A mathematical analysis of the discretized IPT-DMFT equations

Abstract

In a previous contribution (E. Canc\`es, A. Kirsch and S. Perrin--Roussel, arXiv:2406.03384), we have proven the existence of a solution to the Dynamical Mean-Field Theory (DMFT) equations under the Iterated Perturbation Theory (IPT-DMFT) approximation. In view of numerical simulations, these equations need to be discretized. In this article, we are interested in a discretization of the ipt-dmft functional equations, based on the restriction of the hybridization function and local self-energy to a finite number of points in the upper half-plane (iωn)n ∈ |[0,Nω]|, where ωn=(2n+1)π / β is the n-th Matsubara frequency and Nω ∈ N. We first prove the existence of solutions to the discretized equations in some parameter range depending on Nω. We then prove uniqueness for a smaller range of parameters. We also study more in depth the case of bipartite systems exhibiting particle-hole symmetry. In this case, the discretized IPT-DMFT equations have purely imaginary solutions, which can be obtained by solving a real algebraic system of (Nω+1) equations with (Nω+1) variables. We provide a complete characterization of the solutions for Nω=0 and some results for Nω=1 in the simple case of the Hubbard dimer. We finally present some numerical simulations on the Hubbard dimer.