What question did this study set out to answer?

To analyze the behavior of GeSn alloys in thermophotovoltaic systems under various conditions.

March 15, 2026Open Access

GeSn alloys for thermophotovoltaics: interplay of heat transfer, optical and electronic properties

Key Points

To analyze the behavior of GeSn alloys in thermophotovoltaic systems under various conditions.
Developed a finite element model (FEM) of a TPV system using GeSn photovoltaic cells.
Examined effects of indirect recombination and multilayer generation dynamics.
Investigated thermal equilibrium between the emitter and the cell.
Identified relationships between heat transfer and optical/electronic properties.
Determined impacts of strain and composition on Ge-based materials' performance.
Provided insights for future device design.

Abstract

Thermophotovoltaics (TPV) shows promise for direct heat-to-electricity conversion. Unlike solar cells that are powered by the Sun, TPV sources (concentrated sunlight heating, waste heat, power beaming), typically at 1000-2000 K, are closer, which yields radiation with significantly higher power densities (5-60 W/cm2 versus ~0.1 W/cm2 for solar) but below the bandgaps of many common semiconductors. This has drawn attention toward low-bandgap, CMOS-compatible materials (particularly group-IV semiconductors such as germanium (Ge) and germanium-tin alloys (GeSn). This work presents a comprehensive finite element model (FEM) of a TPV system employing a low-bandgap, direct-gap GeSn photovoltaic cell, accounting for indirect recombination, multilayer generation dynamics, and the thermal equilibrium between emitter and cell. It supports in-depth study of Ge-based materials under varying strain, composition, and temperature, providing insights for the design of future devices.

GeSn alloys for thermophotovoltaics: interplay of heat transfer, optical and electronic properties

Key Points

Abstract

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