A the mill produces a diminishing percentage of finished material as the new feed rate increases. To maintain the same product distribution, the coarser mill …
We begin with some mathematical tools for dealing with moving charge, keeping in mind the observed physical law that charge is neither created nor destroyed.
During the charge's motion, it experiences a magnetic force just like an other particle experiences centripetal force undergoing uniform circular motion. When the particle enters the magnetic field, it deviates from its path, which changes the direction …
We know that moving charge in constant velocity has deformed equation of electric field. $$ E = k frac{1-left(frac{v}{c}right)^2}{left[1-frac{v^2 …
Calculate the radius of curvature of the path of a charge that is moving in a magnetic field. Magnetic force can cause a charged particle to move in a circular or spiral path. Cosmic …
The force on a charged particle due to an electric field is directed parallel to the electric field vector in the case of a positive charge, and anti-parallel in the case of a negative charge. …
Motion of Charged Particles in Magnetic Fields. Circulating Charges (Charge +q in a uniform magnetic field) r v =. m qB. Since the particle is tracing out a circle of radius of r, …
Electrical current is defined to be the rate at which charge flows. When there is a large current present, such as that used to run a refrigerator, a large amount of charge moves …
The law of conservation of charge says that electrical charge cannot be created or destroyed. The law of conservation of charge is very useful. It tells us that the net charge …
A point charge $q$ is moving in a circular path of radius $r$ with constant linear velocity $v$. We are asked to find the current associated with this circular motion. …