The discussion revolves around the differences between fermions and bosons, particularly in the context of low temperatures and their statistical properties. Participants explore theoretical explanations for why bosons can occupy the same quantum state while fermions cannot, and how these properties manifest macroscopically. The conversation also touches on the early universe and the mechanisms by which particles acquire their characteristics.
Participants express multiple competing views on the nature of fermions and bosons, their origins, and the mechanisms involved in their statistical properties. The discussion remains unresolved regarding the specifics of symmetry breaking and the fundamental nature of these particles.
Limitations include the dependence on theoretical frameworks such as quantum field theory and the lack of empirical evidence regarding the early universe's conditions. The discussion also reflects uncertainty about the mechanisms of symmetry breaking and the transformation between fermions and bosons.
Simon Bridge said:"because that is how the Universe works" is the bottom line.
Physics does not answer "why" questions very well.
You realize that Physics is an empirical science right?
Certainly. You can have a positron and an electron which decay into a pair of photons, and you can also have the reverse.nouveau_riche said:or is there any possibility that a fermion can become a boson?
jarod765 said:So your question is about the beginning of the universe then?
Since we do not know the physics or the initial conditions of the universe at the earliest scales then we cannot certain how particles "gained" their statistical properties.
If we try and approximate using field theory however we can get an intuition about it. Here is my intuition about it:
1) In field theory particles live in representations of a symmetry group.
2) Depending on which representation it lives in then it will have either integer or non-integer spin.
3) For various technical reasons a field with integral (half-integral) spin will obey commutation (anti-commutation) relations.
4) the commutation relations make explicit which statistics a particle will obey (note: statistics implies the exclusion principle).
As for how many and what type of fermions and bosons were created at the early universe that has to do with the mechanisms of inflation and reheating processes.
DaleSpam said:Certainly. You can have a positron and an electron which decay into a pair of photons, and you can also have the reverse.
According to the spin-statistics theorem, particles with integer spin occupy symmetric quantum states, and particles with half-integer spin occupy antisymmetric states; furthermore, only integer or half-integer values of spin are allowed by the principles of quantum mechanics. In relativistic quantum field theory, the Pauli principle follows from applying a rotation operator in imaginary time to particles of half-integer spin. Since, nonrelativistically, particles can have any statistics and any spin, there is no way to prove a spin-statistics theorem in nonrelativistic quantum mechanics.
arojo said:Hi,
I think your question does not have an easy answer, the raison why bosons and fermions are different is their statistic. From this we get the fermi and bose statistic, which is related to their spin. The Pauli exclusion principle tells us that the wave function of a set of fermions must be antisymmetric and that bosons have symmetric wave functions.
The problem is that to demonstrate this amazing insight Pauli had, it is necessary to use QFT, actually there is a draft of explanation in wikipedia that I like:
Then there is a second question, about how do we see this difference macroscopically and then I would say that the most spectacular effect is the Bose-Einstein condensate. Other difference are more subtle like what happens when a fermion interacts with a boson (eg the Higgs mechanism).
Finally, you ask if we can transform bosons into fermions and vice-versa, and eventually, if I understood correctly your question is which of both is more fundamental. I am not sure that there is a positive answer for that, what I think we can say is that all the experimental results show a Universe made of boson and fermions (Standard Model) and if this model is the correct one then both fermion and bosons are fundamental.
Cheers
That is a good question which nobody knows the answer to. There are some guesses ... the area is work in progress.nouveau_riche said:let me phrase it in the way physics would like
In the early stages of universe, just after the big bang at the moment when particles start to get their properties and dimensions how it is that a particle will become a Fermion or a boson?
Whole atoms can behave like bosons ... see liquid He II for example.how do we macroscopically see the effects of bosons
Simon Bridge said:That is a good question which nobody knows the answer to. There are some guesses ... the area is work in progress.
We can speculate of course - but that would not be allowed in the forums.
Basically that is just how the Universe is.
I think we missed one:
Whole atoms can behave like bosons ... see liquid He II for example.
http://en.wikipedia.org/wiki/Superfluidity
At higher temperatures you can observe the different effects of Bosons and Fermions statistically. Very macroscopically, you need only look to neutron (boson) stars vs White dwarf (fermion) stars.
So did you have a particular effect in mind?
Is there a specific aim to these questions or are you just curious?
nouveau_riche said:i read a article when the LHC announced the foundings for higgs boson that just after the big bang the particles were shapeless, without any physical properties and then they interact with higgs field to gain mass and shape. i don't know how this shapeless particle came in the picture.
Certainly, emission of photons from an atom returning to the ground state from an excited state is an example of producing a boson from fermions without any anhilation.nouveau_riche said:can you give me an example where matter-antimatter anhilation is not involved in producing a boson fron fermions
The bosons produced must always conserve all conserved quantities, not just energy. For example, spin must also be conserved.nouveau_riche said:and the boson produced in the process must have some physical properties instead of being an energy packet.
DaleSpam said:Certainly, emission of photons from an atom returning to the ground state from an excited state is an example of producing a boson from fermions without any anhilation.
The bosons produced must always conserve all conserved quantities, not just energy. For example, spin must also be conserved.
DaleSpam said:Certainly, emission of photons from an atom returning to the ground state from an excited state is an example of producing a boson from fermions without any anhilation.
nouveau_riche said:can a boson have charge?
nouveau_riche said:...the boson produced in the process must have some physical properties instead of being an energy packet.
Ah, I misunderstood, to me "transform" doesn't mean the same as "produce".nouveau_riche said:the example you are giving me doesn't transform a fermion into a boson it instead produces a boson from its energy.
jtbell said:W+ and W-, for example.
DaleSpam said:Why don't matter-antimatter anhilation reactions count?
Dickfore said:But the statistics an elementary or composite particle obeys is intimately connected to the intrinsic spin of the particle, as given by the Spin-Statistics Theorem.
So if you want to change a fermion into a boson, you would have to change its spin, thus making it a new particle.
There is a kind of a "loophole" with composite particles. Take He-4, for example. It has 2 protons, 2 electrons and 2 neutrons. All of these are fermions. But, when paired, they have integer spin, thus making the nucleus, and the atom of this isotope a boson. In fact, He-4 is the first substance that exhibited superfluid transition.
What do you mean by field behavior?nouveau_riche said:because i want to see a process where a fermion can modulate its intrinsic physical property that not just involves energy/momentum conservation but its field behavior
DaleSpam said:What do you mean by field behavior?
DaleSpam said:What do you mean by field behavior?
nouveau_riche said:is it necessary that the bosons will always play the role of force carrier?
Dickfore said:Why do you answer questions with questions?
Yes. More specifically, the forces of the standard model are described by gauge fields, and the quanta of those gauge fields are the gauge bosons. Each gauge field's gauge bosons are the carriers of the respective forces. Note that there are other non-gauge bosons which are not excitations of any of the gauge fields and therefore are not carriers of any of the corresponding forces.nouveau_riche said:is it necessary that the bosons will always play the role of force carrier?