A charge particle `(!=10^(-4)C)` is released from rest at `z=0` in magnetic fiedl given as `vecB=B_(0)cos(omegat+kz)hatj` where `B_(0)=3xx10^(-5)T` and `B_(1)=2xx10^(-6)T`. Then the rms alue of force acting on particle is?

If B_H=4xx10^(-5)T and B_(V)=2xx10^(-5)T, then the Earth's total field (in T) at the place is

The magnetic field of a plane electromagnetic wave is given by: vec(B)=B_(0)hat(i)[cos(kz- omegat)]+B_(1)hat(j)cos(kz+omegat) where B_(0)=3xx10^(-5)T and B_(1)=2xx10^(-6)T . The rms value of the force experienced by a stationary charge Q=10^(-4)C at z=0 is close to:

The magnetic field of a plane electromagnetic wave is given by: vec(B)=B_(0)hat(i)-[cos(kz- omegat)]+B_(1)hat(j)cos(kz+omegat) where B_(0)=3xx10^(-5)T and B_(1)=2xx10^(-6)T . The rms value of the force experienced by a stationary charge Q=10^(-4)C at z=0 is close to:

A particle of mass 10^(-3) kg and charge 1.0 c is initially at rest At time t=0 the paritcle comes under the influence of an electric field hat (E )(t)=E_(0) sin omega t hat(i) where E_(0) =1.0 N C^(-1) and omega =10^(3) rad s^(-1) consider the effect of only the electrical force on the particle .Then the maximum speed in m s^(-1) attained by the paritcle at subsequent times is ______________

The magnetic field in a plane electromagnetic wave is given by B_(y) = 2 xx 10^(-7) sin (0.5 xx 10^(3)x + 1.5 xx 10^(11) t) . This electromagnetic wave is

A particle of mass 1 g and charge 2. 5 xx10^(-4) C is released from rest in an electric field of 1.2 xx 10^4 NC^(-1) (a) Find the electric force and the force of gravity acting on this particle. Can one of these forces be neglected in comparison with the other for approximate analysis? (b) How long will it take for the particle to travel a distance of 40 cm? (c) What will be the speed of the particle after travelling this destance? (d) how much is the work done by electric force on the particle during this period?

A charged particle (q.m) released from origin with velocity v=v_(0)hati in a uniform magnetic field B=(B_(0))/(2)hati+(sqrt3B_(0))/(2)hatJ . Maximum z-coordinate of the particle is

Magnetic force on a charged particle is given by vec F_(m) = q(vec(v) xx vec(B)) and electrostatic force vec F_(e) = q vec (E) . A particle having charge q = 1C and mass 1 kg is released from rest at origin. There are electric and magnetic field given by vec(E) = (10 hat(i)) N//C for x = 1.8 m and vec(B) = -(5 hat(k)) T for 1.8 m le x le 2.4 m A screen is placed parallel to y-z plane at x = 3 m . Neglect gravity forces. The speed with which the particle will collide the screen is

A charged partical having a charge of -2.0 xx 10^(-6) C is placed close to a nonconducting plate having a surface charge density 4.0 xx 10^(-6) C m^(-2). Fine the force of attraction between the particle and the plate.

A charged particle (q.m) released from origin with velocity v=v_(0)hati in a uniform magnetic field B=(B_(0))/(2)hati+(sqrt3B_(0))/(2)hatJ . Pitch of the helical path described by the particle is