Classification of color superconductivity by one-gluon exchange helicity amplitudes and renormalization group equations

TL;DR

This paper classifies color superconductivity in quark matter using one-gluon exchange helicity amplitudes and renormalization group equations, revealing new attractive channels and revising conventional pairing pictures.

Contribution

It introduces a nonrelativistic classification of pairing channels based on OGE helicity amplitudes, identifying new attractive channels and revising the understanding of dominant pairing in quark matter.

Findings

Discovery of a new attractive channel in OGE helicity amplitudes.

Medium effects can make the color 6 channel attractive.

Revised dominance of pairing channels depending on flavor symmetry and Fermi momentum mismatch.

Abstract

Quark matter at high baryon density exhibits diverse pairing patterns classified by color, flavor, and angular momentum quantum numbers. We compute one-gluon exchange (OGE) helicity amplitudes and introduce a nonrelativistic classification of the pairing channel, justified by the channel decomposition in a Lorentz-noninvariant medium and the decoupling of renormalization group flows at leading order. We find the new attractive channel in OGE; the medium effects can render the vacuum-repulsive color $\boldsymbol{6}$ channel attractive in the spin-triplet sector. For color $\boldsymbol{\bar{3}}$ with antisymmetric flavor, the dominant pairing is ${}^1S_0$, while for symmetric flavor the same-helicity $^1P_1$ prevails over $^3S_1$, revising the conventional single-flavor picture. With a mismatch of the Fermi momenta, $^1S_0$ channel, leading to color-flavor locked or two-flavor color superconductor, remains most stable when the separation is small, and the color-spin locked pairing becomes favored as the mismatch gets large. We suggest there are possible quark-hadron continuity in certain cases as expected in the literature.