Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications

abstract: Photovoltaic (PV) energy has shown tremendous improvements in the past few decades showing great promises for future sustainable energy sources. Among all PV energy sources, III-V-based solar cells have demonstrated the highest efficiencies. This dissertation investigates the two different...

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Other Authors: Vadiee, Ehsan (Author)
Format: Doctoral Thesis
Language:English
Published: 2019
Subjects:
Online Access:http://hdl.handle.net/2286/R.I.53926
id ndltd-asu.edu-item-53926
record_format oai_dc
spelling ndltd-asu.edu-item-539262019-05-16T03:02:03Z Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications abstract: Photovoltaic (PV) energy has shown tremendous improvements in the past few decades showing great promises for future sustainable energy sources. Among all PV energy sources, III-V-based solar cells have demonstrated the highest efficiencies. This dissertation investigates the two different III-V solar cells with low (III-antimonide) and high (III-nitride) bandgaps. III-antimonide semiconductors, particularly aluminum (indium) gallium antimonide alloys, with relatively low bandgaps, are promising candidates for the absorption of long wavelength photons and thermophotovoltaic applications. GaSb and its alloys can be grown metamorphically on non-native substrates such as GaAs allowing for the understanding of different multijunction solar cell designs. The work in this dissertation presents the molecular beam epitaxy growth, crystal quality, and device performance of AlxGa1−xSb solar cells grown on GaAs substrates. The motivation is on the optimization of the growth of AlxGa1−xSb on GaAs (001) substrates to decrease the threading dislocation density resulting from the significant lattice mismatch between GaSb and GaAs. GaSb, Al0.15Ga0.85Sb, and Al0.5Ga0.5Sb cells grown on GaAs substrates demonstrate open-circuit voltages of 0.16, 0.17, and 0.35 V, respectively. In addition, a detailed study is presented to demonstrate the temperature dependence of (Al)GaSb PV cells. III-nitride semiconductors are promising candidates for high-efficiency solar cells due to their inherent properties and pre-existing infrastructures that can be used as a leverage to improve future nitride-based solar cells. However, to unleash the full potential of III-nitride alloys for PV and PV-thermal (PVT) applications, significant progress in growth, design, and device fabrication are required. In this dissertation, first, the performance of ii InGaN solar cells designed for high temperature application (such as PVT) are presented showing robust cell performance up to 600 ⁰C with no significant degradation. In the final section, extremely low-resistance GaN-based tunnel junctions with different structures are demonstrated showing highly efficient tunneling characteristics with negative differential resistance (NDR). To improve the efficiency of optoelectronic devices such as UV emitters the first AlGaN tunnel diode with Zener characteristic is presented. Finally, enabled by GaN tunnel junction, the first tunnel contacted InGaN solar cell with a high VOC value of 2.22 V is demonstrated. Dissertation/Thesis Vadiee, Ehsan (Author) Honsberg, Christiana B (Advisor) Doolittle, William A (Advisor) Arizona State University (Publisher) Engineering III-N III-Sb nitride Solar Cell Tunnel junciton wide bandgap eng 190 pages Doctoral Dissertation Electrical Engineering 2019 Doctoral Dissertation http://hdl.handle.net/2286/R.I.53926 http://rightsstatements.org/vocab/InC/1.0/ 2019
collection NDLTD
language English
format Doctoral Thesis
sources NDLTD
topic Engineering
III-N
III-Sb
nitride
Solar Cell
Tunnel junciton
wide bandgap
spellingShingle Engineering
III-N
III-Sb
nitride
Solar Cell
Tunnel junciton
wide bandgap
Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications
description abstract: Photovoltaic (PV) energy has shown tremendous improvements in the past few decades showing great promises for future sustainable energy sources. Among all PV energy sources, III-V-based solar cells have demonstrated the highest efficiencies. This dissertation investigates the two different III-V solar cells with low (III-antimonide) and high (III-nitride) bandgaps. III-antimonide semiconductors, particularly aluminum (indium) gallium antimonide alloys, with relatively low bandgaps, are promising candidates for the absorption of long wavelength photons and thermophotovoltaic applications. GaSb and its alloys can be grown metamorphically on non-native substrates such as GaAs allowing for the understanding of different multijunction solar cell designs. The work in this dissertation presents the molecular beam epitaxy growth, crystal quality, and device performance of AlxGa1−xSb solar cells grown on GaAs substrates. The motivation is on the optimization of the growth of AlxGa1−xSb on GaAs (001) substrates to decrease the threading dislocation density resulting from the significant lattice mismatch between GaSb and GaAs. GaSb, Al0.15Ga0.85Sb, and Al0.5Ga0.5Sb cells grown on GaAs substrates demonstrate open-circuit voltages of 0.16, 0.17, and 0.35 V, respectively. In addition, a detailed study is presented to demonstrate the temperature dependence of (Al)GaSb PV cells. III-nitride semiconductors are promising candidates for high-efficiency solar cells due to their inherent properties and pre-existing infrastructures that can be used as a leverage to improve future nitride-based solar cells. However, to unleash the full potential of III-nitride alloys for PV and PV-thermal (PVT) applications, significant progress in growth, design, and device fabrication are required. In this dissertation, first, the performance of ii InGaN solar cells designed for high temperature application (such as PVT) are presented showing robust cell performance up to 600 ⁰C with no significant degradation. In the final section, extremely low-resistance GaN-based tunnel junctions with different structures are demonstrated showing highly efficient tunneling characteristics with negative differential resistance (NDR). To improve the efficiency of optoelectronic devices such as UV emitters the first AlGaN tunnel diode with Zener characteristic is presented. Finally, enabled by GaN tunnel junction, the first tunnel contacted InGaN solar cell with a high VOC value of 2.22 V is demonstrated. === Dissertation/Thesis === Doctoral Dissertation Electrical Engineering 2019
author2 Vadiee, Ehsan (Author)
author_facet Vadiee, Ehsan (Author)
title Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications
title_short Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications
title_full Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications
title_fullStr Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications
title_full_unstemmed Design, Growth, and Characterization of III-Sb and III-N Materials for Photovoltaic Applications
title_sort design, growth, and characterization of iii-sb and iii-n materials for photovoltaic applications
publishDate 2019
url http://hdl.handle.net/2286/R.I.53926
_version_ 1719184174926004224