as magnetic moments are created by the movement of electric charges Since the neutron is a neutral particle the magnetic moment is an indication of substructure i.e. the neutron is made of other electrically charged particles (quarks).
There is a cloud of pi-mesons around the neutrons in result to the exchange of pi-mesons (the exchange particle of the strong force) with the other nucleons (proton and neutrons).
the non-zero magnetic moment of the neutron indicates that it is not an elementary particle as it carries no net charge but still interacts with a magnetic field.
The magnetic moment is negative which means that the neutron has a tendency to align anti parallel to a magnetic field rather than parallel to the field.
Yes, a neutron can be deflected by a magnetic field because it is a charged particle. The movement of the neutron will be influenced by the Lorentz force, which occurs when a charged particle moves through a magnetic field.
A neutron, an antineutron, a neutrino, an antineutrino, and a photon would not be deflected by a magnetic field, as they all have no net electric charge. I do not find a reference to an antiphoton, but it makes sense that, if it existed, it would also not be affected by a magnetic field.
A neutron has no charge, as it is electrically neutral.
The magnitude of the electron's spin is greater than its magnetic moment because the spin of an electron contributes more to its intrinsic angular momentum than its magnetic moment does. The spin of an electron arises from its intrinsic properties and is a fundamental characteristic of the particle, whereas the magnetic moment is a consequence of the electron's charge and its motion.
The subatomic particle in an atom that has no charge is called a neutron. Neutrons are found in the nucleus of an atom along with protons, which have a positive charge, and electrons, which have a negative charge.
as magnetic moments are created by the movement of electric charges Since the neutron is a neutral particle the magnetic moment is an indication of substructure i.e. the neutron is made of other electrically charged particles (quarks).There is a cloud of pi-mesons around the neutrons in result to the exchange of pi-mesons (the exchange particle of the strong force) with the other nucleons (proton and neutrons).the non-zero magnetic moment of the neutron indicates that it is not an elementary particle as it carries no net charge but still interacts with a magnetic field.The magnetic moment is negative which means that the neutron has a tendency to align anti parallel to a magnetic field rather than parallel to the field.
Yes, a neutron can be deflected by a magnetic field because it is a charged particle. The movement of the neutron will be influenced by the Lorentz force, which occurs when a charged particle moves through a magnetic field.
In a neutron star, the magnetic field is thought to be generated by the intense rotation of the star's core, which contains highly magnetized matter left behind after a supernova. This magnetic field is believed to be generated by the interactions of its constituent particles, particularly neutrons and protons, despite neutrons themselves not having a net charge.
A neutron does not have a charge -- its neutral
A neutron, an antineutron, a neutrino, an antineutrino, and a photon would not be deflected by a magnetic field, as they all have no net electric charge. I do not find a reference to an antiphoton, but it makes sense that, if it existed, it would also not be affected by a magnetic field.
A neutron has no charge, as it is electrically neutral.
No. A neutron carries no charge.
yes neutron has no charge
The magnitude of the electron's spin is greater than its magnetic moment because the spin of an electron contributes more to its intrinsic angular momentum than its magnetic moment does. The spin of an electron arises from its intrinsic properties and is a fundamental characteristic of the particle, whereas the magnetic moment is a consequence of the electron's charge and its motion.
Magnetic fields are cause by the movement of charge , normally electrons each atoms has a magnetic moment
The neutron has no charge, therefore the charge to mass ratio for the neutron is zero.
The magnetic moment of a nucleus is generally smaller than that of an electron because the nucleus is composed of protons and neutrons, which have smaller individual magnetic moments that partially cancel each other out due to their arrangement within the nucleus. Electrons, on the other hand, are elementary particles with a specific magnetic moment that is not cancelled out by other particles.