Cellular dynamical mean-field theory study of an interacting topological honeycomb lattice model at finite temperature

Cellular dynamical mean-field theory of the periodic Anderson model

We develop a cluster dynamical mean-field theory of the periodic Anderson model in three dimensions, taking a cluster of two sites as a basic reference frame. The mean-field theory displays the basic features of the Doniach phase diagram: a paramagnetic Fermi liquid state, an antiferromagnetic state, and a transition between them. In contrast with spin-density wave theories, the transition is a...

Finite-temperature magnetism of transition metals: an ab initio dynamical mean-field theory.

We present an ab initio quantum theory of the finite-temperature magnetism of iron and nickel. A recently developed technique which combines dynamical mean-field theory with realistic electronic structure methods successfully describes the many-body features of the one electron spectra and the observed magnetic moments below and above the Curie temperature.

Dynamical mean-field theory

Dynamical Mean-field Theory for Correlated Lattice Fermions

Dynamical mean-field theory (DMFT) is a successful method to investigate interacting lattice fermions. In these lecture notes we present an introduction into the DMFT for lattice fermions with interaction, disorder and external inhomogeneous potentials. This formulation is applicable to electrons in solids and to cold fermionic atoms in optical lattices. We review here our investigations of the...

Bath optimization in the cellular dynamical mean-field theory

In the cellular dynamical mean-field theory CDMFT , a strongly correlated system is represented by a small cluster of correlated sites, coupled to an adjustable bath of uncorrelated sites simulating the cluster’s environment; the parameters governing the bath are set by a self-consistency condition involving the local Green’s function and the lattice electron dispersion. Solving the cluster pro...