Many-electron characterizations of higher-charge superconductors

TL;DR

This paper introduces a new microscopic approach to characterize higher-charge superconductors with Cooper pairs of more than two electrons, revealing unique signatures like fractional flux and localized pairs.

Contribution

It proposes many-electron characterizations based on translation symmetrization, extending understanding beyond traditional two-electron Cooper pairs.

Findings

Vanishing charge-2e sectors with signatures in charge-4e or 6e expectations

Momentum conservation is crucial for characterizing higher-charge superconductivity

Predicts experimental signatures such as fractional magnetic flux and localized pairs

Abstract

The theoretical understanding of conventional superconductivity as the phonon-assisted formation and condensation of two-electron Cooper pairs is a significant triumph in condensed matter physics. Here, we propose many-electron characterizations of higher-charge superconductivity with Cooper pairs consisting of more than two electrons, by implementing translation symmetrization on parent pair-density-wave-ordered states. In particular, we demonstrate many-electron constructions with vanishing charge-2e sectors, but with sharp signatures in charge-4e or charge-6e expectation values instead. Such characterizations are consistent with previous phenomenology of vestigial order and Ginzburg-Landau theory, yet, instead of point-group-symmetry presumptions, we show that momentum conservation is both vital and sufficient. Our study thus offers a novel, general, and microscopic route to understand and characterize higher-charge superconductivity, including nontrivial experimental signatures such as fractional magnetic flux and period in interferometry, as well as localized Cooper pairs at lattice topological defects.