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.
Basic Answer:
When a section of wire that is part of a complete loop (complete circuit) is moved through a magnetic field with motion perpendicular to the field will induce a current in the wire. The motion of the wire will enduce an EMF in the circuit.
Also Mention:
The wire will feel a force resisting this motion. The force time velocity will equal the rate that energy is produced, I squared R.
If you want to get picky:
If the wire is merely a segment of wire and no current can flow, then an imbalance electric charge will be created on the surface of the wire with positives at tending to one and and negatives to the other. The charges will arrange themselves to there is no voltage in the wire.
There is an E field in space from the reference frame of the wire segment as it moves through the magnetic field. The charges on the surface of the wire arrange themselves to produce an electrostatic field inside the wire that exactly cancels the E field seen from the reference frame of the wire.
Moving a conductor through a magnetic field would induce a voltage into that conductor. Asuming you are moving the conductor perpendicular to the field, then the voltage would be equal to the product of the velocity of the conductor, the length within the magnetic field, and the flux density of the field. If the conductor formed a closed loop, then a current would circulate around the conductor. Remember, though, its the voltage that is being induced, NOT the current.
you will cause an electric current to flow in the conductor
magnetic energy is converted to electric energy
magnet field
it creats magnetic fields
EMF
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.
There are more than one type of loud speaker but the most common is a coil of wire suspended in a magnetic field. When alternating currents are passed through the wire, resulting vibrating magnetic fields push and pull against the permanent magnet. The coil is connected to a surface, usually conical, which moves back and forth because of this pushing and pulling causing sympathetic sound vibrations in the air adjacent to this surface which then move away as sound waves.
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 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.
Induced voltage generates in rod.Voltage difference evolve between two ends.
A generator moves a coil of wire through a magnetic field and that induces a current in the coil .
A generator moves a coil of wire through a magnetic field and that induces a current in the coil .
When a charged particle moves through a magnetic field it experiences the Lorentz force perpendicular to the magnetic fields lines and perpendicular to its direction of motion.The Lorentz equation quantifies the force.F=qE+qvXB, where the vector quantities are in bold. The X refers to the vector cross product operation.In this question, there is no electric field, so this says the force is proportional to the charge, velocity and field strength and the sine of the angle between the velocity and the field.
You can explain the basic relationships:* An electrical current will be accompanied by a magnetic field. That is, it will act as a magnet. * If a conductor moves through a magnetic field (e.g., near a magnet), a current will flow through the conductor (if there is a closed circuit).
When a charged particle moves through a magnetic field it experiences a force from that field. When an electrical conductor moves through a magnetic field the electrons, which are negatively charged, being moving, creating an electric current.
The usual setup is called a generator. The basic idea here is that a piece of wire moves through a magnetic field; this will cause an electrical current. The electrical current causes another magnetic field that opposes the movement, so it requires (mechanical) energy to keep it moving.The usual setup is called a generator. The basic idea here is that a piece of wire moves through a magnetic field; this will cause an electrical current. The electrical current causes another magnetic field that opposes the movement, so it requires (mechanical) energy to keep it moving.The usual setup is called a generator. The basic idea here is that a piece of wire moves through a magnetic field; this will cause an electrical current. The electrical current causes another magnetic field that opposes the movement, so it requires (mechanical) energy to keep it moving.The usual setup is called a generator. The basic idea here is that a piece of wire moves through a magnetic field; this will cause an electrical current. The electrical current causes another magnetic field that opposes the movement, so it requires (mechanical) energy to keep it moving.
Perpendicular to both the current and the magnetic field.