Abstract
The goal of the present paper is twofold. First, a novel expansion many-body method applicable to superfluid open-shell nuclei, the so-called Bogoliubov in-medium similarity renormalization group (BIMSRG) theory, is formulated. This generalization of standard single-reference IMSRG theory for closed-shell systems parallels the recent extensions of coupled cluster, self-consistent Green’s function or many-body perturbation theory. Within the realm of IMSRG theories, BIMSRG provides an interesting alternative to the already existing multi-reference IMSRG (MR-IMSRG) method applicable to open-shell nuclei. The algebraic equations for low-order approximations, i.e., BIMSRG(1) and BIMSRG(2), can be derived manually without much difficulty. However, such a methodology becomes already impractical and error prone for the derivation of the BIMSRG(3) equations, which are eventually needed to reach high accuracy. Based on a diagrammatic formulation of BIMSRG theory, the second objective of the present paper is thus to describe the third version (v3.0) of the ADG code that automatically (1) generates all valid BIMSRG(n) diagrams and (2) evaluates their algebraic expressions in a matter of seconds. This is achieved in such a way that equations can easily be retrieved for both the flow equation and the Magnus expansion formulations of BIMSRG. Expanding on this work, the first future objective is to numerically implement BIMSRG(2) (eventually BIMSRG(3)) equations and perform ab initio calculations of mid-mass open-shell nuclei.
Highlights
The intrinsic cost to solve the many-body Schrödinger equation scales exponentially with the particle number A
Based on a diagrammatic formulation of Bogoliubov in-medium similarity renormalization group (BIMSRG) theory, the second objective of the present paper is to describe the third version (v3.0) of the ADG code that automatically (1) generates all valid BIMSRG(n) diagrams and (2) evaluates their algebraic expressions in a matter of seconds. This is achieved in such a way that equations can be retrieved for both the flow equation and the Magnus expansion formulations of BIMSRG
A novel single-reference expansion many-body method appropriate to the ab initio description of superfluid nuclei is formulated in terms of a particle-number-breaking Bogoliubov vacuum: The Bogoliubov in-medium similarity renormalization group (BIMSRG) formalism
Summary
The intrinsic cost to solve the many-body Schrödinger equation scales exponentially with the particle number A This poses a great challenge to push ab initio calculations based on essentially exact methods such as configuration interaction [1,2,3] (CI) or quantum Monte-Carlo (QMC) approaches [4,5,6] beyond the lightest nuclei. Whenever based on a symmetryconserving Slater-determinant reference state, efficiently describe weakly correlated closed-shell nuclei. In singly open-shell nuclei, U(1) global-gauge symmetry associated with particle-number conservation is relaxed through the use of a Bogoliubov quasiparticle vacuum as the reference state. The present work generalizes the single-reference IMSRG method to Bogoliubov in-medium similarity renormalization group (BIMSRG) theory.
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