Add to ORKGIn these lectures we introduce the Feynman-Schwinger representation method for solving nonperturbative problems in field theory. As an introduction we first give a brief overview of integral equations and path integral methods for solving nonperturbative problems. Then we discuss the Feynman-Schwinger (FSR) representation method with applications to scalar interactions. The FSR approach is a continuum path integral integral approach in terms of covariant trajectories of particles. Using the exact results provided by the FSR approach we test the reliability of commonly used approximations for nonperturbative summation of interactions for few body systems
Dyson-Schwinger equations furnish a Poincare' covariant framework within which to study hadrons. A p...
We describe the application of Dyson-Schwinger equations to the calculation of hadron observables. T...
Dyson-Schwinger equations are integral equations in quantum field theory that describe the Green fun...
In nuclear and particle physics one is often faced with problems where perturbation theory is not ap...
The Feynman-Schwinger representation provides a convenient framework for the cal culation of nonpert...
The Feynman-Schwinger representation provides a convenient framework for the calculation of nonpertu...
Perturbation series for the electron propagator in the Schwinger Model is summed up in a direct way ...
Abstract: The proper time path integral representation is derived explicitly for an arbitrary $n$-po...
Published in: Ann. Phys. 300 (2002) 54-87 citations recorded in [Science Citation Index] Abstract: T...
The paper studies the behavior of equations of motions of Green’s functions under different running ...
A knowledge of nonpertubative propagators is often needed when the standard perturbative methods are...
We write the 4-point Green function in QCD in the Feynman-Schwinger representation and show that all...
We solve the massless Schwinger model exactly in Hamiltonian formalism on a circle. We construct ph...
We review some recent developments in nonperturbative studies of quantum field theory (QFT) using th...
The proper time path integral representation is derived explicitly for Green's functions in QCD. Aft...
Dyson-Schwinger equations furnish a Poincare' covariant framework within which to study hadrons. A p...
We describe the application of Dyson-Schwinger equations to the calculation of hadron observables. T...
Dyson-Schwinger equations are integral equations in quantum field theory that describe the Green fun...
In nuclear and particle physics one is often faced with problems where perturbation theory is not ap...
The Feynman-Schwinger representation provides a convenient framework for the cal culation of nonpert...
The Feynman-Schwinger representation provides a convenient framework for the calculation of nonpertu...
Perturbation series for the electron propagator in the Schwinger Model is summed up in a direct way ...
Abstract: The proper time path integral representation is derived explicitly for an arbitrary $n$-po...
Published in: Ann. Phys. 300 (2002) 54-87 citations recorded in [Science Citation Index] Abstract: T...
The paper studies the behavior of equations of motions of Green’s functions under different running ...
A knowledge of nonpertubative propagators is often needed when the standard perturbative methods are...
We write the 4-point Green function in QCD in the Feynman-Schwinger representation and show that all...
We solve the massless Schwinger model exactly in Hamiltonian formalism on a circle. We construct ph...
We review some recent developments in nonperturbative studies of quantum field theory (QFT) using th...
The proper time path integral representation is derived explicitly for Green's functions in QCD. Aft...
Dyson-Schwinger equations furnish a Poincare' covariant framework within which to study hadrons. A p...
We describe the application of Dyson-Schwinger equations to the calculation of hadron observables. T...
Dyson-Schwinger equations are integral equations in quantum field theory that describe the Green fun...