Gorkov algebraic diagrammatic construction for infinite nuclear matter

TL;DR

This paper introduces a new many-body truncation method within Gorkov SCGF theory that accurately describes pairing and dynamical correlations in infinite nuclear matter, leading to improved predictions of its properties.

Contribution

The paper presents a novel truncation scheme that combines first-order pairing with third-order dynamical correlations in Gorkov SCGF, enabling more accurate modeling of nuclear matter.

Findings

Accurate equation of state predictions for infinite nuclear matter.

Spectral properties consistent with modern chiral Hamiltonians.

Effective handling of pairing correlations at first order.

Abstract

We propose a novel many-body truncation for Gorkov self-consistent Green's function (SCGF) theory where pairing correlations are handled at first order, while dynamical correlations are described using the particle-number-conserving Dyson-SCGF scheme up to third order in the algebraic diagrammatic construction. The new method is enabled by the introduction of a scheme that allows to approximate the Gorkov propagator in terms of a particle-number-conserving optimized reference state. The approach provides state-of-the-art predictions of the equation of state and spectral properties of infinite nuclear matter at zero temperature and in the presence of pairing. We find satisfactory results using modern saturating Hamiltonians at next-to-next-to-leading order in chiral effective field theory.