.
- the system 1500 (Fig.
- a vacuum tube chamber from its top to bottom: a LWF (low work function) film 1503 coated on the first electric conductor plate 1501 bottom surface to serve as the first emitter, a first narrow space 1504 allowing thermally emitted electrons 1505 to flow through ballistically between the first pair of emitter and collector, a HWF (high work function) film 1509 coated on the second electric conductor 1502 top surface to serve as the first collector, a LWF film 1523 coated on the second electric conductor 1502 bottom surface to serve as the second emitter, a second narrow space 1524 allowing thermally emitted electrons 1525 to flow through ballistically between the second pair of emitter and collector, a HWF (high work function) film 1529 coated on the third electric conductor 1521 top surface to sever as the second collector, a LWF film 1533 coated on the third electric conductor 1521 bottom surface to serve as the third emitter, a third narrow space 1534 allowing thermally emitted electrons 15
- the integrated isothermal electricity generator system 1500 (Fig. 22) is similar to the system 1400C (Fig. 2lc) except that only the first electric conductor platel50l and the terminal conductor plate 1532 are wired to provide electricity outlets 1506 and 1507. Therefore, in this example, each of the second and third electric conductor plates in between the first electric conductor platel50l and the terminal (fourth) conductor plate 1532 is designed to simultaneously serve as a collector on its top surface and an emitter at its bottom surface.
- the conductor plate 1502 has a collector (HWF film 1509) on the top surface facing up to receive thermally emitted electrons 1505 from the first emitter (LWF film 1503) located above the narrow space 1504 and an emitter (LWF film 1523) on the bottom side to emit thermal electrons 1525 downwards.
- the conductor plate 1521 has a HWF film 1529 on its top surface facing up to receive thermally emitted electrons 1525 from the second emitter (LWF film 1523) located above the narrow space 1524 and a LWF film 1533 on its bottom to emit thermal electrons 1535 downwards to the terminal collector (HWF 1539) on the terminal conductor 1532.
- the maximum total steady-state operating output voltage typically can be about 9-12 V in this example.
- an asymmetric function-gated thermal electron power generator system in an orientation with its emitter facing down and its collector is placed at the lower position facing up so that it can utilize gravity to better collect the thermally emitted electrons from the emitter placed at a higher position as illustrated in Fig. 22.
- the system can utilize the gravity to help pull the emitted electrons from an emitter above down to the collector below.
- the effect of the gravitational pull may be relatively small, it can help to ensure some of the emitted electrons with nearly zero kinetic energy to travel down to the collector. After any of the emitted electrons enter the collector, their contribution to the isothermal electricity is equally good in accordance with one of the various embodiment of the present invention.
- some of the emitted election may have quite limited kinetic energy that may not be sufficient to overcome the repulsion force of the collector electrode’s surface electrons to immediately enter the collection electrode.
- the use of gravitational pull provides two effects that benefit the collection of the electrons from the emission electrode. First, it can, in some extent, help accelerate the electrons from the emitter more quickly move down into the collector. The second effect is to help localize some of these emitted electrons at (and/or near) the interface between the collector surface and the vacuum space by the use of gravitational force in this manner.
- use of localized electron population density may enhance the utilization of environmental heat to benefit the thermal electron power generation.
- this special energy technology process for generating useful Gibbs free energy from utilization of electron thermal motion energy associated with localized electrons has a special feature that its local electron motive force (emf) generated from its special utilization of environmental heat energy may be calculated according to the following equation:
- R is the gas constant
- T is the absolute temperature
- F Faraday’s constant
- [ef ⁇ ⁇ is the concentration of localized electrons at the interface between the collector surface and the vacuum space
- [ef ] is the electron concentration in the bulk vacuum space.
- this local emf is a logarithmic function of the ratio of localized electron concentration [ef ⁇ ⁇ at the interface to the delocalized electron concentration [e B ] in the bulk vacuum space.
- this local emf may facilitate the entry of thermal elections gap space - collector surface interface into the collector in accordance with one of the various embodiments.
- the use of positive-charged molecular functional group-modified collector surface and/or the use of gravitational force may bring the emitted electrons to the gap space-collector surface interface forming local emf there that may help overcome the collector surface-dipole barrier to facilitate the entry of thermal electrons into the collector for enhanced isothermal electricity production.
- the effect of the isothermal electricity production is additive.
- the number of emitter-collector pairs that may be used per integrated system as shown in Fig. 22 for the purpose of isothermally extracting environmental heat energy to generate electricity may be selected from the group consisting of 1, 2, 3, 4, 5, 6, 7, 8, 8, 9, 10,
- Figure 23 presents another example of an integrated isothermal electricity generator system 1600 that has three pairs of emitters and collectors installed in a vacuum tube chamber set up vertically to utilize the gravity to help pull the emitted electrons from an emitter down to a collector.
- the system 1600 (Fig.
- a vacuum tube container comprises the following components installed in a vacuum tube container from its top to bottom: a LWF (low work function) film 1603 coated onto the vacuum tube wall 1650 inner surface at the dome-shaped top end to serve as a first emitter that has an electricity outlet 1606 (+) wired with a capacitor 1611 that is connected with an Earth ground 1610, a first vacuum space 1604 allowing thermally emitted electrons 1605 to flow through ballistically, a HWF (high work function) film 1609 to serve as a first collector on the top surface of electric conductor 1602, a LWF film 1623 as the second emitter at the bottom surface of electric conductor 1602, a second vacuum space 1624 allowing thermally emitted electrons 1625 to flow through ballistically, a HWF (high work function) film 1629 as the second collector on electric conductor 1621 top surface, a LWF film 1633 as the third emitter at electric conductor 1621 bottom surface, a third vacuum space 1634 allowing thermally emitted electrons
- the integrated isothermal electricity generator system 1600 (Fig. 23) is similar to the system 1500 (Fig. 22) except the following special features: 1) The system 1600 employs the inner surface of dome-shaped top end of the vacuum tube chamber as a physical support to construct the first emitter by coating an LWF (low work function) film 1603; 2) It utilizes the inner surface of the inversed-dome-shaped bottom end of the vacuum tube chamber to construct the terminal collector by coating a HWF (high work function) film 1639; and 3) the first emitter has an electricity outlet 1606 (+) wired with a capacitor 1611 that is connected with an Earth ground 1610 while the terminal collector connected with an electricity outlet 1637 (-).
- the optional use of capacitor 1611 between the electricity outlet 1606 (+) and the Earth ground 1610 also provides an additional way to reduce and/or modulate the possible voltage at the emitter for better system performance.
- an effective emitter such as those in the systems 1300, 1400, 1500 and 1600 absorbs environmental heat from the outside environment and utilizes the environmental heat energy to emit electrons as shown in Figs. 20-22. It is important to provide effective heat conduction from the environment to the emitters.
- the system 1500 (Fig. 22) provide an example where the environmental heat energy primarily flow through the tube wall-electric conductor plate joints to the emitters on the electric conductor plate surfaces. Therefore, it is a preferred practice to employ heat-conductive materials in making the tube wall and more importantly the tube wall- electric conductor plate joints to ensure effective conduction of latent heat from the environment to the emitters.
- the integrated isothermal electricity generator system 1600 (Fig. 23) provide an example of an emitter constructed on the inner surface of dome-shaped top end of the vacuum tube chamber by coating an LWF (low work function) film 1603.
- LWF low work function
- the collector surface is engineered by adding certain positively charged molecular structure such as protonated amine groups on the surface.
- Protonated (poly)aniline which has protonated amine groups (positive charges) on its surface made by the protonation process using the electrostatically localized excess protons as disclosed in W02017/007762 Al and US 2017/0009357 Al is selected for use as a collector electrode in this embodiment.
- the positively charged groups such as the protonated amine groups on the collector electrode surface provide a number of beneficial effects on facilitating the collection of electrons emitted from the emitter electrode: 1) Attracting the electrons emitted from the emitter electrode, which results in an enhanced concentration of localized electron cloud [e ] at the vicinity of the collector electrode surface and thus enable better utilization of additional environmental heat energy according to Eq. 22 to facilitate the entry of the vacuum electrons into the collector electrode for power generation; 2) Neutralizing negative surface dipole (if any) for the collector electrode surface; and 3) Counter balancing the negative electric surface potential resulted from the accumulation of the collected electrons in the collector electrode for more power storage.
- Figure 24a presents an example of an isothermal electricity generator system 1700A that has a low work function Ag-O-Cs (0.6 eV) emitter and a high work function protonated polyaniline (4.42 eV) collector installed in a chamber-like vacuum tube with a dome-shaped top end and an inversed-dome-shaped bottom end.
- the system 1700A (Fig.
- 24a comprises the following components installed in the chamber-like vacuum tube from its top to bottom: a Ag- O-Cs film (emitter) 1703 coated on the dome-shaped top inner surface of the chamber-like vacuum tube wall 1750 to serve as an emitter; a protonated polyaniline film 1739 coated on the inversed-dome-shaped bottom inner surface of the chamber-like vacuum tube to serve as the collector; a vacuum space 1704 allowing thermally emitted electrons 1705 to ballistically fly through between the emitter 1703 and the collector 1739; an electricity outlet 1706 (+) connected with the emitter 1703; and an electricity outlet 1737 (-) connected with the collector 1739.
- a protonated polyaniline film 1739 coated on the inversed-dome-shaped bottom inner surface of the chamber-like vacuum tube to serve as the collector a vacuum space 1704
- the steady-state operating output voltage typically can be about 3.5 V.
- the saturation isothermal electricity current density (at output voltage of 3.5 V) is 7.59x 10 4 A/cm 2 at the standard ambient temperature of 298 K (25 °C) in this example.
- Figure 24b presents an example of an integrated isothermal electricity generator system 1700B that has two pair of emitters and collectors working in series employing low work function of Ag-O-Cs (0.6 eV) and high work function of protonated polyaniline (4.42 eV).
- the system 1700B (Fig.
- the steady-state operating output voltage typically can be about 7 V according to Eq. 18.
- the saturation isothermal electricity current density is about 7.59x 10 4 A/cm 2 at the standard ambient temperature of 298K (25 °C) in this example.
- Figure 24c presents an example of an integrated isothermal electricity generator system 1700C that has three pairs of low work function of Ag-O-Cs (0.6 eV) emitters and high work function protonated polyaniline (4.42 eV) collectors operating in series.
- the system 1700C (Fig.
- 25c comprises the following components installed in a vacuum tube chamber from its top to bottom: a Ag-O-Cs film (emitter) 1703 coated onto the dome-shaped top end inner surface of the vacuum tube wall 1750 to serve as the first emitter; a protonated polyaniline film 1709 (collector) coated on the first middle electric conductor 1702 top surface to serve as the first collector; the first vacuum space 1704 allowing thermally emitted electrons 1705 to fly through ballistically across the first emitter and the first collector; a Ag-O-Cs film 1723 at the first middle electric conductor 1702 bottom surface to serve as the second emitter; a protonated polyaniline film 1729 coated on the second middle electric conductor 1721 top surface to serve as the second collector; the second vacuum space 1724 allowing thermally emitted electrons 1725 to fly through ballistically between the second emitter and the second collector; a Ag-O-Cs film 1733 coated on the second middle electric conductor 1721 bottom surface to serve as the third emitter, a proto
- the maximum total steady-state operating output voltage typically can be about 10.5 V according to Eq. 18.
- the saturation isothermal electricity current density (at output voltage of 10.5 V) is about 7.59 ⁇ 10 4 A/cm 2 at the standard ambient temperature of 298 K (25 °C) in this example.
- an isothermal electrons-based environmental heat energy utilization system comprises low work function of Ag-O-Cs and high work function of Cu metal.
- Figure 25a presents another example of an isothermal electricity generator system 1800A that has a low work function (0.7 eV) Ag-O-Cs emitter and a high work function (4.56 eV) Cu metal collector installed in a chamber-like vacuum tube.
- the system 1800A (Fig.
- 25a comprises the following components installed in the chamber-like vacuum tube from its top to bottom: a Ag-O-Cs film (emitter) 1803 coated on the dome-shaped top end inner surface of the chamber-like vacuum tube wall 1850 to serve as the emitter; a vacuum space 1804 allowing thermally emitted electrons 1805 to flow through ballistically between the emitter 1803 and collector 1839; a Cu film/plate 1839 coated on the inversed-dome-shaped bottom end inner surface of the chamber-like vacuum tube to serve as the collector 1839; the first electricity outlet 1806 (+) connected with the emitter 1803; and the second electricity outlet 1837 (-) connected with the collector 1839.
- a vacuum space 1804 allowing thermally emitted electrons 1805 to flow through ballistically between the emitter 1803 and collector 1839
- the maximum total steady- state operating output voltage typically can be about 3.5 V.
- the saturation isothermal electricity current density (at output voltage of 3.5 V) is about T55xlO 5 (A/cm 2 ) at the standard ambient temperature of 298 K (25 °C) in this example.
- Figure 25b presents another example of an integrated isothermal electricity generator system 1800B that has two pairs of low work function Ag-O-Cs (0.7 eV) emitters and high work function Cu metal (4.56 eV) collectors operating in series.
- the system 1800B (Fig.
- 25b) comprises the following components installed in a vacuum tube chamber from its top to bottom: an Ag-O-Cs film (emitter) 1803 coated on the dome-shaped top end inner surface of the vacuum tube chamber wall 1850 to serve as the first emitter; a first vacuum space 1804 allowing thermally emitted electrons 1805 to flow through ballistically across the first pair of emitter and collector; a Cu film/plate 1809 coated on the middle electric conductor 1802 top surface to serve as the first collector; an Ag-O-Cs film 1823 coated on the middle electric conductor 1802 bottom surface to serve as the second emitter; a second vacuum space 1834 allowing thermally emitted electrons 1835 to flow through ballistically across the second pair of emitter 1823 and collector 1839; a Cu film/plate 1839 coated on the inversed-dome-shaped bottom end inner surface of the vacuum tube chamber to serve as the terminal collector; a first electricity outlet 1806 (+) connected with the first emitter 1803; and a second electricity outlet 1837 (-) connected with
- the maximum total steady-state operating output voltage of the system 1800B typically can be about 7 V.
- the total saturation isothermal electricity current density (at output voltage of 7 V) is about 1.55x10 5 (A/cm 2 ) at the standard ambient temperature of 298 K (25 °C) in this example.
- Figure 25c presents another example of an integrated isothermal electricity generator system 1800C that has three pairs of emitters and collectors operating in series employing low work function of Ag-O-Cs (0.7 eV) and high work function of Cu metal (4.56 eV).
- the system 1800C (Fig.
- 25c comprises the following components installed in a vacuum tube from its top to bottom: an Ag-O-Cs film (emitter) 1803 coated onto the inner surface of dome-shaped top end of the vacuum tube wall 1850 to serve as the first emitter that has an electricity outlet 1806 (+), a first vacuum space 1804 allowing thermally emitted electrons 1805 to flow through ballistically, a Cu film/plate 1809 to serve as the first collector on the top surface of electric conductor 1802, an Ag-O-Cs film 1823 as the second emitter at the bottom surface of electric conductor 1802, a second vacuum space 1824 allowing thermally emitted electrons 1825 to flow through ballistically, a Cu film/plate 1829 as the second collector on electric conductor 1821 top surface, an Ag-O-Cs film 1833 as the third emitter at electric conductor 1821 bottom surface, a third vacuum space 1834 allowing thermally emitted electrons 1835 to flow through ballistically, and a Cu film/plate 1839 coated on the inner surface of the inverse
- the maximum total steady-state operating output voltage typically is about 10.5 V.
- the total saturation isothermal electricity current density (at output voltage of 10.5 V) is about T55xlO 5 (A/cm 2 ) at the standard ambient temperature of 298 K (25 °C) in this example.
- an isothermal electrons-based environmental heat energy utilization system comprises low work function of Ag-O-Cs and high work function of Au metal.
- Figure 26 presents another example of an integrated isothermal electricity generator system 1900 that employs three pairs of exceptionally low work function Ag-O-Cs (0.5 eV) emitters and high work function Au metal (5.10 eV) collectors working in series.
- the system 1900 (Fig.
- the maximum total steady-state operating output voltage typically can be about 12 V.
- the total saturation isothermal electricity current density (at output voltage of 12 V) is about 3.73 x 10 2 A/cm 2 at the standard ambient temperature of 298K (25 °C) in this example.
- an isothermal electrons-based environmental heat energy utilization system comprises low work function of doped-graphene and high work function of graphite.
- Figure 27 presents another example of an integrated isothermal electricity generator system 2000 that employs low work function of doped-graphene (l.OleV) and high work function of graphite (4.60 eV). The system 2000 (Fig.
- the maximum total steady-state operating output voltage typically can be about 9 V.
- the total ideal saturation isothermal electricity current density (at output voltage of 9 V) at the following operating temperature is: 1.30x 10 10 A/cm 2 at 298 K (25 °C), 5.
- an isothermal electrons-based environmental heat energy utilization system comprises low work function of doped-graphene and high work function of graphene.
- Figure 28 presents another example of an integrated isothermal electricity generator system 2100 that employs multiple pairs of low work function doped-graphene (l.OleV) emitters and high work function graphene (4.60 eV) collectors.
- the system 2100 (Fig.
- the maximum total steady- state operating output voltage typically can be about 9 V in this example.
- the total ideal saturation isothermal electricity current density (at output voltage of 9 V) at the following operating temperature is: 1.30x 10 10 A/cm 2 at 298 K (25 °C), 5.14x10 7 A/cm 2 at 373 K (100 °C), 5.94x10 4 A/cm 2 at 473 K (200 °C), 6.3lxl(T 2 A/cm 2 at 573 K (300 °C), 1.76 A/cm 2 at 673 K (400 °C), 1.76 A/cm 2 at 673 K (400 °C), 17.3 A/cm 2 at 763 K (490 °C), 61.1 A/cm 2 at 823 K (500 °C), 154 A/cm 2 at 873 K (600 °C), 354 A/cm 2 at 923 K (650 °C
- any of the isothermal electricity generator systems disclosed here may be modified for various applications.
- a typical smart mobile phone device such as iPhone 6 consumes about 10.5 Watt-hours per day (24 hours).
- Use of certain isothermal electricity generator systems disclosed in this invention may enable to produce a new generation of smart mobile electronic devices that can utilize the latent (existing hidden) heat energy from the ambient temperature environment to power the devices without requiring the conventional electrical power sources.
- use of an asymmetric function-gated isothermal electricity generator system disclosed here with a chip size of about 40 cm 2 that has a 3 V isothermal electricity output of 200 mA may be sufficient to continuously power a smart mobile phone device.
- the collector work function material for this application does not have to be gold (Au) and other work function materials such as Cu metal film, graphene and/or graphite conductors with work function about 4.6 eV can also be used. [0169] As presented in Fig.
- the isothermal electricity current density (A/cm 2 ) curves as a function of output voltage V(c) for a pair of emitter work function of 0.50 eV and collector work function of 4.60 eV showed that this type of isothermal electricity generator system can work even at a refrigerating and/or freezing temperature of 253, 263, 273, and 277 K.
- the saturation level of the steady-state ideal isothermal electricity current density at an output voltage of 3.50 V is: 8.42x10 4 A/cm 2 at 253 K (-20 °C), 2.
- the cooling power of the isothermal electricity generator defined as Watt (W) per square centimeters of the cross-section area of the emitter-collector interelectrode space in this example is estimated to be: 2.88 ⁇ 10 W/cm 2 at 253 K (-20 °C), 7.63xl0 3 W/cm 2 at 263 K (-10 °C), l.84xl0 2 W/cm 2 at 273 K (0 °C), and 2.58 ⁇ 10 2 W/cm 2 at 277 K (4 °C).
- a typical family-size freezer/refrigerator has a height of 174 cm, a depth of 80 cm and a width of 91 cm. It has a total outside surface area of 74,068 cm 2 . Even if only 50% of the surface area is used by an asymmetric function-gated isothermal electricity generator with a cooling power density of 2.88 ⁇ 10 W/cm 2 at 253 K (-20 °C), it maximally can deliver an electricity power of 106 W plus a novel cooling power of 106 W, which is plenty to power the entire family-size freezer/refrigerator that typically requires an electricity power of only 72.5 W to run in this example.
- an asymmetric function-gated optimized isothermal electricity generator system that has a pair of an exceptionally low work function Ag- O-Cs (0.5 eV) emitter and a high work function graphene (4.60 eV) collector is employed to provide the novel cooling for a new type of freezer/refrigerator without requiring any of the conventional refrigeration mechanisms of compressor, condenser, evaporator and/or radiator by isothermally extracting environmental heat energy from inside the freezer/refrigerator while generating isothermal electricity.
- waste heat generator systems can produce electricity by utilizing the waste heat from wide varieties of waste heat sources including (but not limited to) the waste heat from electrical devices such as computers, motor vehicles engines, air-conditioner heat exchange systems, combustion-based power plants, combustion systems, heat-based distillation systems, nuclear power plants, geothermal heat sources, solar heat, and waste heat from photovoltaic panels.
- electrical devices such as computers, motor vehicles engines, air-conditioner heat exchange systems, combustion-based power plants, combustion systems, heat-based distillation systems, nuclear power plants, geothermal heat sources, solar heat, and waste heat from photovoltaic panels.
- Figures 29-31 presents additional prototypes for an isothermal electricity generator system that comprises a pair of a low work function Ag-O-Cs emitter plate (size: 40 mm x 46 mm) and a high work function Cu collector plate (size: 40 mm x 46 mm) installed in a sealed glass bohle (Zhongquo Mingbei, Nuoyan Koubei, made in China) with a screw cap (Fig. 3 la) or with a non-screw cap (Fig. 3 lb).
- the air inside each bottle can be readily removed though a vacuum pump to create a vacuum condition.
- Fig. 29a presents photographs for a pair of parallel aluminum plate-supported silver (Ag) and copper (Cu) electrode plates (size: 40 mm x 46 mm) held together with electric- insulating plastic spacers (washers), screws and nuts at the four comers for each of the two electrode plates to make a pair of Ag-O-Cs type emitter (CsOAg) and Cu collector with or without oxygen plasma treatment.
- Fig. 29b presents photographs for a pair of parallel aluminum plate-supported silver (Ag) and copper (Cu) collector electrode plates (size: 40 mm x 46 mm) held together with electric-insulating plastic spacers (washers), heat-shrink plastic tube-insulated metal screws and nuts at the comers of the electrode plates.
- the silver (Ag) plate and copper (Cu) collector plate were connected by soldering with a red insulator coated copper wire and a blue insulator coated copper wire, respectively.
- the silver (Ag) electrode plate surface was coated with a thin molecular layer of cesium oxide (Cs 2 0) through painting with a dilute cesium oxide solution followed by drying to form a type of Ag-O-Cs emitter with or without oxygen plasma treatment. This shows how a pair of prototype Ag-O-Cs emitter (CsOAg) and Cu collector can be assembled.
- Fig. 30 presents a photograph of the parts for a prototype CsOAg-Cu electrobottle that comprise a pair of parallel aluminum plate-supported CsOAg (silver (Ag), coated with Cs 2 0) and copper (Cu) collector plates installed with the red and blue insulator coated copper wires passing through a screw bottle cap. Two blue plastic air tubes were installed through two additional holes in the screw bottle cap. Electric-insulating and air-tight Kafuter 704 RTV silicone gel (white) was used to seal the joints for the wires and tubes passing through the bottle cap. This shows how a prototype CsOAg-Cu electrobottle can be assembled.
- Fig. 3 la presents a photograph showing four prototype CsOAg-Cu electrobottles that were fabricated using crew bottle caps.
- Each electrobottle comprises a pair of parallel aluminum plate-supported silver CsOAg (a type of Ag-O-Cs emitter) and copper (Cu) collector electrode surfaces installed with red and blue insulator coated wires passing through a screw bottle cap.
- 3 lb presents a photograph of 17 prototype CsOAg-Cu electro-bottles that were made using non-screw bottle caps and sealed with electric-insulating and air-tight Kafuter 704 RTV silicone gel (white) material. [0176] The following methods and steps were employed in fabricating these CsOAg-Cu prototype electrobottles (Figs.
- each pair of a low work function Ag-O-Cs emitter plate (size: 40 mm x 46 mm) and a high work function Cu collector plate (size: 40 mm x 46 mm) was assembled in parallel with a separation distance of 5 mm using a set of four heat-shrinking plastic insulator tube-insulated metal screws, four insulating plastic washers/spacers, and four nuts (or using a set of electric- insulating plastic spacers (washers), screws and nuts as shown in Fig. 29a) at the four comers of the two electrode plates; j) as shown in Fig.
- a pair of 3-mm-diameter holes was made in each of the bottle caps (typically made of stainless steel and/or plastic material) for the red and blue wires to pass through; k) a pair of 8-mm-diameter holes was made in the bottle cap for a pair of blue plastic (or stainless steel) tubes to pass through (to pull vacuum later); 1) the assembled pair of Ag-O-Cs emitter plate and Cu collector plate was then inserted into a glass bottle with its insulated red and blue wires passing through the 3-mm-diameter holes of the bottle cap (Fig.
- the Keithley 6514 electrometer’s red alligator clip was connected with the wire (red) of the Ag-O- Cs emitter plate while the electrometer’s black alligator clip was connected to the wire (black) of the Cu collector plate.
- the metal Faraday box that was typically grounded by connecting with the Keithley 6514 electrometer’s green alligator clip (ground wire) was closed at all sides as shown in Fig. 32b to shield the prototype electrobohle device to minimize any potential electric interference from the sounding environment during the measurements for isothermal electricity generation activity.
- the isothermal electricity generation was measured by a Keithley 6514 electrometer reading“20.9444 PA.CZ”. This indicates that the isothermal electric current from the prototype electrobottle device (Fig. 32a) was approximately 20.94 pico Amps (pA) as measured at a room temperature (2l°C) using the well-established Amps measurement procedure with Keithley 6514 electrometer’s zero check and zero (baseline) correction (CZ) functions.
- a number of prototype CsOAg-Cu electrobottles were experimentally tested for their isothermal electricity production performance.
- Table 10 presents examples of experimental isothermal electricity production results from a prototype isothermal electricity generator (electrobottle sample“CsOAg-Cu 1”) in comparison with a control electrobottle sample“CK Ag-Cu” as tested at 23 °C with Keithley 6514 system electrometer.
- the control electrobottle “CK Ag-Cu” has the same structure as that of the electrobottle“CsOAg-Cu 1” except that the Ag plate surface of the control electrobottle“CK Ag-Cu” was not coated with any cesium oxide (Cs 2 0).
- the isothermal electric current from electrobottle“CsOAg-Cu 1” was measured to be 11.17 ⁇ 0.08 pico amps (pA), which is well above the electrometer baseline signal of 0.071 ⁇ 0.17 pA as measured with Keithley 6514 system’s Model 237-ALG-2 low noise cable with three alligator clips (no electrobottle device).
- the control electrobottle“CK Ag-Cu” gave an electric current reading of -0.360 ⁇ 0.005 pA, which is quite different from that (11.17 ⁇ 0.08 pA) of electrobottle “CsOAg-Cu 1”. Therefore, these experimental results quite clearly demonstrated the isothermal electricity production in the prototype electrobottle“CsOAg-Cu 1”.
- the electricity current density across the CsOAg plate surface area in electrobottle“CsOAg-Cu 1” was determined to be 0.607 pA/cm 2 in its normal polarity and -0.586 pA/cm 2 when measured with its reverse polarity.
- the averaged electricity current density in electrobottle“CsOAg-Cu 1” was calculated to be 0.596 pA/cm 2 .
- the work function of the CsOAg emitter plate surface in electrobottle“CsOAg-Cu 1” was estimated to be about 1.1 eV in this example.
- Table 10 presents the experimental isothermal electricity production results from a prototype isothermal electricity generator (electrobottle“CsOAg-Cu 1”) in comparison with a control electrobottle“CK Ag-Cu” as tested at 23 °C with Keithley 6514 electrometer’s zero check and zero (baseline) correction (CZ) functions.
- Table 11 presents the experimental isothermal electricity production results from another prototype isothermal electricity generator (electrobottle“(3) CsOAg-Cu”) measured as a function of operating temperature.
- electrobotttle“(3) CsOAg-Cu” The standard methods of Amps and voltage measurements with Keithley 6514 electrometer’s zero check and zero (baseline) correction (CZ) were used in testing this prototype“(3) CsOAg-Cu” electrobottle.
- CZ zero check and zero (baseline) correction
- the isothermal electric current from electrobottle “(3) CsOAg-Cu” at 20.5 °C, 23 °C and 25 °C was measured to be 2.12 ⁇ 0.03 pA, 5.81 ⁇ 0.03 pA and 7.35 ⁇ 0.02 pA, respectively.
- This experimental result demonstrated that isothermal electricity production can indeed increase dramatically with the rising of environmental temperature as expected.
- Table 11 presents the experimental isothermal electricity production results from a prototype isothermal electricity generator (electrobottle“(3) CsOAg-Cu”) measured as a function of operating temperature at 20.5 °C, 23 °C and 25 °C with Keithley 6514 electrometer’s zero check and zero (baseline) correction (CZ) functions.
- the isothermal electric voltage output from electrobottle“(3) CsOAg-Cu” at 25 °C was measured to be 54.2 ⁇ 0.8 mV (Table 11). Based on the isothermal electric voltage (54.2 ⁇ 0.8 mV) and isothermal electric current (7.35 ⁇ 0.02 pA) as measured at 25 °C, the isothermal electricity power output was calculated to be 3.98 x l () 1 Watts for the electrobottle“(3) CsOAg-Cu” prototype device in this example.
- Fig. 33a presents a photograph of another prototype electrobottle placed inside a Faraday box and tested in normal polarity (Keithley 6514 system electrometer’s low noise cable/red alligator connector to CsOAg Ag plate (a type of Ag-O-Cs emitter) and black alligator connector to Cu collector plate), showing an electric current reading of“11.888 pA.CZ”. This shows that the isothermal electric current from this prototype electrobottle was approximately 11.89 pA as measured at room temperature (21 °C) with Keithley 6514 electrometer’s zero check and zero (baseline) correction (CZ).
- Fig. 34a presents a photograph of another CsOAg-Cu electrobottle placed inside a Faraday box and tested in normal polarity (Keithley 6514 red alligator connector to CsOAg emitter plate and black alligator connector to Cu collector plate), showing an electric voltage reading of“0.10051 V.CZ”. This shows that the isothermal electric voltage from this sample electrobottle was approximately 100.5 mV as measured at room temperature (2l°C) with Keithley 6514 electrometer’s zero check and zero (baseline) correction (CZ).
- Figure 35 presents a photograph of two prototype electrobottles connected in parallel with their normal polarity (Keithley 6514 system’s red alligator connector to CsOAg emitters and black alligator connector to Cu collectors) inside a Faraday box, showing an electric current reading of“22.230 pA.CZ”.
- the two prototype electrobottles have an individually measured isothermal electric current of about 11 pA each.
- the total electrical current I sa t(totai)
- the predicted isothermal electric current for the two prototype electrobottles used in parallel should be 22 pA, which excellently matched with the measured electric current reading of“22.230 pA.CZ”. This is an important result since it demonstrated that the isothermal electric current generation effects of the electrobottles used in parallel are indeed additive in nature as expected in accordance with one of the various embodiments in the present invention.
- Figure 36 presents a photograph of three prototype electrobottles connected in parallel in normal polarity (Keithley 6514 red alligator connector to CsOAg emitters and black alligator connector to Cu collectors) inside a Faraday box, showing an electric current reading of“26.166 pA.CZ”.
- the first two prototype electrobottles have an individually measured isothermal electric current of about 11 pA each and the third electrobottle has an measured isothermal electric current of about 4 pA. Therefore, the predicted total isothermal electric current for the three prototype electrobottles connected in parallel should be 26 pA, which matched well with the measured electric current reading of “26.166 pA.CZ”. This is an important result since it again demonstrated that the isothermal electricity generation effects of the prototype electrobottles connected in parallel are indeed additive in accordance with one of the various embodiments in the present invention.
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CN201980006695.5A CN111615738A (en) | 2018-01-05 | 2019-01-01 | Isothermal electron energy-renewing power generation by utilizing environmental heat energy |
US16/960,082 US20210067064A1 (en) | 2016-07-05 | 2019-01-01 | Isothermal electricity for energy renewal |
AU2018399640A AU2018399640A1 (en) | 2018-01-05 | 2019-01-01 | Isothermal electricity for energy renewal |
CA3087560A CA3087560A1 (en) | 2018-01-05 | 2019-01-01 | Isothermal electricity for energy renewal |
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US16/237,681 US20200208276A1 (en) | 2019-01-01 | 2019-01-01 | Localized excess protons and isothermal electricity for energy renewal |
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WO2001069657A2 (en) * | 2000-03-06 | 2001-09-20 | Eneco, Inc. | Thermal diode for energy conversion |
US20090173082A1 (en) * | 2007-12-14 | 2009-07-09 | Matthew Rubin | Novel solid state thermovoltaic device for isothermal power generation and cooling |
US20170062195A1 (en) * | 2014-05-11 | 2017-03-02 | Philip Julian Hardcastle | A thermionic energy conversion device |
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WO2001069657A2 (en) * | 2000-03-06 | 2001-09-20 | Eneco, Inc. | Thermal diode for energy conversion |
US20090173082A1 (en) * | 2007-12-14 | 2009-07-09 | Matthew Rubin | Novel solid state thermovoltaic device for isothermal power generation and cooling |
US20170062195A1 (en) * | 2014-05-11 | 2017-03-02 | Philip Julian Hardcastle | A thermionic energy conversion device |
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