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.
An electric current can exert a force on a magnet, and a magnet can exert a force on an electric current.
That answer is false NOT true.
Actually, electric currents and magnets are closely related through electromagnetism. When an electric current flows through a wire, it generates a magnetic field around the wire. Similarly, moving magnets can induce an electric current in a wire. This relationship forms the basis of electromagnetism and is utilized in various technologies like electric motors and generators.
Permanent magnets do not produce electric currents on their own. However, when a permanent magnet moves near a closed loop of wire or coil, it can induce an electric current in the wire due to electromagnetic induction.
The Law of Electric Charge states that like charges repel and opposite charges attract. In an electric motor, this law is crucial for the operation of the motor. By applying electric currents to create magnetic fields, the motor uses the interaction of opposite charges to generate force and produce motion.
True electric currents refer to the movement of electric charge carriers through a conductor, such as electrons in a wire. It is this flow of charge that powers electrical devices and circuits. The direction of the current is defined as the flow of positive charge, even though in reality it is often negative charges (electrons) that are moving.
Actually, electric currents and magnets are closely related through electromagnetism. When an electric current flows through a wire, it generates a magnetic field around the wire. Similarly, moving magnets can induce an electric current in a wire. This relationship forms the basis of electromagnetism and is utilized in various technologies like electric motors and generators.
That answer is false NOT true.
Permanent magnets do not produce electric currents on their own. However, when a permanent magnet moves near a closed loop of wire or coil, it can induce an electric current in the wire due to electromagnetic induction.
Electromagnetism.
Electric currents ... especially in coils.
Faraday showed that a wire passing through a magnetic field will produce electricity. This is how a generator works. Many windings of wire on an armature spin in a magnetic field. This makes electricity.
Motion of a coil within a magnetic field will induce a current in the coil if it can complete a circuit.
ALL magnets are the result of moving electrons. A simple copper coil carrying an electric current demonstrates the simplest form.Permanent magnets are those materials in which a number of the electrons share a similar spin.Commonly reference is made to the magnetic loops of plasma on the surface of the Sun, but at a temperature of over 50 000 deg C, there are no magnetic materials. These magnetic fields are the result of electric currents flowing near the surface of the sun.The magnetic field of the Earth is generated by electric currents flowing roughly parallel with the equator. or rather, the net result of many electric currents flowing around the Earth - probably in the magma.But the ordinary permanent magnets are indeed made of particular elements in which the 'magnetic domains' may be aligned in parallel.
Magnetism or magnetic field is the attraction for iron , associated with electric currents as well as magnets characterized by fields of force
The Law of Electric Charge states that like charges repel and opposite charges attract. In an electric motor, this law is crucial for the operation of the motor. By applying electric currents to create magnetic fields, the motor uses the interaction of opposite charges to generate force and produce motion.
Well when an electric current flows through a conductor a magnetic field is produced. And a changing magnetic flux through a conductor produces a current in the conductor.
In a conductor - only if the field is moving, thus changing.