They will combine to make a single magnetic field.
When two magnetic fields are adjacent to each other, a force is produced through their interaction. Magnetic fields combine when two like currents flow near to one another.
no know will ever know
Wrong grammer man c'mon it's,
no ONE will ever know.
they combine and become one magnetic field
It sticks
If one continously heats a particular magnet to high temperatures or long time or both, it loses it magnetism because the particles get excited and start forming no-magnetic arrangements.
the poles (north and south) create the magnetic fields Magnetic fields are, in the end, the result of the movement of electrostatic charges. Any charged particle will create a magnetic field around its path of travel. (And, conversely, it can be affected by an external magnetic field.) It could be the separation of charges that creates a magnetic dipole, as in an atom. (Positive nucleus with the negative electron cloud about it.) It could be the movement of electrons in a conductor. (Electric current flow in a wire.) One of the four basic forces in the universe is the electromagnetic force. Not the magnetic force, but the electromagnetic force. If there's no moving charge, there's no magnetic field. The two phenomenon are intrinsically connected.
Magnetic fields can be generated by either a permanent magnet, or generating it by electrical flow such as through a coil. If the magnet is then put near another material such as iron... the iron will then also start exhibiting an INDUCED magnetic field. Induction motors operate on this principle with the armature being non-magnetic... and the motor operates by inducing a magnetic field into the armature. Superconductors are unique that a magnet will induce an opposite magnetic field in them, and will be repulsed by the magnet.
When current is passed through a solenoid coil, magnetic field produced due to each turn of solenoid coil is in the same direction. As a result the resultant magnetic field is very strong and uniform. The field lines inside the solenoid are in the form of parallel straight lines along the axis of solenoid. Thus, the solenoid behaves like a bar magnet.
It sticks
No. No moon has strong magnetic fields that result in "poles" like Earth ... but they often do have weak magnetic fields.
WHEN A MAGNET IS DROPPED OR HAMMERED, VIBRATIONS CAUSED BY THE IMPACT ON THE MAGNET RANDOMIZE MAGNETIC MOLECULES and disturb the pattern of molecules of the magnet as a result magnet looses its magnetic force and becomes demagnetised.
Break in the circuit or loss of magnetic strength of the magnet can result in to no generation
Electromagnets possess a magnetic field that is a result of electrical current. When the current stops, the field will disappear also and hence we say that it is not permanent magnet. Magnetism is usually described as a result of one of three circumstances. It is a general law of physics that a magnetic field is created any time there is an electrical current. This is the way an electromagnet works. The so-called permanent magnets have a magnetic field that originates in the magnetic properties of the atoms that comprise the magnet and depends on the type and arrangement of the atoms. One can say the magnetism is a consequence of the material itself. Lastly, when electric fields are changing, such as in an AC circuit, magnetic fields are created as a consequence of the changing electric fields. This too is one of the basic laws of electromagnetic theory and a law of nature. This is not an effect that is easy to see, even in a laboratory setting, but it has important consequences which would take an explanation that goes outside of the topic of the current question.
Either the break in the circuit or loss magnetic strength of the magnet - can result into no generation
Your question is not quite crystal clear. However, a magnetic field is produced by a moving electric charge. Ordinarily, a current passing through a conductor will produce a magnetic field. In a fixed magnet, a group of the electrons has been organized so that their spins are aligned and this produces a permanent magnet. The Earth's magnetic field is the net result of a number of individual fields caused by electric currents generated in the hot interior of the mantle.
Not exactly. A CHANGING magnetic field, or a material moving through a magnetic field, will produce a VOLTAGE. This may or may not result in an actual current.
If one continously heats a particular magnet to high temperatures or long time or both, it loses it magnetism because the particles get excited and start forming no-magnetic arrangements.
A changing magnetic field, in the conductor, can induce a voltage (and, under the correct conditions, that in turn will result in a current). In the case of a permanent magnet, either the magnet or the conductor has to move.
the poles (north and south) create the magnetic fields Magnetic fields are, in the end, the result of the movement of electrostatic charges. Any charged particle will create a magnetic field around its path of travel. (And, conversely, it can be affected by an external magnetic field.) It could be the separation of charges that creates a magnetic dipole, as in an atom. (Positive nucleus with the negative electron cloud about it.) It could be the movement of electrons in a conductor. (Electric current flow in a wire.) One of the four basic forces in the universe is the electromagnetic force. Not the magnetic force, but the electromagnetic force. If there's no moving charge, there's no magnetic field. The two phenomenon are intrinsically connected.
Whatever it is that enables a magnet to push another magnet without ever touching it, is called the "magnetic field". It is an invisible attribute of a magnet that surrounds the magnet and exerts forces on other magnets and some non magnets, like iron.