Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 The supremum of first eigenvalues of conformally covariant operators in a conformal class
- 2 K-Destabilizing test configurations with smooth central fiber
- 3 Explicit constructions of Ricci solitons
- 4 Open Iwasawa cells and applications to surface theory
- 5 Multiplier ideal sheaves and geometric problems
- 6 Multisymplectic formalism and the covariant phase space
- 7 Nonnegative curvature on disk bundles
- 8 Morse theory and stable pairs
- 9 Manifolds with k-positive Ricci curvature
- References
6 - Multisymplectic formalism and the covariant phase space
Published online by Cambridge University Press: 05 November 2011
Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 The supremum of first eigenvalues of conformally covariant operators in a conformal class
- 2 K-Destabilizing test configurations with smooth central fiber
- 3 Explicit constructions of Ricci solitons
- 4 Open Iwasawa cells and applications to surface theory
- 5 Multiplier ideal sheaves and geometric problems
- 6 Multisymplectic formalism and the covariant phase space
- 7 Nonnegative curvature on disk bundles
- 8 Morse theory and stable pairs
- 9 Manifolds with k-positive Ricci curvature
- References
Summary
In most attempts to build the mathematical foundations of Quantum Field Theory (QFT), two classical ways have been explored. The first one is often referred to as the Feynman integral or functional integral method. It is a generalization to fields of the path integral method of quantum mechanics and is heuristically based on computing integrals over the infinite dimensional set of all possible fields Φ by using a kind of ‘measure’ – which should behave like the Lebesgue measure on the set of all possible fields Φ – times eiℒ(Φ)/ℏ, where ℒ is a Lagrangian functional (but attempts to define this ‘measure’ failed in most cases). The second one is referred to as the canonical quantization method and is based on the Hamiltonian formulation of the dynamics of classical fields, by following general axioms which were first proposed by Dirac and later refined. The Feynman approach has the advantage of being manifestly relativistic, i.e. it does not require the choice of a particular system of space-time coordinate, since the main ingredient is ℒ(Φ), which is an integral over all space-time. By contrast, the canonical approach, at least its classical formulation, seems to be based on the choice of a particular time coordinate which is needed to define the Hamiltonian function through an infinite dimensional Legendre transform.
However there are alternative formulations of the Hamiltonian structure of the dynamics of classical fields, which could be used as a starting point of a covariant canonical quantization.
- Type
- Chapter
- Information
- Variational Problems in Differential Geometry , pp. 94 - 126Publisher: Cambridge University PressPrint publication year: 2011
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