Emergent superconductivity and pair density wave at antiphase boundaries of charge density wave order in kagome metals

TL;DR

This study uncovers emergent superconductivity and pair density wave phenomena at antiphase boundaries in kagome metals with charge density wave order, revealing new quantum states and tunable surface superconductivity.

Contribution

It reports the discovery of surface-induced superconductivity and PDW at CDW boundaries in kagome metals, demonstrating atomic manipulation of quantum states.

Findings

Superconductivity with Tc ~ 5.4 K coexists with bulk CDW order.

Observation of a 4x4 pair density wave modulations.

Surface states emerge inside the bulk CDW gap, tunable by surface atom manipulation.

Abstract

Central to the layered kagome lattice superconductors AV3Sb5 (A = K, Cs, Rb) is a cascade of novel quantum states triggered by an unconventional charge density wave (CDW) order. The three-dimensional (3D) order involves a 2x2x2 phase coherent stacking of 2x2 charge density modulations in the kagome plane at low temperatures, exhibiting a CDW energy gap and evidence for time-reversal symmetry breaking. Here we report the discovery of emergent superconductivity and primary pair density wave (PDW) at the antiphase boundaries and stacking faults of bulk CDW order. We find that the {\pi}-phase shift dislocations can naturally appear on the surface as the Cs atoms form 2x2 superstructures that are out of phase with the bulk CDW. An incipient narrow band of surface states inside bulk CDW gap emerge close to the Fermi level where a particle-hole symmetric energy gap develops. We demonstrate that the energy gap originates from a novel quasi-2D kagome superconducting state (Tc ~ 5.4 K) intertwined with bulk CDW order, exhibiting an unprecedented vortex core spectrum and spatial modulations of the superconducting gap consistent with a 4x4 PDW. Intriguingly, the 2D kagome superconductivity is shown to be tunable on and off by atomically manipulating the Cs atoms on the surface. Our findings provide fresh new insights for understanding the interplay between the unconventional CDW and superconductivity in kagome metals and a pathway for atomic manipulation and topological defects engineering of quantum many-body states in correlated materials.