What is the relationship between quantum mechanics and quantum field theory?

In summary, QM is the (0+1) approximation of QFT and is described in terms of wavefunctions, while QFT is the unification of special relativity and QM and is described in terms of fields with fluctuating particles. The two theories use perturbation theory to describe interactions, but QFT includes virtual particles due to its fluctuating fields. While QM is based on a fixed number of particles, QFT allows for creation and annihilation of particles. The term "relativistic quantum mechanics" used to refer to Dirac's theory, but QFT is the true unification of QM and special relativity. The inclusion of special relativity in QFT is important and cannot be reduced to just
  • #1
Son Goku
113
21
I've read on a few websites, as well as having heard from my professors that the relation between QM and QFT is that QM is the (0+1) approximation of QFT.

Does mean that QM ignores the spatial degrees of freedom of field, or is there something else to it, or have I got it all completely wrong.

Basically I'm asking in what situations does QFT reduce to QM.
 
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  • #2
Son Goku said:
I've read on a few websites, as well as having heard from my professors that the relation between QM and QFT is that QM is the (0+1) approximation of QFT.
Does mean that QM ignores the spatial degrees of freedom of field, or is there something else to it, or have I got it all completely wrong.
Basically I'm asking in what situations does QFT reduce to QM.

QFT is the unification of special relativity and QM.

In QM the basic ingredient are wavefunctions.
In QFT the basic ingredient are fields of which the fluctuations correspond to particles.

To describe interactions one uses perturbation theory (in the case of a small coupling constant, ie interactions are not too strong) in both theories. When going from the initial state (just before the interaction) to the final state (just after the interaction) one passes through the socalled intermediate states. These states violate the HUP for a very short while. In QM, the virtual states really are just a sequence of possible states one has to pass in order to go from the initial state to the final state. In QFT, these states correspond to virtual particles because these states are described in terms of fluctuating fields.

Take out the special relativity part and you are back in QM, if the number of particles in the quantumstate remains fixed. Read the EDIT

regards
marlon

EDIT : i forgot to add this : In quantum mechanics, physics is described in terms of wavefunctions that correspond to quantum states of a system. It is important to realize that there is a basic demand for this theory to work : a fixed number of particles. However, for the systems in which particles are created and destroyed, the above demand is not respected. Well, the solution is the introduction of quantum field theory, ie : second quantization...So the first quantization goes from classical field theory to QM (with fixed amount of particles) and the second quantization goes from QM to QFT (variable amount of particles through creation and annihilation.)

In short : classical field -->"first quantization" -->wavefunction (QM)--> "second quantization" --> Quantum fields (QFT)
 
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  • #3
And what about the QFT treatment of BCS? Hardly uses a relativistic quantum field. Condensed matter uses non-relativistic quantum fields all the time.
 
  • #4
marlon said:
Take out the special relativity part and you are back in QM
regards
marlon
Thanks very much for the quick reply.
Just with regard to your last point, I've heard of texts refer to relativistic quantum mechanics, is this a combination of QM and SR which still leaves you with QM, but is flawed in some manner, so you need to introduce QFT anyway?

In other words you can combine QM and SR into relativistic QM, but their true unification is QFT.
 
  • #5
Lonewolf said:
And what about the QFT treatment of BCS? Hardly uses a relativistic quantum field. Condensed matter uses non-relativistic quantum fields all the time.

Indeed, in order to answer i wrote an EDIT in my first post.

marlon
 
  • #6
marlon said:
Indeed, in order to answer i wrote an EDIT in my first post.
marlon

And an excellent answer it was :smile:
 
  • #7
Son Goku said:
Thanks very much for the quick reply.
Just with regard to your last point, I've heard of texts refer to relativistic quantum mechanics, is this a combination of QM and SR which still leaves you with QM, but is flawed in some manner, so you need to introduce QFT anyway?
What texts ? It is difficult to answer this question if i do not have the context within which such a statement is made.

Again, it is not just that QFT = QM + special relativity. Read the EDIT in my first post. There is this important aspect of "fixed number of particles in a quantumstate". Bsides creation and annihilation operators exist both in QM and QFT, but in QM they raise or lower the energy of a state, in QFT these operators actually can create an extra electron (this does NOT happen in QM) for example. This happens in beta decay and also explains why beta decay CANNOT be explained in terms of QM.


marlon
 
  • #8
The phrase "relativistic quantum mechanics" used to be applied to Dirac's theory.
 
  • #9
selfAdjoint said:
The phrase "relativistic quantum mechanics" used to be applied to Dirac's theory.
Yes, Dirac's equation was being referred to.
That explains it, thanks.

marlon said:
Again, it is not just that QFT = QM + special relativity. Read the EDIT in my first post. There is this important aspect of "fixed number of particles in a quantumstate". Bsides creation and annihilation operators exist both in QM and QFT, but in QM they raise or lower the energy of a state, in QFT these operators actually can create an extra electron (this does NOT happen in QM) for example. This happens in beta decay and also explains why beta decay CANNOT be explained in terms of QM.
Sorry, I made my post before you made your edit.
Thanks for the addition it makes more sense now.
 
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1. What is the difference between quantum mechanics (QM) and quantum field theory (QFT)?

QM is a theoretical framework that describes the behavior of particles on a microscopic scale, while QFT is a theoretical framework that describes the behavior of fields on a microscopic scale. QFT is an extension of QM that takes into account the effects of relativity and allows for the description of particles as excitations of underlying fields.

2. How are QM and QFT related?

QM and QFT are closely related as QFT builds upon the concepts and principles of QM. QFT incorporates the principles of QM, such as superposition and uncertainty, into its framework while also incorporating the principles of relativity.

3. Can QM and QFT be used to describe the same physical phenomena?

Yes, QM and QFT can both be used to describe the same physical phenomena, but they do so at different levels of description. QM provides a more fundamental description of particles, while QFT provides a more complete description that includes the effects of relativity.

4. Are there any limitations to QFT that QM does not have?

One limitation of QFT is that it is difficult to apply to systems with strong interactions, such as those found in high energy physics. QM, on the other hand, can be applied to a wider range of systems, including those with strong interactions.

5. How has the study of QM and QFT advanced our understanding of the universe?

The study of QM and QFT has greatly advanced our understanding of the universe by providing a theoretical framework for understanding the behavior of particles and fields at a microscopic scale. It has also led to the development of technologies such as transistors and lasers, which have greatly impacted our daily lives.

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