Abstract
Graphene has gigantic potential in the development of advanced spintronic devices. The interfacial interactions of graphene with semiconducting transition metal dichalcogenides improve the electronic properties drastically, making it an intriguing candidate for spintronic applications. Here, we fabricated bilayer graphene encapsulated by WS2 layers to exploit the interface-induced spin-orbit interaction (SOI). We designed a dual gated device, where the SOI is tuned by gate voltages. The strength of induced SOI in the bilayer graphene is dramatically elevated, which leads to a strong weak antilocalization (WAL) effect at low temperature. The quantitative analysis of WAL demonstrates that the spin relaxation time is 10 times smaller than in bilayer graphene on conventional substrates. To support these results, we also examined Shubnikov-de Haas (SdH) oscillations, which give unambiguous evidence of the zero-field spin-splitting in our bilayer graphene. The spin-orbit coupling constants estimated by two different measurements (i.e., the WAL effect and SdH oscillations) show close values as a function of gate voltage, supporting the self-consistency of this study’s experimental results. The gate modulation of the SOI in bilayer graphene encapsulated by WS2 films establishes a novel way to explore the manipulation of spin-dependent transport through an electric field.
Highlights
We develop an innovative dual gate WS2/bilayer graphene/WS2 sandwich device to address the gate modulation of spinorbit interaction (SOI) by measuring the quantum interference transport and Shubnikov-de Haas (SdH) oscillations
This paper demonstrates that the magnitude of SOI relaxation time in WS2-encapsulated bilayer graphene (BLG) is 10 times smaller than τso in graphene on ordinary substrate
The thickness is further confirmed by atomic force microscopy (AFM)
Summary
We develop an innovative dual gate WS2/bilayer graphene/WS2 sandwich device to address the gate modulation of SOI by measuring the quantum interference transport and Shubnikov-de Haas (SdH) oscillations. It is found that the SOI of the bilayer graphene is tuned by applying gate voltages. To endorse these results, we have measured SdH oscillations, which provide unambiguous evidence of the zero-field spin-splitting due to a strong SOI. The estimated values of SOI through WAL analysis and SdH oscillation analysis give close results, supporting the self-consistency of this study’s experimental results. The effective gate modification of SOI strength in the graphene-based system enables this study to explore new areas of the field-effect spin transport phenomenon
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