Well its all about arrangement of electrons inside the metal. This arrangement gives rise to a force field(not a shield used by the invisible woman in the fantastic four) which has the property of attracting small pieces of iron fillings. Or it may produce electricity when it is displaced around a conductor.
How the field arises is the same as how electric force arises.
The magnetic force of a magnet is the force that a magnet exerts on another magnet or a magnetic material. It is responsible for attracting or repelling objects with magnetic properties. The strength of the magnetic force depends on the material and shape of the magnet.
A region of force around a magnet refers to the magnetic field produced by the magnet, which exerts a force on other magnets or magnetic materials within its influence. The strength and direction of the magnetic force vary depending on the position and orientation relative to the magnet.
As distance from a magnet increases, the strength of the magnetic force decreases. This is because the magnetic field created by the magnet weakens with distance, resulting in a reduction in the force it exerts on other magnetic objects.
When a magnet pulls a car, it demonstrates the principles of magnetic force and motion by showing how the magnetic force between the magnet and the car causes the car to move towards the magnet. This is because the magnet creates a magnetic field that exerts a force on the car, resulting in motion.
A magnet exerts a magnetic force, which is the force of attraction or repulsion between magnets or magnetic materials. This force arises due to the alignment of the magnetic domains within the material, causing a magnetic field.
Whether it exerts a force on ferromagnetic objects.
The magnetic force of a magnet is the force that a magnet exerts on another magnet or a magnetic material. It is responsible for attracting or repelling objects with magnetic properties. The strength of the magnetic force depends on the material and shape of the magnet.
It exerts magnetic energy to push or pull an object
A region of force around a magnet refers to the magnetic field produced by the magnet, which exerts a force on other magnets or magnetic materials within its influence. The strength and direction of the magnetic force vary depending on the position and orientation relative to the magnet.
As distance from a magnet increases, the strength of the magnetic force decreases. This is because the magnetic field created by the magnet weakens with distance, resulting in a reduction in the force it exerts on other magnetic objects.
When a magnet pulls a car, it demonstrates the principles of magnetic force and motion by showing how the magnetic force between the magnet and the car causes the car to move towards the magnet. This is because the magnet creates a magnetic field that exerts a force on the car, resulting in motion.
A magnet exerts a magnetic force, which is the force of attraction or repulsion between magnets or magnetic materials. This force arises due to the alignment of the magnetic domains within the material, causing a magnetic field.
A magnet exerts magnetic force when 'at rest', or when it is not acted upon by any other force. An electromagnet exerts magnetic force only when energized by electricity, and is normally constructed from a ferrite core wrapped by an electric coil.
The magnet exerts a magnetic force on the paper clip in the downward direction. The force experienced by the paper clip will depend on the strength of the magnetic field, the mass of the paper clip, and the distance between the magnet and the paper clip. The force can be calculated using the formula for magnetic force, which involves the strength of the magnetic field, the charge of the particle, and the velocity of the particle.
Magnetic energy causes the nail to move towards the magnet. The magnetic field produced by the magnet exerts a force on the nail, causing it to move.
A magnet can act from a distance because it creates a magnetic field around itself, which exerts a force on other magnetic materials within its field. This force can attract or repel other magnets or magnetic materials without physical contact.
A magnet can move something without touching it by creating a magnetic field that exerts a force on other magnetic materials, such as iron or steel. This force can cause the object to be attracted or repelled by the magnet, leading to movement without direct contact.