Efficiency Limits of Solar Energy Harvesting via Internal Photoemission in Carbon Materials

TL;DR

This paper estimates the maximum efficiency of photon energy harvesting via internal photoemission in carbon materials, comparing it to noble metals, and identifies graphite as a promising candidate for solar spectrum harvesting.

Contribution

It introduces a theoretical framework combining density functional theory and diode modeling to evaluate and compare the efficiency limits of carbon and noble metal-based IPE devices.

Findings

Graphite can effectively harvest visible and near-infrared photons.

Material electron band structure limits IPE device efficiency.

Graphite shows a high potential as a cost-effective IPE absorber.

Abstract

We describe strategies to estimate the upper limits of the efficiency of photon energy harvesting via hot electron extraction from gapless absorbers. Gapless materials such as noble metals can be used for harvesting the whole solar spectrum, including visible and near-infrared light. The energy of photo-generated non-equilibrium or hot charge carriers can be harvested before they thermalize with the crystal lattice via the process of their internal photo-emission (IPE) through the rectifying Schottky junction with a semiconductor. However, the low efficiency and the high cost of noble metals necessitates the search for cheaper abundant alternative materials, and we show here that carbon can serve as a promising IPE material candidate. We compare the upper limits of performance of IPE photon energy-harvesting platforms, which incorporate either gold or carbon as the photoactive material where hot electrons are generated. Through a combination of density functional theory, joint electron density of states calculations, and Schottky diode efficiency modeling, we show that the material electron band structure imposes a strict upper limit on the achievable efficiency of the IPE devices. Our calculations reveal that graphite is a good material candidate for the IPE absorber for harvesting visible and near-infrared photons. Graphite electron density of states yields a sizeable population of hot electrons with energies high enough to be collected across the potential barrier. We also discuss the mechanisms that prevent the IPE device efficiency from reaching the upper limits imposed by their material electron band structures. The proposed approach is general and allows for efficient pre-screening of materials for their potential use in IPE energy converters and photodetectors within application-specific spectral windows.