Magnetic poles are the ends of a magnet where the magnetic force is strongest. There are two, north and south. The north end of a magnet would come together with the south end of another magnet. But, two like poles wouldn't. It's like when you were a kid, trying to force two magnets together, and your hands were pushed out of the way by the force.
like poles repel, while opposites attract. If you studies physics in high school or college, the relation can be overiden by the strong force if they are at a quantum level or are at close proximity.
I have no idea
i wuz hopin u'd tell me...
Same poles will repel each other and opposite poles attract each other
They don't interact at all, unless they are relatively moving.
If they're just laying there on the table, then they're completely
unaware of each other.
Unlike poles will attract one another.
a photon cannot be deflected by an electric or magnetic field because it has no charge and no magnetic poles like elementary particles such as the electron
Magnetism leaves particles in molten metals lined up with north and south poles (magnetic poles, not the Earth's poles). Over time different layers of rock show that the N-S and S-N poles have switched, with S pointing in one direction and S pointing in a different direction depending on the age of the rock.
Only the magnetic poles wanderD.Earth's magnetic and geographic poles are generally not in the same place.Geographic poles are defined by Earth's rotation.
The north and south poles.
The Van Allen belts are composed of charged particles from the solar wind that became captured in the Earth's magnetic field. Deflection of charged particles
Deflecting magnetic forces are concentrated at the earth's magnetic poles where charged particles collide and interact with our atmosphere
Charged particles are attracted to magnetic fields, and therefore are attracted to the magnetic poles of the Earth.
Because the charged particles in the solar wind streaming from the sun are attracted to the magnetic poles.
The planet is Jupiter, and the phenomenon is known as the auroras at the planet's poles. Jupiter's strong magnetic field accelerates charged particles, typically electrons, which collide with gases in its atmosphere, producing bright auroras.
Yes, the rule for the interaction between magnetic poles is similar to the rule for the interaction between charged particles. Opposite magnetic poles attract each other, while like magnetic poles repel each other, similar to the way opposite charges attract and like charges repel in electricity.
Charged particles from the Sun will not reach the surface of the Earth because they are mostly deflected around it by the Earth's magnetic field (the magnetosphere), but where the particles are deflected towards the surface near the Earth's magnetic poles, they interact with the gas high in the atmosphere to form the Auroras and do not penetrate through to the surface.
Charged particles from the Sun will not reach the surface of the Earth because they are mostly deflected around it by the Earth's magnetic field (the magnetosphere), but where the particles are deflected towards the surface near the Earth's magnetic poles, they interact with the gas high in the atmosphere to form the Auroras and do not penetrate through to the surface.
Charged particles from the Sun that are attracted to Earth's magnetic poles can create beautiful auroras, also known as the northern and southern lights. These light displays are caused by the interaction of the solar particles with Earth's atmosphere, producing colorful and dynamic patterns in the sky.
Charged particles from the sun become trapped in the Van Allen radiation belts due to the Earth's magnetic field. The magnetic field bends the charged particles' trajectories, causing them to spiral along the field lines and get trapped in the region around the Earth's magnetic poles.
The Earth's magnetic field plays a crucial role in the formation of the northern lights. When charged particles from the sun are directed towards Earth, they interact with the magnetic field and are funneled towards the poles. As these particles collide with gases in the atmosphere, they emit light, creating the beautiful auroras in the northern and southern regions.
The aurora borealis occurs when charged particles from the sun interact with the Earth's magnetic field, creating a display of colorful lights in the polar regions. These particles collide with gases in the Earth's atmosphere, causing them to emit light. The colors in the aurora are determined by the type of gas molecules present and the altitude at which the collisions occur.
Magnetic fields exist around magnets, electric currents, and moving charged particles. They surround a magnet in three dimensions forming a magnetic field pattern with north and south poles.