An electron enters an electric field having intensity `vecE=3hati+6hatj+2hatkVm^(-1)` and magnetic field having induction `vecB=2hati+3hatjT` with a velocity `vecV=2hati+3hatjms^(-1)` the magnitude of the force acting on the electron is (Givene=`-1.6xx10^(-19)C)`

An electron enters an electric field having intensity vecE=3hati+6hatj+2hatkV.m^(-1) and a magnetic field having induction vecB=2hati+3hatjT with a velocity vecv=2hati+3hatjm.s^(-1) . The magnitude of the force acting on the electron is (Given e=-1.6xx10^(-19)C )

A electron is moving with a velocity vecv=(hati+2hatj)m.s^(-1) in the magnetic field vecB=(2hati+2hatj)Wb.m^(-2) . Determine the magnitude and direction of the force acting on the electron. Charge of an electron is -1.6xx10^(-19)C.

An electron enters a magentic field of 3T at an angle of 30^(@) with a velocity of 10^(6)m.s^(-1) . What force will act on the electron? e=1.6xx10^(-19)C

The dipole moment of an electric dipole is given by vecp=10^(-7)(5hati+hatj-2hatk)cm . The dipole is kept in an electric field of intensity, vecE=10^(7)(hati+hatj+hatk)V.m^(-1) . Obtain the magnitude of torque acting on the dipole.

Calculate the force acting on an electron moving with a velocity (3hati+3hatj)m.s^(-1) in a magnetic field of strength (2hatj+3hatk) tesla.

In a region, the intensity of an electric field is given by vecE=2hati+3hatj+hatk in NC^(-1) . The electric flux through a surface vecS=10hatim^(2) in the region is

In a region, a uniform electric field of 100V.m^(-1) is acting along x-axis and a uniform magnetic field of 10^(-4)T along y-axis. If an electron enters that region along z-axis with a velocity of 10^(5)m.s^(-1) , determine the magnitude and direction of the force acting on it. Charge of an electron =1.6xx10^(-19)C .

What will be the electric flux passing through the area vecS=10hati placed in an electric field of intensity vecE=3hati+4hatj+5hatk ?

veca = 3hati + 3hatj - hatk and vecb = 2hati + 6hatj + mhatk are perpendicular to each other , then the value of m is