A charged cork ball of mass m is suspended on a light sting in the presence of a uniform electric field as shown in fig. When `E=(A hat i+B hat j)NC^(-1)`, Where A and B positive numbers, the ball is in equilibirum at `theta`. Find (a) the charge on the ball and (b) the tension in the string.

A charged cork of mass m suspended by a light string is placed in uniform electric field filed of strength E = (hati+hatj) xx 10^(5)NC^(-1) as shown in the figure. If in equilibrium position tension in the string is 2mg//(1+sqrt3) the angle alpha with the vertical can be

A charged cork ball having mass of 1 gram and charge q is suspended on a light string in a uniform electric field as shown in the figure. The ball is in equilibrium at 0=37^(@) , when value of electric field is vecE=(3hati+5hatj)xx10^(5)N//C . Assume T as tension in the string. Which of the following options are correct? (Given sin37^(@)=0.60andg=10m//s^(2) )

A charged ball of mass 9 kg is suspended from a string in a uniform elelctric field vecE = (3hati + 5hatj) xx 10^5 N//C . The ball is in equilibrium with theta=37^@ . If direction of electric field is reversed, find the new equilibrium position of the ball. Given your answer in terms of angle made by string with vertical. Take g = 10ms^(-2) .

A positively charged particle is moving along the positive x-axis in a unifom electric field vec E= E_0hatj and magnetic field vec B = B_0hat k (where E_0 and B_0 are positive constants), then

A charged ball of mass 5.88xx10^(-4) kg is suspended from two silk strings of equal lengths so that the strings are inclined at 60^(@) with each other. Another ball carrying a charge which is equal in magnitude but opposite in sign of the first one is placed vertically below the first one at a distance of 4.2xx10^(-2) m . Due to this, the tension in the strings is doubled. Determine the charge on the ball and the tension in the strings after electrostatic interaction. (g=9.8 m//s^(2))

A ball of mass m is released from A inside a smooth wedge of mass m as shown in figure. What is the speed of the wedge when the ball reaches point B?

A ball of mass m with a charge q can rotate in a vertical plane at the end of a string of length l in a uniform electrostatic field whose lines of force are directed upwards. What horizontal velocity must be imparted to the ball in the upper position so that the tension in the string in the lower position of the ball is 1.5 times than the weight of the ball?

A small ball B of mass m is suspended with light inelastic string of length L from a block A of same mass in which can move on smooth horizontal surface as shown in the figure. The ball is displaced by angle theta from equilibrium position and then released. Tension in string when it is vertical, is

A small ball of masss m and charge +q tied with a string of length l, rotating in a veticle circle under gravity and a uniform horizontal electric field E as shown. The tension in the string will be minimum for

In uniform electric field, E = 10 NC^(-1) as shown in figure, find (i) V_(A)-V_(B) (ii) V_(B)-V_(C) .