its electrostatic and electro magnetic force..
even universal gravitational force as electrons and neutrons has mass.
ANSWERThere are only 4 known forces:
(a) Strong nuclear force,
(b) Weak nuclear force,
(c) Electromagnetic force,
(d) Gravitation force
The only force we know of acting between the e-and and no particles is an infinitestimally small amount of gravitational force.
The e- is not a nuclear particle and the no is not affected by electromagnetic force.
The force that acts between an up quark and an electron is the electromagnetic force. The interaction is due to the electric charges of the quark (+2/3) and the electron (-1), causing them to attract each other through the exchange of virtual photons.
The fundamental force responsible for some forms of radioactivity is the weak nuclear force. This force is involved in processes such as beta decay, where a neutron in an atomic nucleus is transformed into a proton, an electron, and an antineutrino.
Oh, dude, if you fuse a proton with an electron, you'd get a neutron. It's like they're having a little subatomic party and decide to merge into a neutral particle. So, yeah, you'd basically end up with a neutron, which is pretty chill in the subatomic world.
and the fact that it is stable to estimate the strength of the strong nuclear force between nucleons. assume the distance between nucleons is 10−15 m
A negatively charged electron is attracted by the positively charged nucleus so the electron revolves around the nucleus so that it can generate enough centrifugal force in order that the attractive force is nullified and the electron can stay in its orbit
Yes, an example of an electrostatic force acting in an atom is a proton attracting an electron. This attraction occurs due to the opposite charges of the proton (positive) and the electron (negative), leading to the electrostatic force of attraction between them.
There is no significant attraction between neutrons and electrons. Neither the electric force nor the strong nuclear force applies between them. There is an insignificant attraction due to gravity -- the gravity force between an electron one angstrom from a neutron is weaker than the electric force between that same electron and a proton a billion trillion kilometers away.
If it were there could be no bonding between atoms because bonding is a result of transfering or sharing of electrons by atoms; besides quarks are already present inside a neutrons; if electrons were present inside a neutron they would repel each other, so there would need to be a force that keeps them together. There is a force that holds the nucleus together called the strong interaction mediated by gluons which wouldn't interact with electrons so the neutrons would be unstable.
A proton attracts an neutron. B. A proton repels an electron. C. A proton attracts an electron.
A neutron is made of 3 quarks, namely an up quark and two down quarks. It is this composition of quarks that cause it to have zero charge. (An up quark has a charge of 2/3 and down quarks have a charge of -1/3 - thus 2/3 + (-1/3 *2) = 0) A free neutron (that is one that is not bound in a nucleus) will become a proton, an electron and an electron-neutrino. This happens through the weak force (it acts on a down quark, turning into an up). This does not mean a neutron contains an electron. It does not. Yes, an electron appears when a neutron decays, but that electron does not exist in the neutron as an electron, but it does not.
The force between nucleons is called nuclear force.
The weak force converts a neutron to a proton, an electron, and a neutrino; in the process called beta decay.
A lone neutron spontaneously decays into a proton plus an electron plus an antineutrino (to carry off extra energy).
intrinsic and quantised.
Electrostatic force between the electron and the positively charged nucleus.
The gravitational force is not an example of an electrostatic force that exists within the atom. The electrostatic forces within an atom include the forces between protons and electrons, and the forces holding the nucleus together.
This is called inverse beta decay and it forms a neutron. Normally a neutron will decay into a proton and electron, but the opposite will happen given enough energy. Coincidentally, this is how neutron stars are formed (the immense pressure from gravity overcomes the force separating protons and electrons.)