TY - JOUR
T1 - Study of spin transport and magnetoresistance effect in silicon-based lateral spin devices for spin-mosfet applications
AU - Ishikawa, M.
AU - Saito, Y.
AU - Hamaya, K.
N1 - Publisher Copyright:
© 2020, Magnetics Society of Japan. All rights reserved.
PY - 2020
Y1 - 2020
N2 - In this paper, we introduce the current status of research and development on silicon-based spin metal-oxide-semiconductor field-effect transistors (Si spin-MOSFETs) in terms of electrical spin injection, spin transport, and spin detection in Si-based lateral spin-valve devices. First, it is important for understanding the spin transport in Si to obtain reliably large spin signals for analyses. By using n+-Si spin-transport layers with a small cross-sectional area of ~0.3 μm2, we can observe 50-fold the magnitude of four-terminal nonlocal (NL) magnetoresistance signals and NL Hanle signals at room temperature in previous works. Next, by analyzing these spin signals, we can reliably estimate the spin diffusion length and spin relaxation time of n+-Si at room temperature. Also, we clarify that inter-valley spin-flip scattering is one of the dominant spin relaxation mechanisms in n+-Si at room temperature. Furthermore, we find the crystal orientation effect on spin injection/detection efficiency in n+-Si and discuss the possible origins. Finally, we demonstrate a room-temperature MR ratio of 0.06%, twice as large as that in the previous work.
AB - In this paper, we introduce the current status of research and development on silicon-based spin metal-oxide-semiconductor field-effect transistors (Si spin-MOSFETs) in terms of electrical spin injection, spin transport, and spin detection in Si-based lateral spin-valve devices. First, it is important for understanding the spin transport in Si to obtain reliably large spin signals for analyses. By using n+-Si spin-transport layers with a small cross-sectional area of ~0.3 μm2, we can observe 50-fold the magnitude of four-terminal nonlocal (NL) magnetoresistance signals and NL Hanle signals at room temperature in previous works. Next, by analyzing these spin signals, we can reliably estimate the spin diffusion length and spin relaxation time of n+-Si at room temperature. Also, we clarify that inter-valley spin-flip scattering is one of the dominant spin relaxation mechanisms in n+-Si at room temperature. Furthermore, we find the crystal orientation effect on spin injection/detection efficiency in n+-Si and discuss the possible origins. Finally, we demonstrate a room-temperature MR ratio of 0.06%, twice as large as that in the previous work.
KW - MR
KW - Si spin-MOSFETs
KW - Spin relaxation
KW - Spin transport
UR - http://www.scopus.com/inward/record.url?scp=85084253312&partnerID=8YFLogxK
U2 - 10.3379/msjmag.2005RV002
DO - 10.3379/msjmag.2005RV002
M3 - Article
AN - SCOPUS:85084253312
SN - 1882-2932
VL - 44
SP - 56
EP - 63
JO - Journal of the Magnetics Society of Japan
JF - Journal of the Magnetics Society of Japan
IS - 3
ER -