Mathematical state of Path Integral?

In summary, the conversation discusses the use of path integral methods in quantum field theory and string theory. It is mentioned that while these methods have limitations in terms of mathematical rigor, advancements in mathematics are helping to address these issues. However, it is noted that this requires a deeper understanding of non-trivial mathematics. Additional sources, such as the path integral in Euclidean field theory and the Osterwalder-Schrader theorem, are recommended for further exploration.
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So I've just recently started learning path integral methods in QFT and string theory, and I've heard from numerous sources that the path integral (specifically fermionic path integrals, perhaps?) are objects which are not at all on solid mathematical ground. The feeling I get is that perhaps they're well enough understood for the kind of specific situations in physics, but lack generality. It seems Feynman discovered some phenomenal new mathematical landscape that no mathematicians had yet seen, much less understood.

I'm wondering whether this is all accurate. And moreover, what about random surfaces in string theory? It seems there is very shaky mathematical rigour for integrating over topologies and embeddings.
 
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Related to Mathematical state of Path Integral?

1. What is the mathematical basis of Path Integral?

The mathematical basis of Path Integral is rooted in the principles of quantum mechanics and statistical mechanics. It involves the use of functional integrals and the summation over all possible paths taken by a particle between two points in space and time.

2. How is Path Integral used in physics?

Path Integral is used to calculate the probability of a particle moving from one state to another in quantum systems. It is also used to study the behavior of particles in various physical systems, such as quantum field theory and statistical mechanics.

3. Can Path Integral be applied to classical systems?

Yes, Path Integral can be applied to classical systems as well. In classical physics, it is used to calculate the probability of a particle moving between two points in space and time, similar to its use in quantum mechanics.

4. How does Path Integral differ from other mathematical approaches?

Path Integral is a unique mathematical approach as it takes into account the contribution of all possible paths a particle can take, rather than just the most probable path. It also provides a way to incorporate quantum mechanical effects into classical systems.

5. What are some practical applications of Path Integral?

Path Integral has many practical applications in physics, such as calculating the scattering amplitudes of particles, studying the behavior of particles in a potential, and simulating quantum systems on a computer. It also has applications in other fields, such as finance and biology.

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