wire will move - there is a force acting on it.
it's direction depends upon the orientation of current and magnetic field - a nice way to see this is by looking op a Google picture of Fleming's left hand rule.
the force depends upon the strength of magnetic field, current and length of conductor (perpendicular to field) in the magnetic field.
All of man kind would vanish!!
yes the perpendicular component of earths magnetic field passes through the loop even if the car is moving above it or not , but no current is induced in the loop since it is not moving
Faraday says you will induce a current in the wire.
Before you can understand how electrical energy is supplied by your electric company, you need to know how it is produced. A magnet and a conductor, such as a wire, can be used to induce a current in the conductor. The key is motion. An electric current is induced in a conductor when the conductor moves through a magnetic field. Generating an electric current from the motion of a conductor through a magnetic field is called electromagnetic induction. Current that is generated in this way is called induced current. To induce a current in a conductor, either the conductor can move through the magnetic field or the magnet itself can move.
An armature, often referred to as a rotor in the context of electric motors and generators, is the rotating component that generates electromagnetic force. In electric machines, the armature typically consists of coils of wire wound around a core, which produces electricity when it moves through a magnetic field. In motors, the armature receives electrical current, creating a magnetic field that interacts with the stator to produce motion. The design and function of the armature are crucial for the efficiency and performance of the machine.
When a coil of wire moves through a magnetic field, the changing magnetic field induces a current in the wire through electromagnetic induction.
When a coil of wires moves through a magnetic field, an electric current is induced in the wires through electromagnetic induction. This phenomenon is known as Faraday's law of electromagnetic induction. The direction and magnitude of the induced current depend on the speed and direction of the coil's motion through the magnetic field.
Energy is stored in a magnetic field through the alignment of magnetic particles, creating a magnetic field that contains potential energy. This energy can be released when the magnetic field changes, such as when a magnet moves or when an electric current flows through a coil.
When a wire moves up or down repeatedly in a magnetic field, an electric current is induced in the wire due to electromagnetic induction. This phenomenon is described by Faraday's Law of Electromagnetic Induction. The induced current creates a magnetic field that opposes the original change in magnetic flux.
Magnetic field.
no. For example if u have a straight wire with a current running through it there will still be an electromagnetic field but it will not be magnetic. If u coil it around a magnetic object such as a nail for example u will get a magnetic field as the charge moves from the north to south around the object and back to the north through the object.
When a charged particle moves and experiences no magnetic force, it means that either the magnetic field is zero or the magnetic field is perpendicular to the velocity of the charged particle. As a result, the particle will only experience the electric force, causing it to follow a straight path according to the Lorentz force law.
Induced voltage generates in rod.Voltage difference evolve between two ends.
when a conductor moves accross a magnetic field or when magnetic field moves with respect to a stationary conductor for current to be induced, there must be relative motion between the coil and the magnetic.
when a conductor moves accross a magnetic field or when magnetic field moves with respect to a stationary conductor for current to be induced, there must be relative motion between the coil and the magnetic.
Yes, a neutron can be deflected by a magnetic field because it is a charged particle. The movement of the neutron will be influenced by the Lorentz force, which occurs when a charged particle moves through a magnetic field.
Electromagnetic force is produced by the interaction of electric charges and magnetic fields. When a charged particle moves through a magnetic field, it experiences a force perpendicular to its velocity and the magnetic field lines. This force is the electromagnetic force.