Spin relaxation in a single-electron graphene quantum dot

L. Banszerus; K. Hecker; S. Möller; E. Icking; K. Watanabe; T. Taniguchi; C. Volk; C. Stampfer

Article Spin relaxation in a single-electron graphene quantum dot

L. Banszerus ; K. Hecker ; S. Möller ; E. Icking ; K. Watanabe (National Institute for Materials Science) ; T. Taniguchi (National Institute for Materials Science) ; C. Volk ; C. Stampfer

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L. Banszerus, K. Hecker, S. Möller, E. Icking, K. Watanabe, T. Taniguchi, C. Volk, C. Stampfer. Spin relaxation in a single-electron graphene quantum dot. Nature Communications. 2022, 13 (1), 3637.

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The relaxation time of a single-electron spin is a key parameter for solid-state spin qubits, as it directly limits the lifetime of the encoded information. Thanks to the low spin-orbit interaction and low hyperfine coupling, graphene and bilayer graphene (BLG) have long been considered promising platforms for spin qubit. Only recently, it has become possible to control single-electrons in BLG quantum dots (QDs) and to understand their spin-valley texture, while the relaxation dynamics have remained mostly unexplored. Here, we report spin relaxation times (T1) of single-electron states in BLG QDs. Using pulsed-gate spectroscopy, we extract relaxation times exceeding 200 μs at a magnetic field of 1.9 T. The T1 values show a strong dependence on the spin splitting, promising even longer T1 at lower magnetic fields, where our measurements are limited by the signal-to-noise ratio. The relaxation times are more than two orders of magnitude larger than those previously reported for carbon-based QDs, confirming that graphene is a promising host material for scalable spin qubits.

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