Pair density wave characterized by a hidden string order parameter

TL;DR

This study reveals a hidden string order parameter in a two-leg t-J model that characterizes a pair density wave induced by spin polarization, highlighting a novel nonlocal phase factor as a new order parameter.

Contribution

The paper identifies a string-like phase factor in the pairing order parameter that characterizes a pair density wave in a doped Mott insulator, a novel insight into superconducting states.

Findings

Identification of a string-like phase factor responsible for PDW.

The pairing amplitude remains unaffected by the PDW.

Local spin polarization can cause sign changes in the order parameter.

Abstract

A composite pairing structure of superconducting state is revealed by density matrix renormalization group study in a two-leg $t$-$J$ model. The pairing order parameter is composed of a pairing amplitude and a phase factor, in which the latter explicitly depends on the spin background with an analytic form identified in the anisotropic limit as the interchain hopping integral $t_{\perp}\rightarrow 0$. Such a string-like phase factor is responsible for a pair density wave (PDW) induced by spin polarization with a wavevector $Q_{\mathrm {PDW}}=2\pi m$ ($m$ the magnetization). By contrast, the pairing amplitude remains smooth, unchanged by the PDW. In particular, a local spin polarization can give rise to a sign change of the order parameter across the local defect. Unlike in an Fulde-Ferrell-Larkin-Ovchinnikov state, the nonlocal phase factor here plays a role as the new order parameter characterizing the PDW, whose origin can be traced back to the essential sign structure of the doped Mott insulator.