Hot electrons and cold holes: operation, efficiency, and design of a two-temperature hot-carrier solar cell

Thomas Vezin; Nathan Roubinowitz; Jean François Guillemoles; Daniel Suchet

doi:10.1117/1.JPE.15.012504

Hot electrons and cold holes: operation, efficiency, and design of a two-temperature hot-carrier solar cell

Thomas Vezin
, Nathan Roubinowitz
, Jean François Guillemoles
, Daniel Suchet

Research output: Contribution to journal › Article › peer-review

Abstract

Hot-carrier solar cells (HCSCs) offer the potential to enhance the energy-conversion efficiency of photovoltaic devices up to 86%. However, most HCSC models to date assume that electrons and holes have the same temperature, whereas many reports in III to V materials indicate that electrons can be much hotter than their counterparts. We present a detailed balance HCSC model that includes different temperatures for electrons and holes. We focus on the impact of the temperature imbalance on the voltage of such an HCSC and its power-conversion efficiency. Surprisingly, a temperature imbalance at a fixed effective temperature leads to a slight power-conversion efficiency increase, up to 1 to 2 percentage points, primarily due to an increase in fill factor and possibly open-circuit voltage. Yet, we show that the knowledge of the effective temperature alone is sufficient to design a satisfying HCSC.

Original language	English
Article number	012504
Journal	Journal of Photonics for Energy
Volume	15
Issue number	1
DOIs	https://doi.org/10.1117/1.JPE.15.012504
Publication status	Published - 1 Jan 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

efficiency
hot-carrier solar cells
simulation
two-temperature
voltage

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10.1117/1.JPE.15.012504

Cite this

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title = "Hot electrons and cold holes: operation, efficiency, and design of a two-temperature hot-carrier solar cell",

abstract = "Hot-carrier solar cells (HCSCs) offer the potential to enhance the energy-conversion efficiency of photovoltaic devices up to 86\%. However, most HCSC models to date assume that electrons and holes have the same temperature, whereas many reports in III to V materials indicate that electrons can be much hotter than their counterparts. We present a detailed balance HCSC model that includes different temperatures for electrons and holes. We focus on the impact of the temperature imbalance on the voltage of such an HCSC and its power-conversion efficiency. Surprisingly, a temperature imbalance at a fixed effective temperature leads to a slight power-conversion efficiency increase, up to 1 to 2 percentage points, primarily due to an increase in fill factor and possibly open-circuit voltage. Yet, we show that the knowledge of the effective temperature alone is sufficient to design a satisfying HCSC.",

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AU - Vezin, Thomas

AU - Roubinowitz, Nathan

AU - Guillemoles, Jean François

AU - Suchet, Daniel

PY - 2025/1/1

Y1 - 2025/1/1

N2 - Hot-carrier solar cells (HCSCs) offer the potential to enhance the energy-conversion efficiency of photovoltaic devices up to 86%. However, most HCSC models to date assume that electrons and holes have the same temperature, whereas many reports in III to V materials indicate that electrons can be much hotter than their counterparts. We present a detailed balance HCSC model that includes different temperatures for electrons and holes. We focus on the impact of the temperature imbalance on the voltage of such an HCSC and its power-conversion efficiency. Surprisingly, a temperature imbalance at a fixed effective temperature leads to a slight power-conversion efficiency increase, up to 1 to 2 percentage points, primarily due to an increase in fill factor and possibly open-circuit voltage. Yet, we show that the knowledge of the effective temperature alone is sufficient to design a satisfying HCSC.

AB - Hot-carrier solar cells (HCSCs) offer the potential to enhance the energy-conversion efficiency of photovoltaic devices up to 86%. However, most HCSC models to date assume that electrons and holes have the same temperature, whereas many reports in III to V materials indicate that electrons can be much hotter than their counterparts. We present a detailed balance HCSC model that includes different temperatures for electrons and holes. We focus on the impact of the temperature imbalance on the voltage of such an HCSC and its power-conversion efficiency. Surprisingly, a temperature imbalance at a fixed effective temperature leads to a slight power-conversion efficiency increase, up to 1 to 2 percentage points, primarily due to an increase in fill factor and possibly open-circuit voltage. Yet, we show that the knowledge of the effective temperature alone is sufficient to design a satisfying HCSC.

KW - efficiency

KW - hot-carrier solar cells

KW - simulation

KW - two-temperature

KW - voltage

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DO - 10.1117/1.JPE.15.012504

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Hot electrons and cold holes: operation, efficiency, and design of a two-temperature hot-carrier solar cell

Abstract

UN SDGs

Keywords

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