Vortex sub-lattice melting in a two-component superconductor

TL;DR

This paper studies vortex behavior in a two-component superconductor, revealing a novel vortex sub-lattice melting transition where light vortices become disordered while heavy vortices stay ordered, with implications for complex superconducting states.

Contribution

It introduces the concept of vortex sub-lattice melting in two-component superconductors and characterizes its continuous transition in the XY universality class.

Findings

Light vortex sub-lattice melts continuously.

Heavy vortex lattice remains intact during transition.

Transition belongs to XY universality class.

Abstract

We consider the vortex matter in a three-dimensional two-component superconductor with individually conserved condensates with different bare phase stiffnesses in a finite magnetic field, such as the projected superconducting state of liquid metallic hydrogen. The ground state is an Abrikosov lattice of {\it composite}, i.e. co-centered, vortices in both order parameters. We investigate quantitatively two novel phase transitions when temperature is increased at fixed magnetic field. {\it i)} A ``vortex sub-lattice melting" phase transition where vortices in the field with lowest phase stiffness ("light vortices") loose co-centricity with the vortices with large phase stiffness ("heavy vortices"), thus entering a liquid state. Remarkably, the structure factor of the light vortex sub-lattice vanishes {\it continuously}. This novel transition, which has no counterpart in one-component superconductors, is shown to be in the \xy universality class. Across this transition, the lattice of heavy vortices {\it remains intact}.