Mesons and bosons, same or different?

In summary: Therefore 0 is even.In summary, we discussed the distinction between mesons and bosons, with mesons being a specific type of boson. We also clarified that not all bosons are mesons, and gave examples of other types of bosons such as photons, gluons, and gravitons. The conversation also touched on the fact that atoms with an even number of neutrons are considered bosons, with the exception of the hydrogen atom which has no neutrons.
  • #1
doubledouble
6
0
Mesons are bosons, but are all bosons mesons e.g. intermediate vector bosons (w and z bosons in the weak interaction)?
 
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  • #2
No, not all bosons are mesons.

meson:
Any of a family of subatomic particles that participate in strong interactions, are composed of a quark and an antiquark (or a QM linear combination of quark + antiquark combos), and have masses generally intermediate between leptons and baryons.

boson:
Any particle (or composite system) which has a total spin quantum number that is an integer (0,1,2,...) and therefore obeys Bose-Einstein statistics for its quantum state.
 
  • #3
Photons, gluons, and gravitons are bosons, but none of them are mesons. Also all atoms with an even number of neutrons are bosons.
 
  • #4
"Also all atoms with an even number of neutrons are bosons."

Actually, the hydrogen atom has zero neutrons, but is a boson. For example see:
http://focus.aps.org/story/v2/st22

The hydrogen nucleus, on the other hand, is a fermion. The deuterium atom, which has a neutron, a proton, and an electron, is a fermion. A given atom will alternate between being a boson and a fermion as you strip electrons off of it. This is cause electrons are fermions and have to be counted along with the neutrons and protons in the nucleus. The nucleus for a given atom will always be a boson or fermion. See wikipedia:

http://en.wikipedia.org/wiki/Boson#Composite_bosons
 
  • #5
"Also all atoms with an even number of neutrons are bosons"

He hust have meant "even number of nucleons";
since all even-even nucleis have total Angular momentum J = 0
 
  • #6
actually he did mean "even number of neutrons" cause as has been said, in an atom (key word here- neutral atom is assumed) you count the electrons, neutrons and protons.

A neutral atom always has # electrons = # protons. This always yields an even number. So atoms with even numbers of neutrons PLUS the hydrogen atom are bosons.

I don't know if zero is considered an even integer or not. It has been a long time since I have taken a formal math course.
 
  • #7
I don't know if zero is considered an even integer or not. It has been a long time since I have taken a formal math course.

0 is an even number. It certainly is not odd, so be all usual rules of arithmetic, it is even.

The usual definition is a number is even if there is no remainder when divided by 2.
 

Related to Mesons and bosons, same or different?

1. What are mesons and bosons?

Mesons and bosons are both subatomic particles that make up the building blocks of matter. They are classified as elementary particles, meaning they cannot be broken down into smaller components.

2. Are mesons and bosons the same thing?

No, mesons and bosons are different types of particles with distinct characteristics and properties. Mesons are made up of a quark and an antiquark, while bosons are force-carrying particles that mediate interactions between particles.

3. How do mesons and bosons differ?

Mesons and bosons differ in their spin, which is a property that describes the intrinsic angular momentum of a particle. Mesons have a spin of 0 or 1, while bosons have a spin of 0, 1, or 2.

4. Do mesons and bosons interact differently?

Yes, mesons and bosons interact differently due to their different spins. Mesons, with a spin of 0 or 1, interact through the strong nuclear force, while bosons, with a spin of 0, 1, or 2, interact through the weak and electromagnetic forces.

5. What is the significance of mesons and bosons in the study of particle physics?

Mesons and bosons play a crucial role in understanding the fundamental forces and structure of the universe. They are also important in the development of theories, such as the Standard Model, which describes the interactions between all known particles.

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