TY - JOUR
T1 - Towards a Strong Spin-Orbit Coupling Magnetoelectric Transistor
AU - Dowben, Peter A.
AU - Binek, Christian
AU - Zhang, Kai
AU - Wang, Lu
AU - Mei, Wai Ning
AU - Bird, Jonathan P.
AU - Singisetti, Uttam
AU - Hong, Xia
AU - Wang, Kang L.
AU - Nikonov, Dmitri
N1 - Publisher Copyright:
© 2014 IEEE.
PY - 2018/6
Y1 - 2018/6
N2 - Here, we outline magnetoelectric (ME) device concepts based on the voltage control of the interface magnetism of an ME antiferromagnet gate dielectric formed on a very thin semiconductor channel with large spin-orbit coupling (SOC). The emphasis of the ME spin field-effect transistors (ME spin FET) is on an antiferromagnet spin-orbit read logic device and a ME spin-FET multiplexer. Both spin-FET schemes exploit the strong SOC in the semiconducting channel materials but remain dependent on the voltage-induced switching of an ME, so that the switching time is limited only by the switching dynamics of the ME. The induced exchange field spin polarizes the channel material, breaks time-reversal symmetry, and results in the preferential charge transport direction, due to the spin-orbit-driven spin-momentum locking. These devices could provide reliable room temperature operation with large on/off ratios, well beyond what can be achieved using magnetic tunnel junctions. All of the proposed device spintronic functionalities without the need to switch a ferromagnet, yielding a faster writing speed (10 ps) at a lower cost in energy (10 aJ), excellent temperature stability (operational up to 400 K or above), and requiring far fewer device elements (transistor equivalents) than CMOS.
AB - Here, we outline magnetoelectric (ME) device concepts based on the voltage control of the interface magnetism of an ME antiferromagnet gate dielectric formed on a very thin semiconductor channel with large spin-orbit coupling (SOC). The emphasis of the ME spin field-effect transistors (ME spin FET) is on an antiferromagnet spin-orbit read logic device and a ME spin-FET multiplexer. Both spin-FET schemes exploit the strong SOC in the semiconducting channel materials but remain dependent on the voltage-induced switching of an ME, so that the switching time is limited only by the switching dynamics of the ME. The induced exchange field spin polarizes the channel material, breaks time-reversal symmetry, and results in the preferential charge transport direction, due to the spin-orbit-driven spin-momentum locking. These devices could provide reliable room temperature operation with large on/off ratios, well beyond what can be achieved using magnetic tunnel junctions. All of the proposed device spintronic functionalities without the need to switch a ferromagnet, yielding a faster writing speed (10 ps) at a lower cost in energy (10 aJ), excellent temperature stability (operational up to 400 K or above), and requiring far fewer device elements (transistor equivalents) than CMOS.
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U2 - 10.1109/JXCDC.2018.2809640
DO - 10.1109/JXCDC.2018.2809640
M3 - Article
AN - SCOPUS:85055478513
SN - 2329-9231
VL - 4
SP - 1
EP - 9
JO - IEEE Journal on Exploratory Solid-State Computational Devices and Circuits
JF - IEEE Journal on Exploratory Solid-State Computational Devices and Circuits
ER -