Sintering Temperature-Dependent Chemical Defects and the Effect on the Electrical Resistivity of Thermoelectric ZnO

Yu Zhao; Ashok Kumar; Giti A. Khodaparast; Amnah Eltahir; Hsin Wang; Shashank Priya

doi:10.1515/ehs-2013-0024

Sintering Temperature-Dependent Chemical Defects and the Effect on the Electrical Resistivity of Thermoelectric ZnO

Yu Zhao, Ashok Kumar, Giti A. Khodaparast, Amnah Eltahir, Hsin Wang, Shashank Priya

Materials Science and Engineering

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

7 Scopus citations

Abstract

Thermoelectric properties of zinc oxide (ZnO) are largely influenced by its electrical property. In this paper, we investigated the correlation between the electrical resistivity and synthesis temperature for aluminum (Al)-modified ZnO. At constant Al doping, the electrical resistivity of ZnO exhibited sharp decrease with increase in sintering temperature due to the increased carrier density resulting from Al3+ substitution on Zn2+ sites. Photoluminescence analysis showed that segregation of Al in secondary phase, ZnAl2O4, promotes Zn2+ vacancy formation and consequently compensates the free electrons that dominate the electrical behavior at relatively low sintering temperature. The mechanism controlling the large change in electrical resistivity of dense ZnO, ranging from insulator (~107 ω cm) to semiconducting regime (~ 0.1 ω cm) has been discussed.

Original language	English (US)
Pages (from-to)	113-119
Number of pages	7
Journal	Energy Harvesting and Systems
Volume	1
Issue number	1-2
DOIs	https://doi.org/10.1515/ehs-2013-0024
State	Published - 2014

All Science Journal Classification (ASJC) codes

Renewable Energy, Sustainability and the Environment
Energy Engineering and Power Technology
Electrical and Electronic Engineering
Electrochemistry

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10.1515/ehs-2013-0024

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title = "Sintering Temperature-Dependent Chemical Defects and the Effect on the Electrical Resistivity of Thermoelectric ZnO",

abstract = "Thermoelectric properties of zinc oxide (ZnO) are largely influenced by its electrical property. In this paper, we investigated the correlation between the electrical resistivity and synthesis temperature for aluminum (Al)-modified ZnO. At constant Al doping, the electrical resistivity of ZnO exhibited sharp decrease with increase in sintering temperature due to the increased carrier density resulting from Al3+ substitution on Zn2+ sites. Photoluminescence analysis showed that segregation of Al in secondary phase, ZnAl2O4, promotes Zn2+ vacancy formation and consequently compensates the free electrons that dominate the electrical behavior at relatively low sintering temperature. The mechanism controlling the large change in electrical resistivity of dense ZnO, ranging from insulator (~107 ω cm) to semiconducting regime (~ 0.1 ω cm) has been discussed.",

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T1 - Sintering Temperature-Dependent Chemical Defects and the Effect on the Electrical Resistivity of Thermoelectric ZnO

AU - Zhao, Yu

AU - Kumar, Ashok

AU - Khodaparast, Giti A.

AU - Eltahir, Amnah

AU - Wang, Hsin

AU - Priya, Shashank

PY - 2014

Y1 - 2014

N2 - Thermoelectric properties of zinc oxide (ZnO) are largely influenced by its electrical property. In this paper, we investigated the correlation between the electrical resistivity and synthesis temperature for aluminum (Al)-modified ZnO. At constant Al doping, the electrical resistivity of ZnO exhibited sharp decrease with increase in sintering temperature due to the increased carrier density resulting from Al3+ substitution on Zn2+ sites. Photoluminescence analysis showed that segregation of Al in secondary phase, ZnAl2O4, promotes Zn2+ vacancy formation and consequently compensates the free electrons that dominate the electrical behavior at relatively low sintering temperature. The mechanism controlling the large change in electrical resistivity of dense ZnO, ranging from insulator (~107 ω cm) to semiconducting regime (~ 0.1 ω cm) has been discussed.

AB - Thermoelectric properties of zinc oxide (ZnO) are largely influenced by its electrical property. In this paper, we investigated the correlation between the electrical resistivity and synthesis temperature for aluminum (Al)-modified ZnO. At constant Al doping, the electrical resistivity of ZnO exhibited sharp decrease with increase in sintering temperature due to the increased carrier density resulting from Al3+ substitution on Zn2+ sites. Photoluminescence analysis showed that segregation of Al in secondary phase, ZnAl2O4, promotes Zn2+ vacancy formation and consequently compensates the free electrons that dominate the electrical behavior at relatively low sintering temperature. The mechanism controlling the large change in electrical resistivity of dense ZnO, ranging from insulator (~107 ω cm) to semiconducting regime (~ 0.1 ω cm) has been discussed.

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Sintering Temperature-Dependent Chemical Defects and the Effect on the Electrical Resistivity of Thermoelectric ZnO

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