Topological multicomponent superconductivity with sizable s-wave admixture in twisted bilayer cuprates

Abstract

We investigate multicomponent superconductivity in twisted bilayer cuprates with order parameter s+d1 eiϕ1+d2 eiϕ2, where s=s1+s2 is the symmetric layer-resolved s-wave component and di denotes the d-wave pairing in layer i. When ϕ1-ϕ2≠ 0,π, this three-component state breaks time-reversal and C4 rotational symmetries and is topologically nontrivial. Combining Ginzburg--Landau analysis with self-consistent microscopic mean-field calculations, we show that this topological state is stabilized over a broad parameter regime. We further identify nematic Kerr anisotropy as a smoking-gun signature distinguishing it from s+id and d1+eiϕd2 states. Our results show that a sizable s-wave component does not preclude chiral topological superconductivity, pointing to twisted cuprates as a more robust platform than previously appreciated.