English

Maximally Localized Dynamical Quantum Embedding for Solving Many-Body Correlated Systems

Strongly Correlated Electrons 2021-02-19 v3

Abstract

We present a quantum embedding methodology to resolve the Anderson impurity model in the context of dynamical mean-field theory, based on an extended exact diagonalization method. Our method provides a maximally localized quantum impurity model, where the non-local components of the correlation potential remain minimal. This method comes at a large benefit, as the environment used in the quantum embedding approach is described by propagating correlated electrons and hence offers a polynomial increase O(N4)O(N^4) of the number of degrees of freedom for the embedding mapping without adding bath sites. We report that quantum impurity models with as few as 3 bath sites can reproduce both the Mott transition and the Kondo physics, thus opening a more accessible route to the description of time-dependent phenomena. Finally, we obtain excellent agreement for dynamical magnetic susceptibilities, poising this approach as a candidate to describe 2-particle excitations such as excitons in correlated systems. We expect that our approach will be highly beneficial for the implementation of embedding algorithms on quantum computers, as it allows for a fine description of the correlation in materials with a reduced number of required qubits.

Keywords

Cite

@article{arxiv.2008.04281,
  title  = {Maximally Localized Dynamical Quantum Embedding for Solving Many-Body Correlated Systems},
  author = {Carla Lupo and François Jamet and Terence Tse and Ivan Rungger and Cedric Weber},
  journal= {arXiv preprint arXiv:2008.04281},
  year   = {2021}
}
R2 v1 2026-06-23T17:45:28.838Z