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

A proton falls through a small distance in a uniform electric field of magnitude 1.8xx10^5N/C . The direction of the field is reversed keeping the magnitude unchanged and an electron falls through the same distance. The time of fall will be

An electron falls through a distance of 1.5 cm in a uniform electric field of magnitude 2.0xx10^(4) N C^(-1) . The direction of the field is reversed keeping its magnitude unchanged and a proton falls through the same distance. Compute the time of fall in each case. Contrast the situation with that of 'free fall under gravity'.

An electron falls through a distance of 1.5cm in a uniform electric field of magnitude 2 times 10^4 NC^-1 . The direction of the field is reversed keeping its magnitude unchanged and a proton falls through the same distance. Compute the time of fall in each case.

An electron falls through distance of 1.5 cm in a uniforth electric field of magnitude 2.0xx 10 ^(4) NC^(-1) The direction of the field is reversed keeping its magnitude unchanged and a proton falls through the same distance compute the time of falls in each case . Contrast the situation with that of 'free fall under gravity'

An electron falls throgh a distance of 1.5 cm in a uniform electric field of magnitude 2.0 xx10^(4) N c^(-1) the direction of the field is reversed keeping its magnitude unchanged and a proton falls through the same distance compute the time of falls in each case contrast the situation with that of free fall under gravity

An electron falls throgh a distance of 1.5 cm in a uniform electric field of magnitude 2.0 xx10^(4) N c^(-1) the direction of the field is reversed keeping its magnitude unchanged and a proton falls through the same distance compute the time of falls in each case contrast the situation with that of free fall under gravity

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.