Interaction between electron & neutron

In summary, an electron has no interaction between a neutron since the charge of each quark has become neutralised.
  • #1
Denton
120
0
Since a neutron has no charge and an electron is not involved in the strong nuclear force, does this mean that an electron has no interaction between a neutron? As in a very dense neutron star, would we expect that electrons could easily pass right though without being absorbed/deflected in any way?
 
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  • #2
Neutrons are composite particles made up of quarks which are charged, so the electromagnetic interaction is not out of the picture. Also, electrons and quarks can interact via the weak interaction.
 
  • #3
Yes but since the charge of each quark has become neutralised why would one expect there be any electromagnetic interaction even when the electron 'enters' the neutron? Also with the weak reaction, i thought those only happened when some sort of nuclear reaction took place, how does an electron interact with a neutron on this level?
 
  • #4
Both neutrons and electrons have mass so gravity will have an influence between the particles at the very least. Gravity is normally very weak compared to the electrostatic force, but if you had a very dense (massive) neutron star it seems reasonable that the gravitiational attraction between such a star and an electron can be quite large...
 
  • #5
Denton said:
Yes but since the charge of each quark has become neutralised why would one expect there be any electromagnetic interaction even when the electron 'enters' the neutron?
How has it become "neutralised"?

A neutron is a composite particle that is charge neutral, sort of in the same way that you are also a charge neutral object (made up of charged particles). But that doesn't mean an electron fired at you will not interact with your constituent (charged) particles.

PS: Incidentally, you share your username with the manufacturer of electron beam equipment.
 
  • #6
Note that the neutron has a nonzero magnetic moment, so it can interact with a magnetic field.
 
  • #7
jtbell said:
Note that the neutron has a nonzero magnetic moment, so it can interact with a magnetic field.

It also has a spin, so they can couple to each other that way, too.
 
  • #8
BenTheMan said:
It also has a spin, so they can couple to each other that way, too.

That's not enough. A neutrino and photon both have spin, but they do not interact with each other.

JTBell is correct - the electron has a magnetic interaction with the neutron. He's also right that an electron can interact electrically with the quarks inside a neutron, although this is the scale at which the concept of a neutron behaving as a simple particle breaks down.
 
  • #9
How has it become "neutralised"?

A neutron is a composite particle that is charge neutral, sort of in the same way that you are also a charge neutral object (made up of charged particles). But that doesn't mean an electron fired at you will not interact with your constituent (charged) particles.

Ive always expected this because a neutron does not have a slightly positive side or a slightly negative side as one would expect something being made of dissimilar charged components.
 
  • #10
At high energies, the electron can "resolve" the components of the neutron (i.e. the quarks)
 
  • #11
Denton said:
Ive always expected this because a neutron does not have a slightly positive side or a slightly negative side as one would expect something being made of dissimilar charged components.
It does. There is a non-trivial distribution of charge, not from left to right (unless you break left-right symmetry, by polarization or something), but from inside to outside.
 
  • #12
To build on that a bit: if a neutron had a positive side and a negative side, this would be called it's electric dipole moment. This has been measured to be zero to exquisite precision - it's one of the best known numbers in subatomic physics. However, the inside of a neutron is measurably more positive than the outside.

Now we can ask ourselves what would happen if we scattered a variable energy beam of electrons at a pile of neutrons. First, at very low energies, they would interact magnetically with the whole neutron. As the energy increases, they would start to interact electrically with the negative halo and the positive core. As the energy increases further, they would start to interact with the constituent quarks (the quarks and, in a sense, their "nearby" gluons) and finally at the very highest energies they would interact with the bare current quarks.
 
  • #13
Thanks for that :)
 

1. What is the basic interaction between an electron and a neutron?

The basic interaction between an electron and a neutron is through the electromagnetic force. This force is responsible for the attraction and repulsion between charged particles, such as the negative charge of an electron and the neutral charge of a neutron.

2. How do electrons and neutrons interact in an atom?

In an atom, electrons and neutrons interact through the strong nuclear force. This force holds the nucleus of the atom together by binding protons and neutrons together. Electrons orbit around the nucleus due to the electrostatic attraction between the positively charged protons and negatively charged electrons.

3. Can electrons and neutrons interact outside of an atom?

Yes, electrons and neutrons can interact outside of an atom through the weak nuclear force. This force is responsible for certain types of radioactive decay, where a neutron can turn into a proton by emitting an electron and a neutrino.

4. How does the interaction between an electron and a neutron affect the stability of an atom?

The interaction between an electron and a neutron plays a crucial role in determining the stability of an atom. The number of electrons in an atom determines its chemical properties, while the number of neutrons can affect its nuclear stability. An imbalance between the number of protons and neutrons can lead to radioactive decay.

5. Are there any other factors that can affect the interaction between an electron and a neutron?

Yes, the energy of the electron and the distance between the electron and neutron can also affect their interaction. The closer the electron is to the neutron, the stronger the interaction will be. Additionally, external forces such as magnetic fields can also influence the interaction between these particles.

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