The particle of mass m and charge q will touch the infinitely large of uniform charge density `sigma` if its velocity v is more than : `{"Given that "sigmaq gt 0}`

A charged particle of mass m & charge q enters a zone of uniform magnetic field B with a velocity v making an angle theta with the boundary of the zone, having width d , when the particle penetrates half-way into the zone, the change in energy of the particel is

A small charged particle of mass m and charge q is suspended by an insulated thread in front of a very large conducting charged sheet of uniform surface density of charge sigma . The angle made by the thread with the vertical in equilibrium is

A charge particle q is released at a distance R_(@) from the infinite long wire of linear charge density lambda . Then velocity will be proportional to (At distance R from the wire)

A particle of mass m and charge q is thrown in a region where uniform gravitational field and electric field are present. The path of particle:

A particle of mass m and charge q is lying at the origin in a uniform magnetic field B directed along x-axis. At time t = 0, it is given a velocity v_0 , at an angle theta with the y-axis in the xy-plane. Find the coordinates of the particle after one revolution.

A charge particle of mass m and charge q is released from rest in uniform electric field. Its graph between velocity (v) and distance travelled (x) will be :

A charge particle of mass m and charge q is released from rest in uniform electric field. Its graph between velocity (v) and distance travelled (x) will be :

A particle of mass m and charge Q moving with a velocity v enters a region on uniform field of induction B Then its path in the region is s

Two thin infinite parallel plates have uniform charge densities + sigma and - sigma . The electric field in the space between them is

A charge particle of mass m and charge q is projected with velocity v along y-axis at t=0. Find the velocity vector and position vector of the particle vec v (t) and vec r (t) in relation with time.