A uniform electric field of `20NC^(-1)` exists in the vertically downward direction. Determine the increase in the electric potential as one goes up through a height of 50 cm.

A Uniform electric field of 10NC ^(-1) exists in the vertically downward direction. Find the increase in the electric potential as one goes up through a height of 50cm.

A uniform electric field of 20 N/C exists in the vertically downward direction. Find the increase in the electric potential as one goes up through a height of 40 cm.

A uniform magnetic field of 0.20 xx 10^(-3) T exists in the space. Find the the change in the magnetic scalar potential as one moves through 50cm along the field.

A uniform electric field of 200NC^-1 exists in space in the X-direction. Calculate the flux of this field through a plane square area of edge 10 cm placed in the Y-Z

An electron moving horizontally enters in a uniform electric field of intensity 100 V/m directed vertically downwards . The upward displacement of the electron at the end of 0.02 mu s is

A particle of mass an charge q is projected vertically upwards .A uniform electric field vec(E) is acted vertically downwards.The most appropiate graph between potential energy U (gravitaion plus eelectrostatic) and height h(lt lt radius of earth) is :(assume U to be zero on surface of earth)

A proton falls dwon through a distance of 2 cm in a uniform electric field of magnitude 3.34xx10^(3) NC^(-1) . Determine (i) the acceleration of the electron (ii) the time taken by the proton to fall through the distance of 2 cm, and (iii) the direction of the electric field.

An electric dipole of dipole moment 4xx10^(-5) Cm is placed in a uniform electric field of 10^(-3) N//C making an angle of 30^(@) with the direction of the field. Determine the torque exerted by the electric field on the dipole.

A uniform electric field of 30NC^(-1) exists along the X-axis calculate the potential difference V_(B)-V_(A) between the points A (4m,2m) and B(10m,5m).