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Trapped Ion Quantum Computing

Three-carrier spin blockade and coupling in bilayer graphene double quantum dots

arXiv
Authors: Chuyao Tong, Florian Ginzel, Wei Wister Huang, Annika Kurzmann, Rebekka Garreis, Kenji Watanabe, Takashi Taniguchi, Guido Burkard, Jeroen Danon, Thomas Ihn, Klaus Ensslin

Year

2022

Paper ID

57537

Status

Preprint

Abstract Read

~2 min

Abstract Words

170

Citations

N/A

Abstract

The spin degree of freedom is crucial for the understanding of any condensed matter system. Knowledge of spin-mixing mechanisms is not only essential for successful control and manipulation of spin-qubits, but also uncovers fundamental properties of investigated devices and material. For electrostatically-defined bilayer graphene quantum dots, in which recent studies report spin-relaxation times T1 up to 50ms with strong magnetic field dependence, we study spin-blockade phenomena at charge configuration (1,2)leftrightarrow(0,3). We examine the dependence of the spin-blockade leakage current on interdot tunnel coupling and on the magnitude and orientation of externally applied magnetic field. In out-of-plane magnetic field, the observed zero-field current peak could arise from finite-temperature co-tunneling with the leads; though involvement of additional spin- and valley-mixing mechanisms are necessary for explaining the persistent sharp side peaks observed. In in-plane magnetic field, we observe a zero-field current dip, attributed to the competition between the spin Zeeman effect and the Kane-Mele spin-orbit interaction. Details of the line shape of this current dip however, suggest additional underlying mechanisms are at play.

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  • This paper contributes to the Trapped-Ion Quantum Computing research area in the Quantum Articles archive.
  • It adds a 2022 reference point for readers tracking recent quantum research.
  • The spin degree of freedom is crucial for the understanding of any condensed matter system.

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