Bandgap of cubic ZnS_(1-x)O_x from optical transmission spectroscopy

Huso Jesse; Bergman Leah; McCluskey Matthew D.

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Bandgap of cubic ZnS_(1-x)O_x from optical transmission spectroscopy

机译：光学透射光谱法分析立方ZnS_（1-x）O_x的带隙

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ZnS1-xOx is a highly mismatched semiconductor alloy with potential light-emitting and solar-cell applications. In this work, optical transmission spectroscopy and a modified derivative method were employed to determine the room-temperature bandgap of cubic (zinc blende) ZnS1-xOx from x = 0.01 to 0.3. The bandgap drops steeply for dilute oxygen concentrations, followed by a more gradual decrease for x 0.05. This nonlinear behavior is attributed to a transition from isolated oxygen impurities to pairs and larger clusters. Alloying with x = 0.3 causes bandgap to drop from 3.7 to 3.1 eV. Previous work showed that the bandgap of wurtzite ZnS1-xOx shifts from 3.7 to 2.8 eV over the same composition range. Published under license by AIP Publishing.

机译：ZnS1-xOx是高度不匹配的半导体合金，具有潜在的发光和太阳能电池应用。在这项工作中，采用光学透射光谱法和改进的微分方法来确定立方（锌共混物）ZnS1-xOx的室温带隙为x = 0.01至0.3。随着氧气浓度的降低，带隙急剧下降，随后随着x> 0.05逐渐减小。这种非线性行为归因于从孤立的氧杂质到成对和更大簇的过渡。 x = 0.3的合金化会使带隙从3.7 eV下降到3.1 eV。先前的工作表明，在相同的组成范围内，纤锌矿型ZnS1-xOx的带隙从3.7 eV转变为2.8 eV。由AIP Publishing授权发布。

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《Journal of Applied Physics 》 |2019年第7期| 075704.1-075704.5| 共5页
作者
Huso Jesse; Bergman Leah; McCluskey Matthew D.;
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作者单位

Washington State Univ, Dept Phys & Astron, Pullman, WA 99164 USA|Univ Idaho, Dept Phys, Moscow, ID 83844 USA;

Univ Idaho, Dept Phys, Moscow, ID 83844 USA;

Washington State Univ, Dept Phys & Astron, Pullman, WA 99164 USA;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);
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正文语种 eng
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1. Bandgap of cubic ZnS_(1-x)O_x from optical transmission spectroscopy [J] . Huso Jesse, Bergman Leah, McCluskey Matthew D. Journal of Applied Physics . 2019 ,第7期

机译：来自光传输光谱的立方ZnS_（1-x）O_x的带隙
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Bandgap of cubic ZnS_(1-x)O_x from optical transmission spectroscopy

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