4 pages, 3 figuresNanoscale physics and dynamical mean field theory have both generated increased interest in complex quantum impurity problems and so have focused attention on the need for flexible quantum impurity solvers. Here we demonstrate that the mapping of single quantum impurity problems onto spin-chains can be exploited to yield a powerful and extremely flexible impurity solver. We implement this cluster algorithm explicitly for the Anderson and Kondo Hamiltonians, and illustrate its use in the ``mesoscopic Kondo problem\'\'. To study universal Kondo physics, a large ratio between the effective bandwidth $D_\\mathrm{eff}$ and the temperature $T$ is required; our cluster algorithm treats the mesoscopic fluctuations exactly while be...
International audienceRecent developments in quantum hardware and quantum algorithms have made it po...
The main goal of this short review is to demonstrate the relevance of dynam-ical symmetry and its br...
In this thesis we summarize several theoretical studies in the context of quantum impurity systems. ...
We present a very efficient solver for the general Anderson impurity problem. It is based on the pe...
Machine learning approaches have recently been applied to the study of various problems in physics. ...
Non-equilibrium quantum many-body problems are attracting increasingly more attention in condensed m...
International audienceIn the $0+1$ dimensional imaginary-time path integral formulation of quantum i...
The Numerical Renormalization Group is used to solve quantum impurity problems, which describe magne...
Strongly correlated electron systems show a rich variety of astonishing physical phenomena. However,...
We study the effect of disorder in strongly interacting small atomic chains. Using the Kotliar-Rucke...
The purpose of this lecture is to discuss in detail the generalized approach of Kawashima and Gubern...
In this thesis, we study quantum impurity models by means of the diagrammatic perturbation theory. F...
We here present how a self-consistent solution of the dynamical mean-field theory equations can be o...
International audienceRecent developments in quantum hardware and quantum algorithms have made it po...
The main goal of this short review is to demonstrate the relevance of dynam-ical symmetry and its br...
In this thesis we summarize several theoretical studies in the context of quantum impurity systems. ...
We present a very efficient solver for the general Anderson impurity problem. It is based on the pe...
Machine learning approaches have recently been applied to the study of various problems in physics. ...
Non-equilibrium quantum many-body problems are attracting increasingly more attention in condensed m...
International audienceIn the $0+1$ dimensional imaginary-time path integral formulation of quantum i...
The Numerical Renormalization Group is used to solve quantum impurity problems, which describe magne...
Strongly correlated electron systems show a rich variety of astonishing physical phenomena. However,...
We study the effect of disorder in strongly interacting small atomic chains. Using the Kotliar-Rucke...
The purpose of this lecture is to discuss in detail the generalized approach of Kawashima and Gubern...
In this thesis, we study quantum impurity models by means of the diagrammatic perturbation theory. F...
We here present how a self-consistent solution of the dynamical mean-field theory equations can be o...
International audienceRecent developments in quantum hardware and quantum algorithms have made it po...
The main goal of this short review is to demonstrate the relevance of dynam-ical symmetry and its br...
In this thesis we summarize several theoretical studies in the context of quantum impurity systems. ...