Growth of ZnTe Semiconductor Crystal Via a Te Flux Zone Melting Method and Characterization of Its Properties

Min Jin; Feng He; Shuying Zheng; Yadong Xu; Yan Peng; Xiufei Chen; Xiangang Xu

doi:10.1002/crat.202100279

Growth of ZnTe Semiconductor Crystal Via a Te Flux Zone Melting Method and Characterization of Its Properties

Min Jin, Feng He, Shuying Zheng, Yadong Xu, Yan Peng, Xiufei Chen, Xiangang Xu

材料学院

科研成果: 期刊稿件 › 文章 › 同行评审

5 引用（Scopus）

摘要

In this work, a kind of II;-VI group ZnTe semiconductor crystal is successfully grown using a Te flux zone melting method from Zn: Te = 3: 7 mole ratio solution. The crystal has standard F43m cubic space group and the a/b/c lattice constants are all calculated to be 6.105 Å. Energy dispersive spectroscopy analysis confirms it has quasistoichiometric ratio and the Zn/Te elements are distributed in the material homogeneously. The polished 1.0 mm thickness (110) wafer exhibits a highest ≈64.5% transmittance near 2400 nm wavelength and the bandgap E_g is deduced as 2.223 eV. ZnTe crystal shows a heavy volatilization start from 910 °C and the weight losing speed is about ≈1.45% min⁻¹. The thermal conductivity k displays good repeatability in the cooling and heating stages, the k value is about 15.8 Wm⁻¹ K⁻¹ at room temperature and is deceased to 3.53 Wm⁻¹ K⁻¹ under 500 °C. These results would be of great reference when ZnTe crystal is used for device design and application in the future.

源语言	英语
文章编号	2100279
期刊	Crystal Research and Technology
卷	57
期	10
DOI	https://doi.org/10.1002/crat.202100279
出版状态	已出版 - 10月 2022

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title = "Growth of ZnTe Semiconductor Crystal Via a Te Flux Zone Melting Method and Characterization of Its Properties",

abstract = "In this work, a kind of II;-VI group ZnTe semiconductor crystal is successfully grown using a Te flux zone melting method from Zn: Te = 3: 7 mole ratio solution. The crystal has standard F43m cubic space group and the a/b/c lattice constants are all calculated to be 6.105 {\AA}. Energy dispersive spectroscopy analysis confirms it has quasistoichiometric ratio and the Zn/Te elements are distributed in the material homogeneously. The polished 1.0 mm thickness (110) wafer exhibits a highest ≈64.5% transmittance near 2400 nm wavelength and the bandgap Eg is deduced as 2.223 eV. ZnTe crystal shows a heavy volatilization start from 910 °C and the weight losing speed is about ≈1.45% min−1. The thermal conductivity k displays good repeatability in the cooling and heating stages, the k value is about 15.8 Wm−1 K−1 at room temperature and is deceased to 3.53 Wm−1 K−1 under 500 °C. These results would be of great reference when ZnTe crystal is used for device design and application in the future.",

keywords = "ZnTe crystal, thermal conductivity, transmittance, volatilization",

author = "Min Jin and Feng He and Shuying Zheng and Yadong Xu and Yan Peng and Xiufei Chen and Xiangang Xu",

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doi = "10.1002/crat.202100279",

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T1 - Growth of ZnTe Semiconductor Crystal Via a Te Flux Zone Melting Method and Characterization of Its Properties

AU - Jin, Min

AU - He, Feng

AU - Zheng, Shuying

AU - Xu, Yadong

AU - Peng, Yan

AU - Chen, Xiufei

AU - Xu, Xiangang

PY - 2022/10

Y1 - 2022/10

N2 - In this work, a kind of II;-VI group ZnTe semiconductor crystal is successfully grown using a Te flux zone melting method from Zn: Te = 3: 7 mole ratio solution. The crystal has standard F43m cubic space group and the a/b/c lattice constants are all calculated to be 6.105 Å. Energy dispersive spectroscopy analysis confirms it has quasistoichiometric ratio and the Zn/Te elements are distributed in the material homogeneously. The polished 1.0 mm thickness (110) wafer exhibits a highest ≈64.5% transmittance near 2400 nm wavelength and the bandgap Eg is deduced as 2.223 eV. ZnTe crystal shows a heavy volatilization start from 910 °C and the weight losing speed is about ≈1.45% min−1. The thermal conductivity k displays good repeatability in the cooling and heating stages, the k value is about 15.8 Wm−1 K−1 at room temperature and is deceased to 3.53 Wm−1 K−1 under 500 °C. These results would be of great reference when ZnTe crystal is used for device design and application in the future.

AB - In this work, a kind of II;-VI group ZnTe semiconductor crystal is successfully grown using a Te flux zone melting method from Zn: Te = 3: 7 mole ratio solution. The crystal has standard F43m cubic space group and the a/b/c lattice constants are all calculated to be 6.105 Å. Energy dispersive spectroscopy analysis confirms it has quasistoichiometric ratio and the Zn/Te elements are distributed in the material homogeneously. The polished 1.0 mm thickness (110) wafer exhibits a highest ≈64.5% transmittance near 2400 nm wavelength and the bandgap Eg is deduced as 2.223 eV. ZnTe crystal shows a heavy volatilization start from 910 °C and the weight losing speed is about ≈1.45% min−1. The thermal conductivity k displays good repeatability in the cooling and heating stages, the k value is about 15.8 Wm−1 K−1 at room temperature and is deceased to 3.53 Wm−1 K−1 under 500 °C. These results would be of great reference when ZnTe crystal is used for device design and application in the future.

KW - ZnTe crystal

KW - thermal conductivity

KW - transmittance

KW - volatilization

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Growth of ZnTe Semiconductor Crystal Via a Te Flux Zone Melting Method and Characterization of Its Properties

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