The rule for the interaction between the magnetic poles is similar to the interaction between the electrical charges in terms of the attraction and repulsion. In both cases the unlike poles attract while the like poles repel.
Like charges, and like poles, repel each other; different charges, and different poles, attract each other.
Like charges, and like poles, repel each other; different charges, and different poles, attract each other.
Like charges, and like poles, repel each other; different charges, and different poles, attract each other.
Like charges, and like poles, repel each other; different charges, and different poles, attract each other.
it cahnges the magnet by making it reach to the top
Like charges, and like poles, repel each other; different charges, and different poles, attract each other.
the dipole interaction between them
The strength of the magnet can be measured by the strength of flux density produce by its magnetic field in reference to a determine distance. This can be measured by the use of a Gauss Meter . The unit of measure is gauss( centimeter-gram- second or maxwell per square centimeter).By: Frederick de LeonElectronics & Acoustic Design EngineeringMeadow ParkLaboratoriesBK10, Lt 5, Meadow ParkMolino 4, Bacoor, Cavite, Philippines4102Cellphone: +639175271849Email: freddiedeleon@gmail.com
Magnetic Forcenounattraction for iron; associated with electric currents as well as magnets; characterized by fields of force [syn: magnetism]
Magnetic field strength (H) is defined as the magnetomotive force per unit length, and is expressed in amperes per metre (often spoken as 'ampere turns per metre') in SI. An older, and far more descriptive term, is 'magnetomotive force gradient'.The 'closeness' or intensity of a magnetic field's flux lines, on the other hand is termed magnetic flux density(B), expressed in teslas in SI.There is a complex relationship between magnetic field strength and flux density, because of a property exhibited by ferromagnetic materials, called 'hysteresis'. In general, as the magnetic field strength applied to a sample of unmagnetised ferromagnetic material increases, the resulting flux density also increases (but not linearly) until saturation is reached, at which point any further increase in magnetic field strength will have no effect whatsoever on the flux density. If the magnetic field strength is then reduced, the flux density will also reduce (again, not linearly), but when the magnetic field strength reaches zero amperes, a certain amount of flux density remains.So to answer your question, you really need to study what's known as the B-H or magnetising curve for a sample of ferromagnetic material -this will show you exactly what the relationship between magnetic field strength and flux density for any give ferromagnetic material.
The magnetic force between currents moving in the oppoiste directions is repulsive.
A moving charge (or an electron) has a magnetic field around it. When it is moved in an external magnetic field in such a way that its direction of motion is not parallel to applied magnetic field. then both the fields interact to produce a FORCE on electron.Or you may say that A moving charge, when placed in a magnetic field , experiences a force given by:F=q(V*B) .In this equation, a CROSS PRODUCT is present between velocity "V" and magnetic strength "B" , SO direction of resultant force is at right angle to both V and B. hence force acts at angle of 90 degrees to displacement and hence does no work to change its speed. For more details, contact at saqibahmad81@yahoo.com
Magnetic flux through a loop is just a measurement of the strength of the magnetic field passing through the loop, and since magnetic field strength is directly related to magnetic force, magnetic force is directly related to the magnetic flux passing through the loop.
Pole strength is ability of poles to produce lines of force where is field strength is force which a magnetic poles experiences when places in magnetic field.
Magnetic force is inversely proportional to the square of the distance from the magnet which generates it.
It's an electrical force that causes strength to a magnetic appearance .
The force is just one aspect of magnetism. For example, there is a magnetic field all around a magnet. Of course they are related, but "magnetism" is a wider term for the entire phenomenon - it may relate to the force, to the magnetic field, or to a few other things.
Not at all
Provide amoving magnetic force field.
they are inversely related. as the distance increases the magnetic attraction decreases and when the distance decreases the magnetic attraction increases.
Zero - that is, when they are touching. The strength of the magnetic force is inversely proportional to the square of the distance between the magnet and the paper clip.
Magnetic force is the force exerted between magnetic poles, producing magnetization of force, either of attraction or of repulsion.
-- A current flowing through a conductor creates a magnetic field around the conductor. -- Moving a conductor through a constant magnetic field creates a current in the conductor. -- If there's a conductor sitting motionless in a magnetic field, a current flows in the conductor whenever the strength or direction of the magnetic field changes.
loser sex