A conducting bubble of radius a, thickness t (t << a) has potential V. Now, the bubble collapses into a droplet. The potential of the droplet will be:

A conducting bubble of radius a, thickness t ( lt lt a) has a potential V. Now the bubble transforms into a droplet. Find the potential on the surface of the droplet.

A conducting liquid bubble of radius a and thickness t ( tltlt a) is charged to potential V . If the bubble collapses to a droplet , find the potential on the droplet .

A soap bubble of radius R = 3 cm and thickness t = 10^(-2) mm is charged to a potential of V = 0.3 volt. The bubble burst and falls as a spherical drop. Determine the potential of the drop

A soap bubble has radius R and thickness d(ltltR) as shown. It colapses into a spherical drop. The ratio of excess pressure in the drop to the excess pressure inside the bubble is

A circular conducting coil of radius T_0 , having resistance R is placed in a time varying transverse uniform magnetic field B=4t^2 as shown in the figure. The current in the coil at time t = 2 s is (consider all quantities are in Si units)

A dielectric slab of thickness t of dielectric constant k and a conducting plate of same thickness is inserted between two parallel conducting plates of cross -section area A and charge q and -q as shown in figure. The distance between two plates is 5t . The potential -distance (V-x) graph will be (Consider potential of positive plate is V_0 and position x=0 , E_0 is electric field in free space)

A conducting loop of radius R is present in a uniform magnetic field B perpendicular to the plane of the ring. If radius R varies as a function of time t, as R =R_(0) +t . The emf induced in the loop is

A capacitor is made of two circular plates of radius R each, separated by a distance dltltR . The capacitor is connected to a constant voltage. A thin conducting disc of radius r ltlt R and thickness t ltlt r is placed at a center of the bottom plate. Find the minimum voltage required to lift the disc if the mass of the disc is m.

A conducting circular loop of radius a and resistance R is kept on a horizontal plane. A vertical time varying magnetic field B=2t is switched on at time t=0. Then

A long thick conducting cylinder of radius 'R' carries a current uniformly distributed over its cross section :