Put two ends of two magnets together and the force will repel the other.
The magnetic force between currents moving in the oppoiste directions is repulsive.
The electro-magnetic force, I guess. The strong nuclear force holds the nucleons together and the electro-magnetic tries to push them apart.
electromagnetic - long range, either attractive or repulsive, moderateweak nuclear - short range, either attractive or repulsive, weakstrong nuclear - very short range, either attractive or repulsive, very stronggravity - long range, always attractive, very weak
The strong nuclear force is an attractive force that counteracts (or rather balances-out) the repulsive coulomb force. Forces can be modelled by an exchange of particles between the involved bodies. I think the particle responsible for the strong nuclear force is the gluon. In a nucleus there should be a balance of protons and neutrons; too many protons and the repulsive force will be too high, too many neutrons and there won't be enough glue to go round.
You push them together. They won't stay together, though, since the repulsive force will continue acting. OR, use a nutural \ sympathetic strata ... a simple example is use a metal that attracts the magnetic poles ... and they will unite! N --> |Metal| <-- N
repulsive force
Magnetic Force
The magnetic force between currents moving in the oppoiste directions is repulsive.
Compass plants respond to Earth's magnetic field, but do not produce their own magnetic force.
The electro-magnetic force, I guess. The strong nuclear force holds the nucleons together and the electro-magnetic tries to push them apart.
The gravitational force is only attractive. Electric and magnetic forces can be both attractive and repulsive.
electromagnetic - long range, either attractive or repulsive, moderateweak nuclear - short range, either attractive or repulsive, weakstrong nuclear - very short range, either attractive or repulsive, very stronggravity - long range, always attractive, very weak
because there is a magnetic field round an object
No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.
The strong nuclear force is an attractive force that counteracts (or rather balances-out) the repulsive coulomb force. Forces can be modelled by an exchange of particles between the involved bodies. I think the particle responsible for the strong nuclear force is the gluon. In a nucleus there should be a balance of protons and neutrons; too many protons and the repulsive force will be too high, too many neutrons and there won't be enough glue to go round.
It is equally strong at the north pole compared with the south pole.
force push pull magnetic strong