Far out-of-equilibrium spin populations trigger giant spin injection into atomically thin MoS2

Far out-of-equilibrium spin populations trigger giant spin injection into atomically thin MoS2

Injecting spins from ferromagnetic metals into semiconductors efficiently is a crucial step towards the seamless integration of charge- and spin-information processing in a single device1,2. However, efficient spin injection into semiconductors has remained an elusive challenge even after almost thr...

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Bibliographic Details
Main Authors: Cheng, Liang, Wang, Xinbo, Yang, Weifeng, Chai, Jianwei, Yang, Ming, Chen, Mengji, Wu, Yang, Chen, Xiaoxuan, Chi, Dongzhi, Goh, Johnson Kuan Eng, Zhu, Jian-Xin, Sun, Handong, Wang, Shijie, Song, Justin Chien Wen, Battiato, Marco, Yang, Hyunsoo, Chia, Elbert Ee Min
Other Authors: School of Physical and Mathematical Sciences
Format: Article
Language:English
Published: 2020
Subjects:
Science::Physics
Spintronics
Terahertz Optics
Online Access:https://hdl.handle.net/10356/138561
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Institution: Nanyang Technological University
Language: English
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Summary:Injecting spins from ferromagnetic metals into semiconductors efficiently is a crucial step towards the seamless integration of charge- and spin-information processing in a single device1,2. However, efficient spin injection into semiconductors has remained an elusive challenge even after almost three decades of major scientific effort3,4,5, due to, for example, the extremely low injection efficiencies originating from impedance mismatch1,2,5,6, or technological challenges originating from stability and the costs of the approaches7,8,9,10,11,12. We show here that, by utilizing the strongly out-of-equilibrium nature of subpicosecond spin-current pulses, we can obtain a massive spin transfer even across a bare ferromagnet/semiconductor interface. We demonstrate this by producing ultrashort spin-polarized current pulses in Co and injecting them into monolayer MoS2, a two-dimensional semiconductor. The MoS2 layer acts both as the receiver of the spin injection and as a selective converter of the spin current into a charge current, whose terahertz emission is then measured. Strikingly, we measure a giant spin current, orders of magnitude larger than typical injected spin-current densities using currently available techniques. Our result demonstrates that technologically relevant spin currents do not require the very strong excitations typically associated with femtosecond lasers. Rather, they can be driven by ultralow-intensity laser pulses, finally enabling ultrashort spin-current pulses to be a technologically viable information carrier for terahertz spintronics.

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