Add to ORKGWe present a method to accelerate the numerical evaluation of spatial integrals of Feynman diagrams when expressed on the real frequency axis. This can be realized through use of a renormalized perturbation expansion with a constant but complex renormalization shift. The complex shift acts as a regularization parameter for the numerical integration of otherwise sharp functions. This results in an exponential speed up of stochastic numerical integration at the expense of evaluating additional counter-term diagrams. We provide proof of concept calculations within a difficult limit of the half-filled 2D Hubbard model on a square lattice
A systematic loop expansion is formulated in terms of full propagators and vertices. It is based on ...
We propose a regularization-independent method for studying a renormalizable field theory nonperturb...
A perturbative renormalization procedure is proposed which applies to massive field theories on a sp...
We compute perturbative expansions of the self-energy and spin susceptibility functions in real-fre...
6 pages, 5 figuresWe present a general formalism that allows for the computation of large-order reno...
International audienceWe present a technique that enables the evaluation of perturbative expansions ...
15 pages, 9 figuresDiagrammatic expansions are a central tool for treating correlated electron syste...
International audienceDiagrammatic expansions are a central tool for treating correlated electron sy...
AbstractWe propose a new renormalization procedure to all orders in perturbation theory, which is fo...
We study the renormalized perturbation theory of the single-impurity Anderson model, particularly th...
This paper discusses methods for the construction of approximate real space renormal-ization transfo...
Renormalization of massless Feynman amplitudes in x-space is reexamined here, using almost exclusive...
We give a prescription for the one-loop renormalisation of the imaginary parts of vertex functions i...
This thesis is devoted to the development of numerical methods for correlated electrons in realistic...
Renormalization of massless Feynman amplitudes in x -space is reexamined here, using almost exclusiv...
A systematic loop expansion is formulated in terms of full propagators and vertices. It is based on ...
We propose a regularization-independent method for studying a renormalizable field theory nonperturb...
A perturbative renormalization procedure is proposed which applies to massive field theories on a sp...
We compute perturbative expansions of the self-energy and spin susceptibility functions in real-fre...
6 pages, 5 figuresWe present a general formalism that allows for the computation of large-order reno...
International audienceWe present a technique that enables the evaluation of perturbative expansions ...
15 pages, 9 figuresDiagrammatic expansions are a central tool for treating correlated electron syste...
International audienceDiagrammatic expansions are a central tool for treating correlated electron sy...
AbstractWe propose a new renormalization procedure to all orders in perturbation theory, which is fo...
We study the renormalized perturbation theory of the single-impurity Anderson model, particularly th...
This paper discusses methods for the construction of approximate real space renormal-ization transfo...
Renormalization of massless Feynman amplitudes in x-space is reexamined here, using almost exclusive...
We give a prescription for the one-loop renormalisation of the imaginary parts of vertex functions i...
This thesis is devoted to the development of numerical methods for correlated electrons in realistic...
Renormalization of massless Feynman amplitudes in x -space is reexamined here, using almost exclusiv...
A systematic loop expansion is formulated in terms of full propagators and vertices. It is based on ...
We propose a regularization-independent method for studying a renormalizable field theory nonperturb...
A perturbative renormalization procedure is proposed which applies to massive field theories on a sp...