The Thermal Cost of Harvesting the Solar Infrared Tail in Space-Based Photovoltaics

TL;DR

This paper analyzes the thermal costs associated with harvesting the solar infrared tail in space-based photovoltaics and suggests an optimal cutoff wavelength to improve efficiency and power output.

Contribution

It introduces a method to optimize the infrared spectral cutoff in space photovoltaics to reduce heat generation and enhance overall device performance.

Findings

Optimal infrared cutoff wavelength improves efficiency.

Lower operating temperatures increase end-of-life power output.

Avoiding infrared wavelengths beyond the optimum reduces thermal losses.

Abstract

Space applications require the highest performing photovoltaic devices. Typically these are multi-junction devices that are capable of converting a larger bandwidth of the solar spectrum. However, the conversion of longer wavelength photons in the solar infrared tail results in a disproportionate increase in generated heat per watt of electricity, and since devices have limited heat rejection in space, this excess heat raises the operating temperature, lowering the efficiency of the entire device. Here we show that space-based photovoltaics should avoid converting the solar infrared tail past an optimum terminal cutoff wavelength, and that this will lead to higher electrical output. In addition, a lower operating temperature may lead to higher end-of-life power outputs.