Thermoelectrochemical Heat Converter

1 . A device for direct thermoelectrochemical heat-to-electricity conversion, the device comprising: a first electrochemical cell comprising a first gas-impermeable, electron-blocking membrane capable of transporting an ion I at a first temperature, and a first pair of electrodes on opposite sides of the first membrane, a second electrochemical cell comprising a second gas-impermeable, electron-blocking membrane capable of transporting the ion I at a second temperature lower than the first temperature, and a second pair of electrodes on opposite sides of the second membrane, a closed-circuit chamber A comprising a working fluid A, a pump A, and a counter-flow heat exchanger A, wherein the closed-circuit chamber A is connected to the first electrochemical cell on a side A of the first membrane and to the second electrochemical cell on a side A of the second membrane, a closed-circuit chamber B comprising a working fluid B, a pump B, and a counter-flow heat exchanger B, wherein the closed-circuit chamber B is connected to the first electrochemical cell on a side B of the first membrane and to the second electrochemical cell on a side B of the second membrane, wherein working fluid A is capable of undergoing a reversible redox half-reaction of the general form R A →O A +I+e − and wherein working fluid B is capable of undergoing a reversible redox half-reaction of the general form R B →O B +I+e − , where R A and R B are reduced forms of active species in working fluid A and working fluid B, respectively, O A and O B are the oxidized forms of active species in working fluid A and working fluid B, respectively, wherein the first electrochemical cell is connected electrically in series with the second electrochemical cell, wherein one of the first pair of electrodes is porous to the working fluid A, and another one of the first pair of electrodes is porous to the working fluid B, wherein one of the second pair of electrodes is porous to the working fluid A, and another one of the second pair of electrodes is porous to the working fluid B, wherein one of the first pair of electrodes is electrically connected to one the second pair of electrodes via an electrical load to produce electricity, whereby the first electrochemical cell runs a forward redox reaction, gaining entropy, and the second electrochemical cell runs a reverse redox reaction, expelling entropy. 2 . The device of claim 1 wherein the first electrochemical cell comprises multiple electrochemical cells connected in series. 3 . The device of claim 1 wherein the second electrochemical cell comprises multiple electrochemical cells connected in series. 4 . The device of claim 1 wherein the working fluid is a liquid, gas, dissolved species or slurry, supporting redox processes with different entropies of reduction and containing a species that crosses the ion-transporting membrane as the ion I. 5 . The device of claim 1 wherein the working fluid is oxygen, hydrogen, water, carbon monoxide, carbon dioxide, or mixtures thereof. 6 . The device of claim 1 wherein the first membrane or second membrane is an ion-conducting ceramic, an ion-conducting polymer, or a molten salt. 7 . The device of claim 1 wherein the porous electrodes are alloys of W, Mo, Ni, other metals, or ceramics supported on an electronically conducting or mixed ion-electron-conducting framework.