Vortex Dynamics in Magic-Angle Twisted Graphene
Abstract
We use a gate-defined Josephson junction (JJ) device made from twisted-layer graphene for studying vortex dynamics in two dimensions. The JJ sensor signals the presence of individual vortices in the superconducting leads nearby the junction through shifts in the Fraunhofer interference pattern of the magnetic-field-dependent critical current Ic(B) across the junction. Rapid vortex fluctuations manifest as telegraph-type noise in time traces of the junction voltage V(t). Measurements of Ic(B) and V(t) are interpreted in terms of multi-vortex processes where fast vortex fluctuations in the leads are modulated by quasi-stationary vortices trapped in the leads. The different timescales associated with these processes allow for their disentangling and quantitative analysis. Tracking the temperature dependence of the vortex-dynamical rates between T = 7 mK and T = 120 mK, we find that the creep type vortex motion is thermally activated above T ≈ 100 mK, while the saturation of rates below T ≈ 80 mK is suggestive of a sharp transition to macroscopic quantum tunneling of vortices.
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