用剪切应变提高硅薄膜的迁移率和自旋寿命

2014 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD) Pub Date : 2014-10-23 DOI:10.1109/SISPAD.2014.6931596

D. Osintsev, V. Sverdlov, T. Windbacher, S. Selberherr

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引用次数: 2

摘要

由于22nm及以上节点的finfet /超薄体SOI器件正在不断转变，因此此类结构的移动性增强是一个重要问题。半导体行业用于提高迁移率的应力工程预计在超薄SOI结构中效率会降低，因为传输有效质量对应变的依赖性不太明显。利用k·p哈密顿量精确描述了应变和自旋轨道相互作用下硅中电子的波函数，我们发现波函数和矩阵元素对应变的依赖弥补了有效质量的较弱依赖性，这导致即使在拉伸[110]应力下的超薄(001)SOI薄膜中迁移率也增加了近两倍。此外，我们证明了由于表面粗糙度和声子散射引起的自旋弛豫率也通过施加拉伸应力有效地抑制了一个数量级，这使得SOI结构对自旋驱动应用具有吸引力。

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Increasing mobility and spin lifetime with shear strain in thin silicon films

Because of an ongoing shift to FinFETs/ultra-thin body SOI based devices for the 22nm node and beyond, mobility enhancement in such structures is an important issue. Stress engineering used by the semiconductor industry to boost mobility was predicted to become less efficient in ultra-thin SOI structures due to the less pronounced dependence of the transport effective mass on strain. Using the k · p Hamiltonian which accurately describes the wave functions of electrons in silicon in the presence of strain and spin-orbit interaction, we show that the wave functions and the matrix elements' dependences on strain compensate the weaker dependence of the effective mass, which results in an almost two-fold mobility increase even in ultra-thin (001) SOI films under tensile [110] stress. In addition, we demonstrate that the spin relaxation rate due to surface roughness and phonon scattering is also efficiently suppressed by an order of magnitude by applying tensile stress, which makes SOI structures attractive for spin-driven applications.

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来源期刊

2014 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD)

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