Book contents
- Frontmatter
- Contents
- Introduction
- 1 Vector spaces
- 2 Operators in Hilbert spaces
- 3 Tensor algebras
- 4 Analysisin L2 (ℝd)
- 5 Measures
- 6 Algebras
- 7 Anti-symmetric calculus
- 8 Canonical commutation relations
- 9 CCR on Fock space
- 10 Symplectic invariance of CCR in finite-dimensions
- 11 Symplectic invariance of the CCR on Fock spaces
- 12 Canonical anti-commutation relations
- 13 CAR on Fock spaces
- 14 Orthogonal invariance of CAR algebras
- 15 Clifford relations
- 16 Orthogonal invariance of the CAR on Fock spaces
- 17 Quasi-free states
- 18 Dynamics of quantum fields
- 19 Quantum fields on space-time
- 20 Diagrammatics
- 21 Euclidean approach for bosons
- 22 Interacting bosonic fields
- References
- Symbols index
- Subject index
20 - Diagrammatics
- Frontmatter
- Contents
- Introduction
- 1 Vector spaces
- 2 Operators in Hilbert spaces
- 3 Tensor algebras
- 4 Analysisin L2 (ℝd)
- 5 Measures
- 6 Algebras
- 7 Anti-symmetric calculus
- 8 Canonical commutation relations
- 9 CCR on Fock space
- 10 Symplectic invariance of CCR in finite-dimensions
- 11 Symplectic invariance of the CCR on Fock spaces
- 12 Canonical anti-commutation relations
- 13 CAR on Fock spaces
- 14 Orthogonal invariance of CAR algebras
- 15 Clifford relations
- 16 Orthogonal invariance of the CAR on Fock spaces
- 17 Quasi-free states
- 18 Dynamics of quantum fields
- 19 Quantum fields on space-time
- 20 Diagrammatics
- 21 Euclidean approach for bosons
- 22 Interacting bosonic fields
- References
- Symbols index
- Subject index
Summary
The diagrammatic method is one of the most powerful tools of theoretical physics. It allows us to efficiently organize perturbative computations in statistical physics, quantum many-body theory and quantum field theory. The main feature of this method is a representation of individual terms of a perturbative expansion as diagrams (graphs). Diagrams consist of vertices representing terms in the perturbation, lines representing pairings between vertices and, possibly, external legs.
There exist several kinds of diagrams. We will try to present them in a systematic way.
In Sect. 20.1 we present a diagrammatic formalism whose goal is to organize integration of polynomials with respect to a Gaussian measure. This formalism is used extensively in classical statistical physics. It also plays an important role in quantum physics, especially in the Euclidean approach, since many quantum quantities can be expressed in terms of Gaussian integrals over classical variables.
We use the term “Gaussian integration” in a rather broad sense. Beside commuting “bosonic” variables, we also consider anti-commuting “fermionic” variables, where we use the Berezin integral with respect to a Gaussian weight. Even in the case of commuting variables, the “Gaussian integral” is not necessarily meant in the sense of measure theory. It denotes an algebraic operation performed on polynomials (or formal power series), which in the case of a positive definite covariance coincides with the usual integral with a Gaussian weight. However, we allow the covariance to be complex, or even negative definite, and do not insist that the operation have a measure theoretic meaning.
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- Information
- Mathematics of Quantization and Quantum Fields , pp. 555 - 604Publisher: Cambridge University PressPrint publication year: 2013