Phonon-induced spin relaxation of conduction electrons in silicon crystals

2014 International Workshop on Computational Electronics (IWCE) Pub Date : 2014-06-03 DOI:10.1109/IWCE.2014.6865863

D. P. Adorno, N. Pizzolato, C. Graceffa

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引用次数: 2

Abstract

Experimental works managing electrical injection of spin polarization in n-type and p-type silicon have been recently carried out up to room-temperature. In spite of these promising experimental results, a comprehensive theoretical framework concerning the influence of transport conditions on phonon-induced electron spin depolarization in silicon structures, in a wide range of values of lattice temperature, doping concentration and amplitude of external fields, is still at a developing stage. In order to investigate the spin transport of conduction electrons in lightly doped n-type Si crystals, a set of semiclassical multiparticle Monte Carlo simulations has been carried out. The mean spin depolarization time and length of drifting electrons, heated by an electric field, have been calculated. A good agreement is found between our numerical findings and those computed by using different theoretical approaches and recent experimental results obtained in spin transport devices. Our Monte Carlo outcomes, in ranges of temperature and field amplitude yet unexplored, can be used as a guide for future experimental studies oriented towards a more effective optimization of room-temperature silicon-based spintronic devices.

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硅晶体中传导电子的声子诱导自旋弛豫

在室温下，对n型和p型硅中自旋极化的电注入进行了实验研究。尽管有这些令人鼓舞的实验结果，但在晶格温度、掺杂浓度和外场振幅的大范围范围内，关于输运条件对硅结构中声子诱导的电子自旋去极化影响的综合理论框架仍处于发展阶段。为了研究轻掺杂n型Si晶体中传导电子的自旋输运，进行了一套半经典多粒子蒙特卡罗模拟。计算了在电场加热下漂移电子的平均自旋退极化时间和长度。本文的数值计算结果与用不同理论方法计算的结果和最近在自旋输运装置中得到的实验结果吻合得很好。我们的蒙特卡罗结果，在温度和场振幅范围内尚未探索，可以用作未来实验研究的指南，以更有效地优化室温硅基自旋电子器件。

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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2014 International Workshop on Computational Electronics (IWCE)

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