Spin Lifetime Enhancement by Shear Strain in Thin Silicon-On-Insulator Films
نویسندگان
چکیده
Spintronics attracts at present much interest because of the potential to build novel spin-based devices which are superior to nowadays charge-based microelectronic elements. Utilizing spin properties of electrons opens great opportunities to reduce device power consumption in future electronic circuits. Silicon, the main element of microelectronics, is promising for spin-driven applications. Understanding the details of the spin propagation in silicon structures is a key for building novel spin-based nanoelectronic devices. We investigate the influence of shear strain on surface roughness induced spin relaxation in a thin silicon-on-insulator-based transistor. Shear strain dramatically influences the spin, which opens a new opportunity to boost spin lifetime in a silicon spin field-effect transistor.
منابع مشابه
Uniaxial Shear Strain as a Mechanism to Increase Spin Lifetime in Thin Film of a SOI-Based Silicon Spin FETs
In this chapter we investigate spin relaxation in thin silicon films. We employ a k p based approach to investigate surface roughness and phonon induced momentum and spin relaxation matrix elements. We show that the spin relaxation matrix elements strongly decrease with shear strain increased. In order to meet computational requirements with actual resources needed for relaxation time calculati...
متن کاملSilicon-on-Insulator for Spintronic Applications: Spin Lifetime and Electric Spin Manipulation
With complementary metal-oxide semiconductor feature size rapidly approaching ultimate scaling limits, the electron spin attracts much attention as an alternative to the electron charge degree of freedom for low-power reprogrammable logic and nonvolatile memory applications. Silicon, the main element of microelectronics, appears to be the perfect material for spin-driven applications. Despite a...
متن کاملStrained silicon-on-insulator for spintronic applications: Giant spin lifetime enhancement
With CMOS feature size rapidly approaching ultimate limits, electron spin is attracting attention as an alternative to the electron charge. Silicon appears to be the perfect material for spin-driven applications. Room-temperature electrical spin injection into Si from a ferromagnetic contact has been successfully demonstrated [1]. Silicon is mostly composed of nuclei with zero spin and characte...
متن کاملVariation of Spin Lifetime with Spin Injection Orientation in Strained Thin Silicon Films
Spintronics attracts at present much interest because of the potential to build novel spin-based devices which are superior to charge-based microelectronic elements. Silicon, the main element of microelectronics, is promising for spin-driven applications. Understanding the peculiarities of the subband structure and details of spin propagation in thin silicon films in the presence of the spinorb...
متن کاملEvaluation of Spin Lifetime in Thin-Body FETs: A High Performance Computing Approach
Silicon, the prominent material of microelectronics, is perfectly suited for spin-driven applications because of the weak spin-orbit interaction resulting in long spin lifetime. However, additional spin relaxation on rough interfaces and acoustic phonons may strongly decrease the spin lifetime in modern silicon-on-insulator and trigate transistors. Because of the need to perform numerical calcu...
متن کاملذخیره در منابع من
با ذخیره ی این منبع در منابع من، دسترسی به آن را برای استفاده های بعدی آسان تر کنید
عنوان ژورنال:
دوره شماره
صفحات -
تاریخ انتشار 2013