It doesn't work like that. You can't make an electron have spin, remove its spin, or change the amount of its spin.What happens in a permanent magnet is that more electrons have their spin axis in one direction than in the opposite direction.
Since the spin is associated with a magnetic field, that results in magnetism that can be observed externally.
Yes. Placing a rotating magnet below it can generate a magnetic field that creates a spin in the suspended magnet. If the magnet is mounted on a low-friction axis, bringing an opposite pole toward one side of the magnet, then removing it, will add force to spin it for awhile.
Each atom acts like a tiny magnet. When the atoms are aligned, the magnets produce magnetism. When an iron or nickel material comes near the magnet, its atoms align with the different pole facing the magnet. For example, if the magnet's atoms have the North side facing away, then the iron object will have the South side facing the magnet. So then they attract.
D. electron spin. Magnetism in materials is primarily caused by the alignment and spin of electrons in the atoms. When electrons have aligned spins, they create a magnetic field, resulting in magnetism in the material.
Magnet shaped like a horseshoe, so both the polarities are pointed the same way. They can be weak or strong magnets (my dad had a couple when we were kids... we put a broomstick in them and did chin-ups from the I-beam in the basement, because they were strong enough to hold a 12-year-old's weight easily). Here is a site with a picture of some: http://www.indigo.com/magnets/gphmgnts/chrome-steel-horseshoe-magnets.html
Liquid oxygen is attracted to a magnet due to its paramagnetic properties, meaning it contains unpaired electrons that respond to magnetic fields. When a magnet is brought near liquid oxygen, these unpaired electrons align with the magnetic field, causing the liquid oxygen to be weakly attracted towards the magnet.
Yes, magnet attraction is related to electron spin. Electrons possess a property called spin, which creates a magnetic moment. When electrons align their spins in the same direction, they create a magnetic field that can interact with other magnetic fields, leading to magnet attraction or repulsion.
This could be a description of a dipole, as of a ferromagnet where the fields at the poles are opposite.
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.
Coils of wire and a magnet. When magnetic lines of force move across a wire, it causes electrons in the wire to move. Those moving electrons are electrical current. In a generator, either the magnet or the coils of wire spin.
Yes. Placing a rotating magnet below it can generate a magnetic field that creates a spin in the suspended magnet. If the magnet is mounted on a low-friction axis, bringing an opposite pole toward one side of the magnet, then removing it, will add force to spin it for awhile.
Yes, electrons do spin in an atom.
Electrons behave like tiny magnets because they have a property known as spin. This spin generates a magnetic field around the electron, giving it magnetic properties. When electrons are in motion, their spin causes them to act like small magnets, aligning with an external magnetic field.
Actually due to current, here movement of electrons around the nucleus, a magnetic dipole is formed. These are the basic causes to make a material magnetized. Also spin of electrons too bring the dipoles in the scene. The beauty is that even free space has magnetic properties.
Spin causes electrons to have an intrinsic magnetic moment, leading to the phenomenon of electron spin. This property allows electrons to interact with magnetic fields and is crucial for understanding the behavior of atoms and molecules in chemistry and physics.
A single covalent bond consists of a shared pair of electrons formed by two atoms. Each atom contributes one electron to the shared pair, resulting in a total of two electrons being shared in the bond.
Electrons have an intrinsic property called "spin," which isn't the same as actual spinning motion. It is a quantum mechanical property that describes an electron's intrinsic angular momentum. Electrons can have a spin value of either +1/2 (spin-up) or -1/2 (spin-down).
A magnet is an alignment of particles in a solid. You can imagine a magnet as a bunch of tiny magnets that are all pointing in the same direction. When they point in the same direction, the little parts add up, and the magnet works like you'd expect. When you heat or hammer a magnet, the little magnetic parts can get jostled and unaligned. When that alignment is disturbed, they no longer point in the same direction and may even cancel other magnetic parts out, weakening and eventualy destroying the magnetism.