The thermoradiative diode (TRD) is the symmetric counterpart to the photovoltaic solar cell that generates power via the net emission rather than absorption of light. While the TRD has enticing applications in night-sky power generation, there are also opportunities for power generation via waste heat recovery. However, while the theoretical limits for power generation are promising, the current technological limits have not been explored. Here we compare the electro-optical characteristics of HgCdTe photodiodes in operating in both thermoradiative and thermophotovoltaic (TPV) modes, supported by optical modelling. By contrasting thermoradiative and TPV operation using the same devices, we set realistic expectations for power generation using mid-infrared semiconductors.
We present the symmetric counterpart to the solar cell that generates power via the net emission rather than absorption of light. This thermoradiative diode (TRD) has enticing applications in night-sky power generation and waste heat recovery. However, while theoretical limits for night-sky power generation are promising, the current technological limits have not been explored. Here we present the electro-optical characteristics a HgCdTe photodiode in thermoradiative and photovoltaic operation, supported by theoretical calculations that include critical non-radiative processes.
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