From quantum field theory to quantum mechanics

In summary, references on quantum mechanics can vary depending on the definition used. In the broad definition, quantum mechanics is a general theory that includes quantum field theory. In the narrow definition, quantum mechanics is a specific theory that describes systems with fixed numbers of particles. The "dressed particle" formalism can explain how the traditional quantum mechanics arises from the more general quantum field theory. Some recommended sources for further reading on this topic include the paper by Greenberg and Schweber and the book "Quantum Field Theory in a Nutshell" by Zee. Additionally, Feynman's Path Integral text is also a good reference, although it may be difficult to obtain.
  • #1
luxxio
44
0
i need references on the topics. thanx
 
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  • #2
luxxio,

the answer depends on your definition of the term "quantum mechanics". There is a broad definition of this term and a narrow one.

In the broad definition "quantum mechanics" is a theory operating with Hilbert spaces, wave functions, Hermitian operators, etc. In this case, there is no separation between QFT and QM. QFT is simply a particular case of the general quantum mechanical formalism.

In the narrow definition "quantum mechanics" is a quantum theory describing systems with fixed numbers of particles. In this case the answer is not that simple, because the number of ("bare") particles in any QFT system (including the vacuum and 1-particle systems) is changing all the time: virtual particles and pairs are constantly emitted and absorbed. The best explanation of how the traditional QM with fixed number of particles follows from the QFT (where the number of particles is not fixed) can be found in the "dressed particle" formalism:

O. W. Greenberg and S. S. Schweber, "Clothed particle operators in simple models of quantum field theory", Nuovo Cim. 8 (1958), 378.

You can use Google Scholar to find more recent references to this rather old idea.
 
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  • #3
If you want the path integral counterpart to the Schrodinger Equation from the transition amplitude of QFT, see Chapter 1 of Zee, A.: Quantum Field Theory in a Nutshell. Princeton University Press, Princeton (2003).
 
  • #5
RUTA said:
If you want the path integral counterpart to the Schrodinger Equation from the transition amplitude of QFT, see Chapter 1 of Zee, A.: Quantum Field Theory in a Nutshell. Princeton University Press, Princeton (2003).

I picked up that book just the other day and I agree that it is a good introductory source from what I have seen of the first couple of chapters. Feynman's Path Integral text is also a very good reference but it seems that it only had one printing so it may be difficult to get.
 

1. What is the difference between quantum field theory and quantum mechanics?

Quantum field theory is a theoretical framework that combines quantum mechanics and special relativity to describe the behavior of subatomic particles. It is a more advanced and comprehensive theory compared to quantum mechanics, which only deals with individual particles and their interactions.

2. How does quantum field theory explain the behavior of particles?

Quantum field theory explains the behavior of particles by treating them as excitations of underlying quantum fields. These fields permeate all of space and interact with each other, giving rise to the observed particles and their properties.

3. Can quantum field theory be used to explain macroscopic phenomena?

While quantum field theory is primarily used to describe the behavior of subatomic particles, it can also be applied to macroscopic phenomena. For example, it has been used to explain superconductivity and the behavior of superfluids.

4. What are some real-world applications of quantum field theory?

Quantum field theory has numerous applications, including in particle physics, condensed matter physics, and cosmology. It is also used in the development of technologies such as transistors, lasers, and magnetic resonance imaging (MRI).

5. Is quantum field theory a complete theory?

Currently, quantum field theory is the most complete and accurate theory we have for describing the behavior of subatomic particles. However, it is not a complete theory of everything, and there are still unanswered questions and areas for further research, such as the unification of quantum mechanics and general relativity.

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