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| related topics |
| {equation, function, exp} |
| {force, casimir, field} |
| {phase, path, phys} |
| {operator, operators, space} |
| {field, particle, equation} |
| {classical, space, random} |
| {particle, mechanics, theory} |
| {group, space, representation} |
| {energy, gaussian, time} |
| {time, systems, information} |
| {theory, mechanics, state} |
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Path integrals and boundary conditions
M. Asorey, A. Ibort, G. Marmo
abstract: The path integral approach to quantum mechanics provides a method of
quantization of dynamical systems directly from the Lagrange formalism. In
field theory the method presents some advantages over Hamiltonian quantization.
The Lagrange formalism preserves relativistic covariance which makes the
Feynman method very convenient to achieve the renormalization of field theories
both in perturbative and non-perturbative approaches. However, when the systems
are confined in bounded domains we shall show that the path integral approach
does not describe the most general type of boundary conditions. Highly
non-local boundary conditions cannot be described by Feynman's approach. We
analyse in this note the origin of this problem in quantum mechanics and its
implications for field theory.
- oai_identifier:
- oai:arXiv.org:quant-ph/0609023
- categories:
- quant-ph hep-th
- comments:
- 10 pages, 1 figure. Proceedings of the Meeting on Fundamental Physics
'A. Galindo', Eds. R.F. Alvarez-Estrada et al, Madrid (2004)
- arxiv_id:
- quant-ph/0609023
- created:
- 2006-09-04
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