Poisson's Equation as a Condition of Equilibrium in Electrochemical Systems

Christopher, H. A.; Shipman, C.W.

doi:10.1149/1.2411292

Cited by 11 publications

(11 citation statements)

References 5 publications

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“…The performance of the cell can be explained by a series of steps. First, when the PS2 output voltage V PS2 =E ex I=0 (null point) because of the usual condition of uniformity of the electrochemical potential throughout the electrolyte solution [9]. Second, if V PS2 is increased from the null point, then a charge current I=I c flows due to the total source voltage (emf) of ΔE=V PS2 -E ex .…”

Section: Electrostatic-induction Potential-superposed Charge Of Lithimentioning

confidence: 99%

Theories on the On-board Lithium-Ion Battery Electric Power Generator for Infinite Cruising Range Electric Vehicles

Ono¹

2017

J Electr Electron Syst

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Section: Electrostatic-induction Potential-superposed Charge Of Lithimentioning

confidence: 99%

Theories on the On-board Lithium-Ion Battery Electric Power Generator for Infinite Cruising Range Electric Vehicles

Ono¹

2017

J Electr Electron Syst

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“…When a cell is open and no current flows, electrochemical potential of ions (ũ, unit in Jmol −1 ) is even throughout in the electrolyte [7]. When a cell is open and no current flows, electrochemical potential of ions (ũ, unit in Jmol −1 ) is even throughout in the electrolyte [7].…”

Section: Electrostatic Energy Conversion In Power Generation Systemmentioning

confidence: 99%

Theoretical Concept of Hydrogen Redox Electric Power Generation

Ono

2016

Electrical Engineering Japan

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This paper demonstrates the electric power generator with both zero energy input and zero matter input and emission without violating the laws of thermodynamics. The hydrogen redox power generation system is a combined energy cycle consisting of the H 2 O reduction by the electrostatic induction hydrogen electrolytic cell for the synthesis of pure stoichiometric H 2 -O 2 fuel and the H 2 oxidation to H 2 O by the fuel cell. The electrostatic induction potential superposed hydrogen electrolytic cell works on the mechanism in which, on the theoretical base, power used is 17% of the total electrical energy required, while the remaining 83% can be provided by the electrostatic energy free of power. Part of the power delivered by the fuel cell is returned to the electrolytic cell, and the remainder represents the net power output. For high-power applications, the cycle power efficiency defined as the ratio of net power output outside the generator to power delivered by the H 2 -O 2 fuel cell is of primary interest. According to calculations using the operational data of alkaline water electrolysis in industries, the cycle power efficiencies exceed 70%.

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“…The electric field is used in the laws of thermodynamics as an independent intensive factor similar to temperature or pressure [9][10][11][12]. Thus, we wish to show that the electrostatic energy of the electric field can be quasi-statically converted into the chemical energy of the ionic medium (thermodynamic energy), and to derive an equation for such conversion.…”

Section: Internally Self-sustaining Electrostatic Energymentioning

confidence: 99%

Energetically Self‐Sustaining Electric Power Generation System Based on the Combined Cycle of Electrostatic Induction Hydrogen Electrolyzer and Fuel Cell

Ono

2015

Electrical Engineering Japan

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SUMMARY Toward achieving a breakthrough in self‐sustaining electric power generation systems consisting of a hydrogen energy cycle, we demonstrate an electrostatic induction potential superposed hydrogen electrolyzer to produce stoichiometric H0true2‐O0true2 fuel for fuel cells. This electrolytic system operates by a mechanism in which the total power requirement is given by the product of the electrolytic current and the additional voltage over the decomposition voltage. In order to achieve the highest energy efficiency for the fuel cell and full sustainability for the fuel, a combined cycle of an H0true2‐O0true2 fuel cell and this type of electrolyzer is introduced. Part of the power delivered by the fuel cell is returned to the electrolyzer, and the remainder represents the net power output. According to theoretical calculations, the net power output exceeds 70% of that delivered by the H0true2‐O0true2 fuel cell, without violating the laws of thermodynamics.

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Poisson's Equation as a Condition of Equilibrium in Electrochemical Systems

Cited by 11 publications

References 5 publications

Theories on the On-board Lithium-Ion Battery Electric Power Generator for Infinite Cruising Range Electric Vehicles

Theories on the On-board Lithium-Ion Battery Electric Power Generator for Infinite Cruising Range Electric Vehicles

Theoretical Concept of Hydrogen Redox Electric Power Generation

Energetically Self‐Sustaining Electric Power Generation System Based on the Combined Cycle of Electrostatic Induction Hydrogen Electrolyzer and Fuel Cell

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