Thermopower Study of GaN-Based Materials for Next-Generation Thermoelectric Devices and Applications

被引:0
|
作者
Elisa N. Hurwitz
Muhammad Asghar
Andrew Melton
Bahadir Kucukgok
Liqin Su
Mateusz Orocz
Muhammad Jamil
Na Lu
Ian T. Ferguson
机构
[1] University of North Carolina at Charlotte,Department of Engineering Technology, Sustainable Material and Renewable Technology (SMART) Laboratory
[2] University of North Carolina at Charlotte,Department of Electrical and Computing Engineering
[3] Islamia University of Bahawalpur,Department of Physics
[4] Georgia Institute of Technology,Department of Electrical and Computer Engineering
[5] University of North Carolina at Charlotte,Department of Physics and Optical Science
来源
Journal of Electronic Materials | 2011年 / 40卷
关键词
Thermoelectrics; III-nitrides; Seebeck; GaN; InGaN; GaN:Gd; MOCVD; thermopower;
D O I
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中图分类号
学科分类号
摘要
III-nitride InGaN-based solar cells have gained importance because their band gap can potentially cover most of the solar spectrum, spanning 0.7 eV to 3.4 eV. However, to use these materials to harvest additional energy, other properties such as their thermoelectric properties should be exploited. In this work, the Seebeck coefficient and the electrical conductivity of three InGaN alloys with various indium concentrations and Gd-doped GaN (GaN:Gd) were measured, and the power factor was calculated. We report a Seebeck value of ∼209 μV/K for Gd-doped GaN.
引用
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页码:513 / 517
页数:4
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