Abstract Both nonzero temperature and chemical potentials break the Lorentz symmetry present in vacuum quantum field theory by singling out the rest frame of the heat bath. This leads to complications in the application of thermal perturbation theory, including the appearance of novel infrared divergences in loop integrals and an apparent absence of four-dimensional integration-by-parts (IBP) identities, vital for high-order computations. Here, we propose a new strategy that enables the use of IBP techniques in the evaluation of Feynman integrals, in particular vacuum or bubble diagrams, in the limit of vanishing temperature T but nonzero chemical potentials μ. The central elements of the new setup include a contour representation for the t...
In this article an introduction to the thermal field theory within imaginary time vis-a-vis Matsubar...
It is known one may use Feynman’s path integral approach to solve for a quantum propagator. Setting ...
Bödeker D, McLerran L, Smilga A. Really Computing Nonpertubative Real Time Correlation Functions. Ph...
We discuss the prospects of performing high-order perturbative calculations in systems characterized...
The technique of decomposing Feynman diagrams at the one loop level into elementary integrals is gen...
Nishimura M, Schroeder Y. IBP methods at finite temperature. JHEP. 2012;2012(9): 51.We demonstrate t...
In calculating Feynman diagrams at finite temperature, it is sometimes convenient to isolate subdiag...
In this thesis we present different topics in perturbation theory. We start by introducing the metho...
A projection operator, similar to one previously used by us for problems with a finite set of basis ...
We describe an algorithm to organize Feynman integrals in terms of their infrared properties. Our ap...
Path integral Monte Carlo is a proven method for accurately simulating quantum mechanical systems at...
The classical approximation provides a non-perturbative approach to time-dependent problems in finit...
Schroeder Y. Loops for Hot QCD. Nucl. Phys. Proc. Suppl. B. 2008;183:296-301.In this talk we review ...
The classical approximation provides a non-perturbative approach to time-dependent problems in finit...
For a given diagrammatic approximation in many-body perturbation theory it is not guaranteed that po...
In this article an introduction to the thermal field theory within imaginary time vis-a-vis Matsubar...
It is known one may use Feynman’s path integral approach to solve for a quantum propagator. Setting ...
Bödeker D, McLerran L, Smilga A. Really Computing Nonpertubative Real Time Correlation Functions. Ph...
We discuss the prospects of performing high-order perturbative calculations in systems characterized...
The technique of decomposing Feynman diagrams at the one loop level into elementary integrals is gen...
Nishimura M, Schroeder Y. IBP methods at finite temperature. JHEP. 2012;2012(9): 51.We demonstrate t...
In calculating Feynman diagrams at finite temperature, it is sometimes convenient to isolate subdiag...
In this thesis we present different topics in perturbation theory. We start by introducing the metho...
A projection operator, similar to one previously used by us for problems with a finite set of basis ...
We describe an algorithm to organize Feynman integrals in terms of their infrared properties. Our ap...
Path integral Monte Carlo is a proven method for accurately simulating quantum mechanical systems at...
The classical approximation provides a non-perturbative approach to time-dependent problems in finit...
Schroeder Y. Loops for Hot QCD. Nucl. Phys. Proc. Suppl. B. 2008;183:296-301.In this talk we review ...
The classical approximation provides a non-perturbative approach to time-dependent problems in finit...
For a given diagrammatic approximation in many-body perturbation theory it is not guaranteed that po...
In this article an introduction to the thermal field theory within imaginary time vis-a-vis Matsubar...
It is known one may use Feynman’s path integral approach to solve for a quantum propagator. Setting ...
Bödeker D, McLerran L, Smilga A. Really Computing Nonpertubative Real Time Correlation Functions. Ph...