E. A. Kalinina, D. V. Guseinov, A. V. Soukhorukov, A. A. Ezhevskii, D. G. Zverev, F. F. Murzakhanov, N. V. Abrosimov
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引用次数: 0
摘要
摘要 在温度为 T = 3.5-30 K 时,通过电子自旋共振研究了富含无自旋 28Si 和 72Ge 同位素(分别为 99.998% 和 99.984%)的 Si1-xGex(x = 0.0039-0.05)单晶体中的锂供体中心,并将其与硅晶体中的行为进行了比较。研究表明,对于不同的 x < 5 at % 值,具有三方([111])对称性的锂中心在块状 Si1-xGex 中具有最稳定的构型。轴对称性可以通过锂中心位置及其邻近原子的变形来解释。在 4-30 K 的温度范围内对自旋弛豫速率进行了研究,结果表明横向和纵向弛豫由两个部分组成,其速率几乎相差一个数量级。与 1/T1 的拉曼过程一起,观察到指数在 T5 以下有所下降。这种行为可以通过锂的扭曲构型状态的交叉弛豫来解释,锂的扭曲构型状态是由于 Ge 原子的随机分布对晶体场势的调制而产生的。
Electron Spin Resonance of Lithium Related Donor Centers in Bulk Si1−xGex Crystals Enriched in 28Si and 72Ge Isotopes
The lithium donor centers in Si1–xGex (x = 0.0039–0.05) single crystals enriched in spinless 28Si and 72Ge isotopes (99.998 and 99.984%, respectively) are studied by electron spin resonance at temperatures of T = 3.5–30 K and compared with its behavior in Si crystals. It is shown that lithium center with trigonal ([111]) symmetry has a most stable configuration in bulk Si1–xGex for different values of x < 5 at %. Axial symmetry is explained by the distortion of the lithium central position and their neighboring atoms. The spin relaxation rates were studied in temperature range 4–30 K and it was shown that transverse and longitudinal relaxation consist of two components with rates differ by almost an order of magnitude. Together with Raman processes for 1/T1, a decrease in the exponent below T5 is observed. This behavior is explained by cross-relaxation through states of the distorted configuration of lithium, which arise due to modulation of the crystal field potential by random distribution of Ge atoms.
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Applied Magnetic Resonance provides an international forum for the application of magnetic resonance in physics, chemistry, biology, medicine, geochemistry, ecology, engineering, and related fields.
The contents include articles with a strong emphasis on new applications, and on new experimental methods. Additional features include book reviews and Letters to the Editor.
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