a magnet is made up of lots of tiny things called domains.these domain are what make moagnet a magnet. they alway face north, that's what makes it a permanant magnet.though you can get temporary magnets by swiping the magnet onto a magnetic material many time making sure that only swiping in one direction and not keeping the magnet close to the metal when going back to the other side. this haappens because those domains are magnetic, and by swiping a magnet on it, the all get attracted to the north pole. but hte can be stopped from being a temporay magnet when droped heavily. amina =3
the magnet attracts to iron by the magnetic field both the iron and the magnet have
can be separated by using a magnet
Lodestone is an example of a natural magnet.
the same ones as make up you: protons, neutrons, and electrons.
The magnetic field of a magnet is concentrated at the poles. These are the points on the magnet where the magnetic force is strongest and where attraction or repulsion is most noticeable.
you are changing one type of energy into another, you are moving electrons using a magnet, these electrons have energy that powers our electronic devices
When a magnet is stroked along a material, the magnetic domains within the material align themselves in the direction of the magnetic field produced by the magnet. This alignment results in the material becoming magnetized.
Electrons align in a magnet due to their inherent magnetic moment, which arises from their spinning motion and orbital angular momentum. In a magnet, the magnetic moments of individual electrons align in the same direction, creating a magnetic field.
Poles on a magnet attract or repel because of the way the electrons line up. The electrons in the valence shells tend to line up on one side of the nucleus. The electrons have a negative charge and the nucleus has a positive charge. The negative charges in one magnet repel the negative charges in another magnet but attract the positive charges in another magnet.
electrons. These moving electrons create a magnetic field that can cause the atom to behave like a tiny magnet.
When you spin electrons in a magnet, they generate a magnetic field. This is because electrons behave like tiny magnets due to their spin and charge. Spinning electrons contribute to the overall magnetic properties of the material.
Yes, a magnet has moving electrons in it. When a material becomes magnetized, the electrons within its atoms align in a way that creates a magnetic field. This alignment of electrons results in the magnetic properties we observe in magnets.
The effect a magnet has on an atom is dependent on the magnetic properties of the atom, such as its electron configuration and spin. Atoms with unpaired electrons are more likely to interact with a magnet and exhibit magnetic properties.
Some metals are naturally paramagnetic, meaing that you can induce a magnet field on it but only with a very strong magnet. To actually magnetize the metal itself without a magnet, you would have to make an induced magnet by wrapping the metal around a copper wire and sending electricity through it. It all has to do with the arrangement of the electrons within the metal.
When a metal object is placed near a magnet, the magnetic field of the magnet exerts a force on the free electrons in the metal, causing those electrons to align in the same direction. This alignment creates a magnetic field in the metal, which either attracts or repels the original magnet, depending on the orientation of the magnetic poles.
The electrons of the permanent magnet would align the way the electromagnetic field passed through the magnet.