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Spin-Valley Locking for In-Gap Quantum Dots in a MoS<sub>2</sub> Transistor

Radha Krishnan, Sangram Biswas, Yu‐Ling Hsueh, Hongyang Ma, Rajib Rahman, Bent Weber

2023Nano Letters24 citationsDOIOpen Access PDF

Abstract

Spins confined to atomically thin semiconductors are being actively explored as quantum information carriers. In transition metal dichalcogenides (TMDCs), the hexagonal crystal lattice gives rise to an additional valley degree of freedom with spin-valley locking and potentially enhanced spin life and coherence times. However, realizing well-separated single-particle levels and achieving transparent electrical contact to address them has remained challenging. Here, we report well-defined spin states in a few-layer MoS 2 transistor, characterized with a spectral resolution of ∼50 μeV at T el = 150 mK. Ground state magnetospectroscopy confirms a finite Berry-curvature induced coupling of spin and valley, reflected in a pronounced Zeeman anisotropy, with a large out-of-plane g -factor of g ⊥ ≃ 8. A finite in-plane g -factor ( g ∥ ≃ 0.55–0.8) allows us to quantify spin-valley locking and estimate the spin–orbit splitting 2Δ SO ∼ 100 μeV. The demonstration of spin-valley locking is an important milestone toward realizing spin-valley quantum bits.

Topics & Concepts

Condensed matter physicsSpin (aerodynamics)Spin transistorPhysicsSpinsQuantum dotQuantum wellGround stateRashba effectSpin polarizationSpin engineeringAtomic physicsOptoelectronicsFerromagnetismQuantum mechanicsElectronSpintronicsThermodynamicsLaserQuantum and electron transport phenomena2D Materials and ApplicationsGraphene research and applications
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