Switchable half-quantum flux states in a ring of the kagome superconductor CsV3Sb5

Abstract

Magnetic flux quantization in units of 0 = h/2e is a defining feature of superconductivity, rooted in the charge-2e nature of Cooper pairs. In a ring geometry, the flux quantization leads to oscillations in the critical temperature with magnetic flux, known as the Little-Parks effect. While the maximal critical temperature is conventionally at zero flux, departures from this rule, for instance shifts by a half-quantum flux 0/2, clearly signal unconventional superconducting states and require sign-changing order parameters. Historically, such π-phase shifts in Little-Parks oscillations have been found in tricrystals or engineered ring structures that intentionally incorporate a π-phase shift. Here we report the discovery of switchable half-quantum flux states in rings made from single crystals of the kagome superconductor CsV3Sb5. We observe Little-Parks oscillations with a π-phase shift at zero bias current, which can be reversibly tuned to conventional Little-Parks oscillations upon applying a bias current. Between the π-phase and 0-phase regimes, h/4e periodic oscillations appear. Our observations suggest unconventional pairing, potentially in the form of a multicomponent order parameter in the kagome superconductor CsV3Sb5, and reveal an electrically tunable landscape of competing superconducting condensates and fractional flux states.

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