Abstract
This paper derives the Feynman rules for the diagrammatic perturbation expansion of the effective action around an arbitrary solvable problem. The perturbation expansion around a Gaussian theory is well-known and composed of one-line irreducible diagrams only. For the expansions around an arbitrary, non-Gaussian problem, we show that a more general class of irreducible diagrams remains in addition to a second set of diagrams that has no analogue in the Gaussian case. The effective action is central to field theory, in particular to the study of phase transitions, symmetry breaking, effective equations of motion, and renormalization. We exemplify the method on the Ising model, where the effective action amounts to the Gibbs free energy, recovering the Thouless–Anderson–Palmer mean-field theory in a fully diagrammatic derivation. Higher order corrections follow with only minimal effort compared to existing techniques. Our results show further that the Plefka expansion and the high-temperature expansion are special cases of the general formalism presented here.
Highlights
Many-particle systems are of interest in various fields of physics
We exemplify the method on the Ising model, where the effective action amounts to the Gibbs free energy, recovering the Thouless– Anderson–Palmer mean-field theory in a fully diagrammatic derivation
We here choose a notation that should be transparent with regard to the nature of the problem: our results transfer to classical statistical mechanics, quantum mechanics, quantum statistics, or quantum field theory
Summary
Many-particle systems are of interest in various fields of physics. Field theory offers a versatile unique language to describe such systems and powerful methods to treat diverse problems arising in classical statistical mechanics, quantum mechanics, quantum statistics, quantum. Field theory, and stochastic dynamical systems [1,2,3,4,5]. Diagrammatic techniques in particular are convenient and efficient to organize practical calculations that arise in the context of systematic perturbation expansions and fluctuation expansions around a solvable problem. The purpose of this paper is to extend the diagrammatic computation of a central quantity, the effective action Γ, beyond this Gaussian case
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