When magnets are placed close together, they exert a force of magnetism that can either attract or repel each other, depending on their orientation. Opposite poles (north and south) attract, while like poles (north-north or south-south) repel. The strength of this magnetic force increases as the distance between the magnets decreases, leading to a stronger interaction. This phenomenon is governed by the magnetic field generated by each magnet.
When the poles of two magnets are brought close together, they can either attract or repel each other depending on their alignment. Opposite poles (north and south) attract, pulling the magnets together, while like poles (north and north or south and south) repel, pushing the magnets apart. This interaction is a fundamental principle of magnetism and is governed by the magnetic field generated by each magnet.
The scientific term for the pushing force of magnets is "magnetic repulsion." This phenomenon occurs when like poles of two magnets (either north-north or south-south) are brought close together, causing them to push away from each other. Magnetic repulsion is a fundamental aspect of magnetism, along with magnetic attraction, which occurs between opposite poles.
If they come end-to-end, they will either attract or repel depending on the polarity.If you bring the sides together, they often will slide to bring their ends + & - ends together.
Magnets can repel each other for an indefinite amount of time as long as they are placed in a position where their poles are facing each other in such a way that repulsion occurs. This repulsion can persist as long as the magnets remain in close proximity to one another.
When current flows in a conductor there is a magnetic field formed around the conductor. This magnetic field can be used to make an electric magnet (like the ones used at junkyards), motors also use magnetism to operate, and many switches (solenoid, motor starters, and relay switches) use magnetism to open or close.
When the poles of two magnets are brought close together, they can either attract or repel each other depending on their alignment. Opposite poles (north and south) attract, pulling the magnets together, while like poles (north and north or south and south) repel, pushing the magnets apart. This interaction is a fundamental principle of magnetism and is governed by the magnetic field generated by each magnet.
The force is called "magnetism". The refrigerator is not magnetic, but the magnet will temporarily induce magnetism in the refrigerator's metal - the part that is close to the magnet.
Some examples of induced magnets are when a piece of iron is brought close to a permanent magnet and becomes temporarily magnetized, or when an electric current flowing through a coil of wire induces magnetism in a nearby object. Magnetic induction can also occur in materials like nickel or cobalt when placed in a magnetic field.
When opposite magnets are brought close together, they attract each other and pull towards one another. This is because opposite poles of magnets (north and south) are attracted to each other due to their magnetic fields.
The scientific term for the pushing force of magnets is "magnetic repulsion." This phenomenon occurs when like poles of two magnets (either north-north or south-south) are brought close together, causing them to push away from each other. Magnetic repulsion is a fundamental aspect of magnetism, along with magnetic attraction, which occurs between opposite poles.
Magnets that stick together demonstrate the principle of magnetic attraction by showing how opposite poles attract each other. When two magnets with opposite poles (north and south) come close together, they are pulled towards each other due to the magnetic force between them. This attraction is what causes the magnets to stick together.
If they come end-to-end, they will either attract or repel depending on the polarity.If you bring the sides together, they often will slide to bring their ends + & - ends together.
A magnet will adversely effect the beams path by deflecting it once it passes close enough to the magnet. This is why magnets are used in the column of an eb weld machine. If a magnet were to be placed in an eb weld chamber and an the beam was shot at the magnet, the beam would deflect drastically. That said, I have personally welded parts containing magnets directly beneath the surface to be welded by using steel shunts to absorb the magnets pull. Although it didn't completley stop the magnets effect on the beam, it dampened the effect drastically and allowed for successful welding.
When two magnets are brought close together, their magnetic fields interact. Depending on the orientation of the magnets, they can either attract or repel each other. This interaction is due to the alignment of the magnetic domains within the magnets, which causes the magnetic fields to either reinforce or cancel each other out.
If they are brought together by their ends they'll repel each other. In other way, they'll attract each other.
Magnets can repel each other for an indefinite amount of time as long as they are placed in a position where their poles are facing each other in such a way that repulsion occurs. This repulsion can persist as long as the magnets remain in close proximity to one another.
An example of repulsion would be when two magnets with like poles facing each other push away from each other when brought close together. This is due to the repulsive force between the like poles of the magnets.