Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell

Thermophotovoltaic (TPV) devices are known for capturing infrared radiation from a high temperature heat source and converting them into electricity. While InAs TPV cells have the ability to harvest radiation heat from temperature source below 1000 K, the best-reported homojunction InAs efficiency i...

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Main Authors: Wong, B.W.A., Gamel, M.M.A., Lee, H.J., Rashid, W.E., Yao, L.K., Jern, K.P.
Format: Conference Paper
Language:English
Published: 2020
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Institution: Universiti Tenaga Nasional
Language: English
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spelling my.uniten.dspace-129052020-07-07T04:26:32Z Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell Wong, B.W.A. Gamel, M.M.A. Lee, H.J. Rashid, W.E. Yao, L.K. Jern, K.P. Thermophotovoltaic (TPV) devices are known for capturing infrared radiation from a high temperature heat source and converting them into electricity. While InAs TPV cells have the ability to harvest radiation heat from temperature source below 1000 K, the best-reported homojunction InAs efficiency is only 0.6 % under 1000 K. This is due to the lack of an optimize structure for TPV application. This research work investigates on optimizing the emitter thickness for Indium Arsenide (InAs) based TPV cells. The electrical characteristics of the InAs TPV cell were simulated using the SILVACO TCAD software. The thickness of p-type emitter ranging from 0.1 to 2.3\ \boldsymbol{\mu} \mathbf{m} were investigated. As the emitter thickness increases, the open circuit voltage (\boldsymbol{V-{oc}}) increases, while the short-circuit current density (\boldsymbol{J-{sc}}) decreases. With the increase rate of \boldsymbol{V-{oc}} which is faster than the decreasing rate of \boldsymbol{J-{sc}}, the maximum power efficiency was achieved at an optimum thickness of 1.5\ \boldsymbol{\mu} \mathbf{m}. At 800 °C blackbody temperature, the highest power efficiency was acquired as 0.61 % at the optimum emitter thickness. © 2019 IEEE. 2020-02-03T03:27:42Z 2020-02-03T03:27:42Z 2019 Conference Paper 10.1109/RSM46715.2019.8943553 en
institution Universiti Tenaga Nasional
building UNITEN Library
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country Malaysia
content_provider Universiti Tenaga Nasional
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language English
description Thermophotovoltaic (TPV) devices are known for capturing infrared radiation from a high temperature heat source and converting them into electricity. While InAs TPV cells have the ability to harvest radiation heat from temperature source below 1000 K, the best-reported homojunction InAs efficiency is only 0.6 % under 1000 K. This is due to the lack of an optimize structure for TPV application. This research work investigates on optimizing the emitter thickness for Indium Arsenide (InAs) based TPV cells. The electrical characteristics of the InAs TPV cell were simulated using the SILVACO TCAD software. The thickness of p-type emitter ranging from 0.1 to 2.3\ \boldsymbol{\mu} \mathbf{m} were investigated. As the emitter thickness increases, the open circuit voltage (\boldsymbol{V-{oc}}) increases, while the short-circuit current density (\boldsymbol{J-{sc}}) decreases. With the increase rate of \boldsymbol{V-{oc}} which is faster than the decreasing rate of \boldsymbol{J-{sc}}, the maximum power efficiency was achieved at an optimum thickness of 1.5\ \boldsymbol{\mu} \mathbf{m}. At 800 °C blackbody temperature, the highest power efficiency was acquired as 0.61 % at the optimum emitter thickness. © 2019 IEEE.
format Conference Paper
author Wong, B.W.A.
Gamel, M.M.A.
Lee, H.J.
Rashid, W.E.
Yao, L.K.
Jern, K.P.
spellingShingle Wong, B.W.A.
Gamel, M.M.A.
Lee, H.J.
Rashid, W.E.
Yao, L.K.
Jern, K.P.
Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell
author_facet Wong, B.W.A.
Gamel, M.M.A.
Lee, H.J.
Rashid, W.E.
Yao, L.K.
Jern, K.P.
author_sort Wong, B.W.A.
title Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell
title_short Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell
title_full Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell
title_fullStr Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell
title_full_unstemmed Simulation and Optimization of Emitter Thickness for Indium Arsenide-Based Thermophotovoltaic Cell
title_sort simulation and optimization of emitter thickness for indium arsenide-based thermophotovoltaic cell
publishDate 2020
_version_ 1672614189185630208