Nonreciprocal superconducting critical currents with normal state field trainability in kagome superconductor CsV3Sb5

Determining time-reversal symmetry (TRS) and chirality in the superconducting state and its relation to the symmetry and topology in the normal state are important issues in modern condensed matter physics. Here, we report the observation of nonreciprocal superconducting critical currents (Ic) at zero applied magnetic field: Ic exhibits different values in opposite directions, in both flakes and micro-bridges of the kagome superconductor CsV3Sb5. Such spontaneous nonreciprocity requires TRS and inversion symmetry breakings. We find that the direction of asymmetry changes randomly in repeated sample heating to 300 K and cooling into the zero-resistance state, consistent with the expected behavior arising from spontaneous TRS breaking. Crucially, on applying a perpendicular magnetic field at 300 K, above the charge density wave (CDW) transition at TCDW in this compound and removing it to zero well above the superconducting onset critical temperature (Tc), the direction of the Ic asymmetry consistently flips on changing the direction of the field. This magnetic field training ascertains that the CDW state above the superconducting transition temperature may also break the Z2 TRS and has a macroscopic directionality which can be changed by a uniform training field. The symmetry breaking continues into the superconducting state and gives rise to the nonreciprocal superconducting critical currents. These results indicate the loop-current CDW normal state with topological features in CsV3Sb5. Our observations provide direct evidence for the TRS breaking in kagome superconductor CsV3Sb5, and offer new insights into the mechanism of TRS breaking in kagome superconductors.