An electron falls from rest through a vertical distance h in a uniform and vertically upwards directed electric field E. The direction of electric field is now reversed , keeping its magnitude the same. A proton is allowed to fall from rest in it through the same vertical distance h. The time of fall of the electron, in comparison to the time of fall proton is

An electron falls through a small distance in a uniform electric field of magnitude 2xx10^(4)NC^(-1) . The direction of the field reversed keeping the magnitude unchanged and a proton falls through the same distance. The time of fall will be

An electron (mass m_(e ) )falls through a distance d in a uniform electric field of magnitude E. , The direction of the field is reversed keeping its magnitudes unchanged, and a proton(mass m_(p) ) falls through the same distance. If the times taken by the electrons and the protons to fall the distance d is t_("electron") and t_("proton") respectively, then the ratio t_("electron")//t_("proton") .

An electron falls through a distance of 1.5 cm in a uniform electric field of magnitude 2.4xx10^(4) NC^(-1) [Fig.1.12 (a)] . The direction of the field is reversed keeping its magnitude unchagned and a proton falls through the same distance [Fig. 1.12 (b) ]. Complute the time of fall in each case. Contrast the situation (a) with that of free fall under gravity.

An electron and a proton travel through equal distances in the same uniform electric field E. Compare their time of travel. (Neglect gravity)

A stone is allowed to fall freely from rest. The ratio of the time taken to fall through the first metre and the second metre distance is

A small drop of water falls from rest through a large height h in air, the final velocity is