Particle number conservation and motivations for QFT

In summary, the conversation discusses the motivation for the need for quantum field theory (QFT) due to the inability of quantum mechanics to account for particle creation/annihilation, which is predicted by special relativity. To construct a fully consistent relativistic quantum theory, one must account for such phenomena, leading to the development of QFT. It is uncertain if QM can treat scenarios with a variable number of particles due to the continuity equation and implications of special relativity, and the inclusion of mathematics is necessary for a full understanding. The Klein paradox and Dirac equation are also mentioned as related topics. Srednicki's QFT book and a paper on relativistic quantum mechanics are recommended
  • #1
Frank Castle
580
23
I've read that one of the primary motivations for the need for QFT is that quantum mechanics cannot account for particle creation/annihilation, however special relativity "predicts" that such phenomena are possible (clearly they have been observed experimentally, but I'm going for a heuristic explanation for motivating QFT here). Hence, if one wishes to construct a fully consistent relativistic quantum theory, one must account for such phenomena, which naturally leads to the construction of QFT.

If this is correct, then there are a couple of things that I'm slightly unsure about.

Firstly, is the reason why quantum mechanics cannot treat scenarios in which there are a variable number of particles because of the the continuity equation: $$\frac{\partial}{\partial t}(\langle\psi\vert\psi\rangle) +\nabla\cdot\mathbb{j}=0$$ which implies conservation of particle number (I think it's correct to say that it is derived by assuming that no particles can be created or annihilated)?

Secondly, in what sense does special relativity "predict" that particle creation/annihilation should be possible? Is it implied by the energy dispersion relation $$E^2=m^2c^4+p^2c^2$$ so if the system has enough energy it can create a particle of mass ##m## from the vacuum?! Does it also come from Dirac's construction of a relativistic equation of motion (the Dirac equation) which predicts the existence of the positron which itself can annihilate with the electron?
 
Physics news on Phys.org
  • #2
https://en.wikipedia.org/wiki/Klein_paradox

is a nice prelude to QFT

Furthermore, time and space are not treated on equal "footing" in non-rel QM. Time is not an operator in QM, it is just a label

If you give heuristically arguments for QFT, then the answers must be heuristic as well :)
 
  • #3
malawi_glenn said:
https://en.wikipedia.org/wiki/Klein_paradox

is a nice prelude to QFT

Furthermore, time and space are not treated on equal "footing" in non-rel QM. Time is not an operator in QM, it is just a label

If you give heuristically arguments for QFT, then the answers must be heuristic as well :)

Thanks for the link.

I get the reasoning from the point of treating space and time "on equal footing" a la relativity. What I don't fully understand is the reasoning from issues such as particle number (non) conservation, creation/annihilation of particles. (I don't mind the inclusion of mathematics in the explanation by the way :wink:)
 
  • #4
People tried to reformulate QM in terms of relativistic wave-equations, the Klein Equation and the Dirac Equation.

The paradox I linked to is related to the Klein Equation, which shows that probability is not conserved. Furthermore, you can examine the causality of the solutions to the Klein Equation and see that they do not respect causality (you have non-zero probability density outside the light-cone)

Here is a link to a "paper" I wrote many years ago in a course i took on relativistic quantum mechanics. It contains a mathematical treatment of the Klein Paradox
https://www.dropbox.com/s/ajoohwff2xvr8vf/RelativisticQM_handin.pdf?dl=0

The first chapters in Srednickis QFT book is also quite nice. Here you can find a draft of the book on his homepage http://web.physics.ucsb.edu/~mark/ms-qft-DRAFT.pdf
 
  • #5
malawi_glenn said:
People tried to reformulate QM in terms of relativistic wave-equations, the Klein Equation and the Dirac Equation.

The paradox I linked to is related to the Klein Equation, which shows that probability is not conserved. Furthermore, you can examine the causality of the solutions to the Klein Equation and see that they do not respect causality (you have non-zero probability density outside the light-cone)

Here is a link to a "paper" I wrote many years ago in a course i took on relativistic quantum mechanics. It contains a mathematical treatment of the Klein Paradox
https://www.dropbox.com/s/ajoohwff2xvr8vf/RelativisticQM_handin.pdf?dl=0

The first chapters in Srednickis QFT book is also quite nice. Here you can find a draft of the book on his homepage http://web.physics.ucsb.edu/~mark/ms-qft-DRAFT.pdf

Ah, ok. Thanks for the references, I'll take a look and get back if I have further questions (if that's ok?!)
 
  • #6
Sure post here and more people can contribute and benefit :)
 
  • #7
malawi_glenn said:
Sure post here and more people can contribute and benefit :)

I have since had a chance to read through the first few chapters of Srednicki's QFT book, and whilst enlightening, it still doesn't provide a satisfactory explanation as to why QM+SR implies that particle number is not conserved (is this because of the mass-energy equivalence in SR and so if there is sufficient energy then particles can be created, and conversely, mass can be converted into energy implying particle destruction), and also why one can't use QM to describe systems in which there are a variable number of particles (is it because in QM we describe multi-particle states in terms of products of single-particle states and if the system has varying numbers of particles then it is not possible to do this?)
 
  • #8
Isn't it possible to have a nonrelativistic quantum field describing crystal vibrations, where phonon number isn't conserved?
 
  • #9
hilbert2 said:
Isn't it possible to have a nonrelativistic quantum field describing crystal vibrations, where phonon number isn't conserved?

From what I've read, there is no mechanism in standard non-relativistic quantum mechanics to deal with changes in the particle number. Equations in quantum mechanics are always written for fixed numbers of particles (Indeed, the continuity equation implies that particle number is conserved).
 
  • #10
^ Yes, we can't define a wave function unless we know how many variables that function depends on, and the number of variables in 3D space is three times the number of particles (ignoring spin variables). But I still don't think that you necessarily need a relativistic system to have a non-constant number of quasiparticles such as phonons.

http://eduardo.physics.illinois.edu/phys582/582-chapter6.pdf
 
  • #11
hilbert2 said:
^ Yes, we can't define a wave function unless we know how many variables that function depends on, and the number of variables in 3D space is three times the number of particles (ignoring spin variables). But I still don't think that you necessarily need a relativistic system to have a non-constant number of quasiparticles such as phonons.

http://eduardo.physics.illinois.edu/phys582/582-chapter6.pdf

Is the point here though that one has to deviate from standard quantum mechanics (in which products of single-particle Hilbert spaces are used to construct multi-particle wavefunctions) and introduce the notion of a Fock space to account for the changing number of particles?
 
  • #12
^ Yes, you need the Fock space to do that.
 
  • #13
hilbert2 said:
Isn't it possible to have a nonrelativistic quantum field describing crystal vibrations, where phonon number isn't conserved?
Frank Castle said:
From what I've read, there is no mechanism in standard non-relativistic quantum mechanics to deal with changes in the particle number. Equations in quantum mechanics are always written for fixed numbers of particles (Indeed, the continuity equation implies that particle number is conserved).
Quantum field theories allow for a variable number of particles which makes them a good starting point for a relativistic theory, but they don't have to be relativistic. There's a good example, the field-theoretical treatment of an array of coupled harmonic oscillators, towards the beginning of Lancaster's "Quantum field theory for the gifted amateur". You may find that this book is a better starting point than Srednicki.
 
  • #14
Nugatory said:
Quantum field theories allow for a variable number of particles which makes them a good starting point for a relativistic theory, but they don't have to be relativistic. There's a good example, the field-theoretical treatment of an array of coupled harmonic oscillators, towards the beginning of Lancaster's "Quantum field theory for the gifted amateur". You may find that this book is a better starting point than Srednicki.

Thanks for the recommendation, I shall take a look.

Does one need field theory, whether relativistic or not, then to describe cases in which the particle number varies?

Is the point also that in single-particle quantum mechanics is not compatible with relativity since it violates causality (there is a small, but non-zero amplitude for the particle to exist outside its forward light-cone)?! (Also, the energy-uncertainty relation along with the relativistic energy-dispersion relation implies that pair production can occur even in the case where there was originally one particle present)
 
Last edited:
  • #15
hilbert2 said:
Isn't it possible to have a nonrelativistic quantum field describing crystal vibrations, where phonon number isn't conserved?
Of course, you can as well formulate nonrelativistic QFT, and that's what condensed-matter physicists do nowadays all the time. Phonons are the vibrations of the crystal lattice, and in the QFT description they appear as particle-like excitations. That's why they are also called quasiparticles. There are tons of interesting quasiparticles in condensed-matter theory, including very exotic stuff like magnetic monopoles, Weyl fermions, etc.
 
  • #16
I am not sure if I understand, at a deep level, why relativity would imply the possibility of particle non-conservation, but treating space and time on an equal footing intuitively makes it compelling to me.

The following diagrams aren't seriously meant to be Feynman diagrams--they're just visual illustrations of processes involving particles. On the picture on the left, we have a pretty unremarkable process: An electron (marked by the solid line) is hit by a photon (marked by the wavy line) and is deflected. In the diagram, time is vertical and the one spatial dimension is the horizontal axis.

Now the diagram on the right is the same process, "rotated" in spacetime. In this diagram, the same process is described by: Originally, (in the bottom of the diagram), there is only a photon. At some point, the photon produces an electron-positron pair. So pair production and deflection of an electron by a photon are closely related processes. (In actuality, these simple processes have zero amplitude, because there is no way to get energy/momentum to balance for a single photon to split into an electron/positron pair.)
crossing2.jpg
 
  • Like
Likes kith
  • #17
Frank Castle said:
Does one need field theory, whether relativistic or not, then to describe cases in which the particle number varies?

I think that there is a sense in which many-particle quantum mechanics simply is field theory, if you drop the restriction on particle conservation.
 
  • #18
stevendaryl said:
I am not sure if I understand, at a deep level, why relativity would imply the possibility of particle non-conservation, but treating space and time on an equal footing intuitively makes it compelling to me.

The following diagrams aren't seriously meant to be Feynman diagrams--they're just visual illustrations of processes involving particles. On the picture on the left, we have a pretty unremarkable process: An electron (marked by the solid line) is hit by a photon (marked by the wavy line) and is deflected. In the diagram, time is vertical and the one spatial dimension is the horizontal axis.

Now the diagram on the right is the same process, "rotated" in spacetime. In this diagram, the same process is described by: Originally, (in the bottom of the diagram), there is only a photon. At some point, the photon produces an electron-positron pair. So pair production and deflection of an electron by a photon are closely related processes. (In actuality, these simple processes have zero amplitude, because there is no way to get energy/momentum to balance for a single photon to split into an electron/positron pair.)

So is the point that, in spacetime it is quite natural, in some sense, for particle production to occur and such a phenomenon cannot be described in standard quantum mechanics?

stevendaryl said:
I think that there is a sense in which many-particle quantum mechanics simply is field theory, if you drop the restriction on particle conservation.

Is this purely because one introduces the occupation number representation of quantum states and also the notion of a Fock space to describe a varying number of particles?
 
  • #20
Frank Castle said:
I've read that one of the primary motivations for the need for QFT is that quantum mechanics cannot account for particle creation/annihilation, however special relativity "predicts" that such phenomena are possible (clearly they have been observed experimentally, but I'm going for a heuristic explanation for motivating QFT here). Hence, if one wishes to construct a fully consistent relativistic quantum theory, one must account for such phenomena, which naturally leads to the construction of QFT.

Combining QM and relativity inevitably leads to particle number not being fixed.

See section 8.3 of the following book where its carefully explained:
https://www.dur.ac.uk/physics/qftgabook/

Once that is recognized you are naturally led to QM formulation F of the equivalent formulations of QM:
http://www.colorado.edu/physics/phys5260/phys5260_sp16/lectureNotes/NineFormulations.pdf

Thanks
Bill
 
  • #21
bhobba said:
Combining QM and relativity inevitably leads to particle number not being fixed.

See section 8.3 of the following book where its carefully explained:
https://www.dur.ac.uk/physics/qftgabook/

Once that is recognized you are naturally led to QM formulation F of the equivalent formulations of QM:
http://www.colorado.edu/physics/phys5260/phys5260_sp16/lectureNotes/NineFormulations.pdf

Thanks
Bill

Thanks for the references, I shall have a read through them.
 
  • #22
bhobba said:
See section 8.3 of the following book where its carefully explained:
https://www.dur.ac.uk/physics/qftgabook/

So is the point then that if one combines single-particle quantum mechanics with special relativity one finds that the probability of finding a particle outside its forward lightcone is non-zero, hence violating causality. Furthermore, combining the Heisenberg uncertainty relation between position and momentum one finds that by localising a particle to within its Compton wavelength causes the uncertainty in the momentum of the particle to be large, implying that the spread of energy values that the particle could have is large enough that its energy can be much larger than its mass. Then, according to the relativistic energy-momentum dispersion relation, one can in principle have particle production, meaning that on average a box the size of the particles Compton wavelength will, on average, have more than a single particle within it?!
 
  • #23
Basically - yes.

But if you want to discuss that reference best to start a new thread.

Thanks
Bill
 

1. What is particle number conservation?

Particle number conservation is a fundamental principle in physics that states the total number of particles in a closed system remains constant over time. This means that particles cannot be created or destroyed, only transformed into different types of particles. This concept is important in quantum field theory (QFT) as it helps to explain the behavior of particles and their interactions.

2. How does QFT explain particle number conservation?

QFT is a theoretical framework that combines quantum mechanics and special relativity to describe the behavior of particles at a subatomic level. In QFT, particles are represented as excitations of underlying fields, and the conservation of particle number is explained by the invariance of the underlying equations of motion. This means that the total number of particles remains constant because the equations that govern their behavior do not change over time.

3. What are some motivations for studying QFT?

There are several motivations for studying QFT, including its ability to explain the behavior of particles at a subatomic level, its use in high-energy physics and particle accelerators, and its applications in fields such as condensed matter physics and cosmology. QFT also provides a more complete and consistent framework for understanding the fundamental forces of nature, such as electromagnetism and the strong and weak nuclear forces.

4. Can particle number conservation be violated?

In certain circumstances, particle number conservation can appear to be violated. For example, in particle collisions, particles can be created or destroyed, seemingly violating the principle. However, these processes are balanced by an equal number of particles being created or destroyed in the opposite direction, conserving the total number of particles. This is known as "pair production" and is allowed by the laws of quantum mechanics.

5. How is particle number conservation related to other conservation laws?

Particle number conservation is related to other conservation laws, such as energy and momentum conservation, through the principles of symmetry and invariance. These laws are all connected by the concept of Noether's theorem, which states that for every continuous symmetry in a physical system, there is a corresponding conservation law. In the case of particle number conservation, it is related to the symmetry of the equations of motion in QFT.

Similar threads

Replies
18
Views
3K
Replies
7
Views
1K
Replies
2
Views
1K
  • Quantum Physics
4
Replies
113
Views
6K
Replies
26
Views
2K
  • Quantum Physics
Replies
13
Views
3K
  • Quantum Physics
3
Replies
87
Views
5K
Replies
6
Views
1K
  • Quantum Physics
2
Replies
69
Views
4K
Back
Top