Determination of Conductivity Electron Concentration in Single-Crystalline n-GaSb Samples Using FIR Reflection Spectra at T = 295 K

IF 0.8 4区物理与天体物理 Q4 OPTICS Optics and Spectroscopy Pub Date : 2024-09-11 DOI:10.1134/S0030400X24040027

A. G. Belov, E. V. Molodtsova, S. S. Kormilitsina, R. Yu. Kozlov, E. O. Zhuravlev, S. A. Klimin, N. N. Novikova, V. A. Yakovlev

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Abstract

A method is proposed for separately determining the concentrations of “light” and “heavy” electrons in n-GaSb. It is based on the analysis of reflection spectra in the far infrared region, taking into account the plasmon-phonon coupling. Calibration curves have been calculated that allow one to determine the concentrations of “light” and “heavy” electrons in GaSb using the frequency of high-energy coupled plasmon-phonon mode. For a series of n-GaSb samples the reflection spectra were measured and the concentrations of “light” and “heavy” electrons were determined at room temperature. Electrophysical Van der Paw measurements have been performed on the same samples at room temperature. By comparing the optical and Hall data, the ratios of the mobilities of “light” and “heavy” electrons (parameter b) were determined. This method of determining the value of the parameter b is used for the first time.

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利用 T = 295 K 时的 FIR 反射谱测定单晶 n-GaSb 样品中的传导性电子浓度

摘要提出了一种分别确定 n-GaSb 中 "轻 "电子和 "重 "电子浓度的方法。该方法基于对远红外区域反射光谱的分析，并考虑了质子-声子耦合。通过计算校准曲线，可以利用高能耦合质子-声子模式的频率确定氮化镓硒中 "轻 "电子和 "重 "电子的浓度。对一系列 n-GaSb 样品的反射光谱进行了测量，并确定了室温下 "轻 "和 "重 "电子的浓度。在室温下对相同的样品进行了范德帕电物理测量。通过比较光学数据和霍尔数据，确定了 "轻 "电子和 "重 "电子的迁移率之比（参数 b）。这种确定参数 b 值的方法是首次使用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Optics and Spectroscopy 物理-光谱学

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

4.5 months

期刊介绍： Optics and Spectroscopy (Optika i spektroskopiya), founded in 1956, presents original and review papers in various fields of modern optics and spectroscopy in the entire wavelength range from radio waves to X-rays. Topics covered include problems of theoretical and experimental spectroscopy of atoms, molecules, and condensed state, lasers and the interaction of laser radiation with matter, physical and geometrical optics, holography, and physical principles of optical instrument making.