Add to ORKGThe well-known bosonisation method of one-dimensional electron systems is extended to finite temperatures. As an example, the correlation functions of the non-interacting case are explicitly calculated. The presentation is pedagogical and is intended to be accessible to graduate students or physicists who are not experts in this field. 1
In this review we provide a rigorous and self-contained presentation of one-body reduced density-mat...
1D spin-1/2 Fermi gas with a self-interaction allows a non-perturbative solution. Using the algebrai...
We present a phase-space method for fermionic systems, which enables simulations of the dynamics and...
The well-known bosonisation method of one-dimensional electron systems is extended to finite tempera...
We extend a recently proposed non-local and non-covariant version of the Thirring model to the finit...
We derive an intrinsically temperature-dependent approximation to the correlation grand potential fo...
We develop a general approach to calculating "nonuniversal" prefactors in static and dynamic correla...
We investigate proposals of how the form factor approach to compute correlation functions at zero te...
We present a new approach to the static finite temperature correlation functions of the Heisenberg c...
We calculate the two-particle local correlation for an interacting 1D Bose gas at finite temperature...
The strictly correlated electron approach to density functional theory, first proposed by Seidl and ...
We address the problem of calculating finite-temperature response functions of an experimentally rel...
We study the role of finite-temperature exchange-correlation functional in an ab initio molecular dy...
A general self-consistent scheme for approximating statistical operators is discussed within the con...
14 pages, 19 figuresInternational audienceWe analyze the finite-temperature effects on the phase dia...
In this review we provide a rigorous and self-contained presentation of one-body reduced density-mat...
1D spin-1/2 Fermi gas with a self-interaction allows a non-perturbative solution. Using the algebrai...
We present a phase-space method for fermionic systems, which enables simulations of the dynamics and...
The well-known bosonisation method of one-dimensional electron systems is extended to finite tempera...
We extend a recently proposed non-local and non-covariant version of the Thirring model to the finit...
We derive an intrinsically temperature-dependent approximation to the correlation grand potential fo...
We develop a general approach to calculating "nonuniversal" prefactors in static and dynamic correla...
We investigate proposals of how the form factor approach to compute correlation functions at zero te...
We present a new approach to the static finite temperature correlation functions of the Heisenberg c...
We calculate the two-particle local correlation for an interacting 1D Bose gas at finite temperature...
The strictly correlated electron approach to density functional theory, first proposed by Seidl and ...
We address the problem of calculating finite-temperature response functions of an experimentally rel...
We study the role of finite-temperature exchange-correlation functional in an ab initio molecular dy...
A general self-consistent scheme for approximating statistical operators is discussed within the con...
14 pages, 19 figuresInternational audienceWe analyze the finite-temperature effects on the phase dia...
In this review we provide a rigorous and self-contained presentation of one-body reduced density-mat...
1D spin-1/2 Fermi gas with a self-interaction allows a non-perturbative solution. Using the algebrai...
We present a phase-space method for fermionic systems, which enables simulations of the dynamics and...