Multi-orbital effects on superconductivity in kagome metals: Parquet renormalization group analysis (2503.17121v1)

Abstract: The Van Hove singularities (VHSs), where the electronic density of states diverges due to saddle points in the band structure, play a crucial role in enhancing electronic correlations and driving various instabilities. In particular, VHS-induced superconductivity has earned significant attention due to its potential to achieve high transition temperatures and its tendency to favor exotic pairing states beyond conventional electron-phonon mechanisms. Despite extensive research on VHS-driven superconductivity, the multi-orbital effect on such systems remains less explored. Motivated by recent experiments on several kagome metals under doping and pressure [Z.Zhang {\it et al.}, Phys.Rev.B {\bf 103}, 224513 (2021), Y.Sur {\it et al.}, Nat.Commun. {\bf 14}, 3899 (2023)], we explore the effects of multi-orbital physics and strong correlations induced by VHS in the kagome lattice, focusing on their impact on superconductivity. Using parquet renormalization group analysis, we uncover eight distinct superconducting instabilities, characterized by order parameters with mixed orbital degrees of freedom. Among these, we identify a parameter regime where $d$-wave-like orbital-singlet spin-triplet order parameters dominate as the leading instability. The degenerate spin-triplet states in this regime are capable of breaking time-reversal symmetry, which is a multi-orbital analogue of chiral spin-triplet superconductivity. These findings highlight the interplay between multi-orbital effects on superconductivity and can apply to the kagome metal systems such as $A$V$_3$Sb$_5$ ($A$ = K, Rb, Cs) family.