Integrated near-field thermo-photovoltaics for on-demand heat recycling

Abstract

The energy transferred via thermal radiation between two surfaces separated by nanometers distances (near-field) can be much larger than the blackbody limit. However, realizing a reconfigurable platform that utilizes this energy exchange mechanism to generate electricity in industrial and space applications on-demand, remains a challenge. The challenge lies in designing a platform that can separate two surfaces by a small and tunable gap while simultaneously maintaining a large temperature differential. Here, we present a fully integrated, reconfigurable and scalable platform operating in near-field regime that performs controlled heat extraction and energy recycling. Our platform relies on an integrated nano-electromechanical system (NEMS) that enables precise positioning of a large area thermal emitter within nanometers distances from a room-temperature germanium photodetector to form a thermo-photovoltaic (TPV) cell. We show over an order of magnitude higher power generation Pgen 1.25 \, μ W · cm-2 from our TPV cell by tuning the gap between a hot emitter (TE 880 \, K) and the cold photodetector (TD 300 \, K) from 500 \, nm to 100 \, nm. The significant enhancement in Pgen at such small distances is a clear indication of near-field heat transfer effect. Our electrostatically controlled NEMS switch consumes negligible tuning power (Pgen/PNEMS 104) and relies on conventional silicon-based process technologies.