On the classical action in Feynman approach

In summary, the Feynman approach to quantum field theory uses a classical action to calculate amplitudes, functional derivatives, and other outcomes of quantum field-theoretic processes. The approach is limited to bosons, which are not as classical as fermions. Actions that are physically meaningful in QFT are based on gauge symmetry. However, there are cases in which actions are not based on classical symmetry.
  • #1
metroplex021
151
0
Hi All,

In the Feynman, 'sum over paths' approach to quantum field theory, we compute amplitudes, generating functionals etc by feeding in a "classical action".

By calling the Lagrangian that we feed in "classical", this mean that the fields that feature in that action are regarded as classical fields? (Is there even such a thing as a classical field for a proton, etc?!)

I'm quite perplexed by this, so any sage words at all would be much appreciated!
 
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  • #2
Yes, for bosons the Feynman path integral is over classical trajectories, and we rotate into imnaginary time to calculate so that it becomes a stochastic process. Whether this works in quantum mechanics - ie. is meaningful in terms of Hilbert spaces, operators etc - is governed by the Osterwalder-Schrader conditions. http://www.einstein-online.info/spotlights/path_integrals. There are more comments on these conditions on p17-18 of http://www.rivasseau.com/resources/book.pdf.

For fermions, one has to use a Grassmann variables, which are not so classical.
 
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  • #3
Atyy, thank you very much for your answer and for the reference to the OS conditions. I have one more question in case you happen to know the answer to this too.

In the Feynman approach, we feed in a classical action in order to calculate outcomes of quantum field-theoretic processes. Is there an approach to QFT in which one has a *non*-classical action -- a Lagrangian that is itself explicitly quantum field-theoretic? (I appreciate this is a weird question, but if you have any input I'd appreciate it very much!)

Thanks again.
 
  • #4
metroplex021 said:
Is there an approach to QFT in which one has a *non*-classical action -- a Lagrangian that is itself explicitly quantum field-theoretic? (I appreciate this is a weird question, but if you have any input I'd appreciate it very much!)

In QFT the actions, just like classical physics, are constrained by symmetry - eg QED is based on gauge symmetry. Because of that actions are often the same or similar.

But often is not always, for example the actions found in QCD do not have a classical analogue, being based on Yang-Mills fields of which EM is just a simple example.

Thanks
Bill
 

What is the classical action in Feynman approach?

The classical action in Feynman approach is a mathematical concept used in quantum field theory to describe the behavior of a physical system. It is calculated by integrating the Lagrangian, which is a function that describes the dynamics of the system, over a certain period of time.

How is the classical action related to quantum mechanics?

The classical action is a fundamental concept in quantum field theory, which is the mathematical framework used to describe quantum mechanics. In quantum field theory, the classical action is used to calculate the probability amplitudes for different paths that a particle can take in a physical system.

What is the significance of the classical action in Feynman approach?

The classical action plays a crucial role in the Feynman approach to quantum mechanics. It is used to calculate the probability amplitudes for different particle paths, which are then combined to determine the overall probability of a particle's behavior in a physical system. This allows for a more accurate and precise understanding of quantum phenomena.

How is the classical action calculated in Feynman approach?

The classical action is calculated by integrating the Lagrangian of a physical system over a certain period of time. This integration is typically done using the principle of least action, which states that the actual path taken by a particle is the one that minimizes the action. In Feynman approach, the classical action is then used to calculate the probability amplitudes for different particle paths.

What are some real-world applications of the classical action in Feynman approach?

The classical action in Feynman approach has many applications in modern physics, including quantum field theory, particle physics, condensed matter physics, and cosmology. It is used to study the behavior of particles and fields at both microscopic and macroscopic scales, and has contributed to our understanding of fundamental particles and forces, as well as the evolution of the universe as a whole.

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