Theoretical efficiency limits for thermoradiative energy conversion
Original version
Strandberg, R. (2015). Theoretical efficiency limits for thermoradiative energy conversion. Journal of Applied Physics, 117(5). doi: 10.1063/1.4907392Abstract
A new method to produce electricity from heat called thermoradiative energy conversion is
analyzed. The method is based on sustaining a difference in the chemical potential for electron
populations above and below an energy gap and let this difference drive a current through an
electric circuit. The difference in chemical potential originates from an imbalance in the excitation
and de-excitation of electrons across the energy gap. The method has similarities to thermophotovoltaics
and conventional photovoltaics. While photovoltaic cells absorb thermal radiation from a
body with higher temperature than the cell itself, thermoradiative cells are hot during operation and
emit a net outflow of photons to colder surroundings. A thermoradiative cell with an energy gap of
0.25 eV at a temperature of 500K in surroundings at 300K is found to have a theoretical efficiency
limit of 33.2%. For a high-temperature thermoradiative cell with an energy gap of 0.4 eV, a theoretical
efficiency close to 50% is found while the cell produces 1000 W/m2 has a temperature of
1000K and is placed in surroundings with a temperature of 300 K. Some aspects related to the
practical implementation of the concept are discussed and some challenges are addressed. It is, for
example, obvious that there is an upper boundary for the temperature under which solid state
devices can work properly over time. No conclusions are drawn with regard to such practical
boundaries, because the work is aimed at establishing upper limits for ideal thermoradiative
devices.
Description
Published version of an article in the journal: Journal of Applied Physics. Also available from the publisher at: http://dx.doi.org/10.1063/1.4907392