In a conductor - only if the field is moving, thus changing.
From the magnet.
magnetic field. The magnetic field is the region in which the magnetic force generated by the magnet can exert influence on other objects or materials.
through a wire coil to induce an electric current in a process known as electromagnetic induction. As the magnet moves relative to the coil, the changing magnetic field creates an electric current. This current can then be harnessed to generate electricity.
Yes, a bar magnet can exert a torque on itself due to its own magnetic field. This torque can cause the magnet to align itself in a specific orientation, depending on the interaction between its north and south poles. If the magnet is not free to rotate, this torque can manifest itself as a force causing the magnet to move.
You need to do the experiment. If the magnet is strong enough, metal (steel, iron) will jump to the magnet (or pull the magnet towards it).
Sort of... In permanent magnets, magnetism is due to the movement of electrons around their atoms. Each atom is a small magnet, and there are more atoms aligned in one direction than in the other. If you consider the electron orbiting around the atom, or "spinning around its axis" as a "current", then yes.
From the magnet.
When an electric current flows through a conductor, it creates a magnetic field around it. This magnetic field can exert a force on nearby magnets or other currents. Similarly, a moving magnet can induce an electric current in a conductor, which also creates an interaction between the two. This phenomenon is described by the principles of electromagnetism.
No, a magnet is a physical object. However, a magnet can EXERT a force.
A magnet induces an electric current in a wire coil when there is a relative motion between the magnet and the coil, which generates a changing magnetic field. This changing magnetic field induces an electromotive force, leading to the flow of an electric current in the wire coil.
Yes, it is true that a magnet is an object that can exert force on another material. However, it will only exert that force if it is made out of the correct material. Items made of iron are the most common magnetic objects.
A magnet can exert a force on non-magnetic objects through magnetic induction or attraction. This force can cause the non-magnetic object to be attracted to the magnet or to experience a magnetic field-induced movement or alignment.
A magnet can exert force on a non-magnetic object through magnetic induction, attraction, or repulsion. The non-magnetic object can be attracted towards the magnet or repelled away from it depending on their relative orientation.
A magnet can exert a force on a non-magnetic object through magnetic induction. When a magnet is brought near a non-magnetic object, the object can become temporarily magnetized and experience an attractive or repulsive force depending on the orientation of the object and the magnet.
because they love each other
A magnet can exert a force over a distance because of its magnetic field. The field extends around the magnet and interacts with other magnetic materials or objects at a distance, causing them to be attracted or repelled. This force is the result of the alignment of magnetic moments within the material.
Generating electromotive force (emf) or inducing an electromotive force (emf) in the coil of wire is known as electromagnetic induction. This phenomenon is the basis for how electric current can be produced by moving a bar magnet in and out of a coil of wire.