Thermionic-enhanced near-field thermophotovoltaics
Alejandro Datas, Rodolphe Vaillon

TL;DR
This paper introduces a novel thermionic-enhanced near-field thermophotovoltaic device that significantly boosts power density and efficiency by utilizing nanoscale vacuum gaps for simultaneous photon and electron emission.
Contribution
It proposes a new device design combining thermionic and thermophotovoltaic effects with nanoscale gaps, achieving higher power density and efficiency than existing near-field devices.
Findings
Achieves 30% efficiency at 2000K with 70W/cm2 power density.
Uses nanoscale vacuum gaps to enhance photon and electron fluxes.
Eliminates series resistance issues with grid-less cell design.
Abstract
Solid-state heat-to-electrical power converters are thermodynamic engines that use fundamental particles, such as electrons or photons, as working fluids. Virtually all commercially available devices are thermoelectric generators, in which electrons flow through a solid driven by a temperature difference. Thermophotovoltaics and thermionics are highly efficient alternatives relying on the direct emission of photons and electrons. However, the low energy flux carried by the emitted particles significantly limits their generated electrical power density potential. Creating nanoscale vacuum gaps between the emitter and the receiver in thermionic and thermophotovoltaic devices enables a significant enhancement of the electron and photon energy fluxes, respectively, which in turn results in an increase of the generated electrical power density. Here we propose a thermionic-enhanced…
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