In the previous question, in place of disc a ring is used whose inner radius is `R_(1)` and outer radius is `R_(2)` Now how much extra weight should be added on the other side, so that the ring can just come out of water ?

A metallic spherical shell has an inner radius R_(1) and outer radius R_(2) . A charge is placed at the centre of the spherical cavity. The surface charge density on the inner surface is

A disc has mass 'M" and radius 'R'. How much tangential force should be applied to the rim of the disc so as to rotate with angular velocity omega in time 't'?

A thin capillary of inner radius r_(1) and outer radius r_(2) (The inner tube is solid) is dipped in water. To how much height will the water raise in the tube ? (Assume contact angle theta rarr 0 )

A spherical conducting shell of inner radius r_(1) and outer radius r_(2) has a charge Q. (a) A charge q is placed at the center of the shell. What is the surface charge density on the inner and outer surfaces of the shell ? (b) Is the electric field intensity inside a cavity (with no charge) zero, even if the shell is not spherical, but has any irregular shape ? Explain.

A charge Q is kept at the centre of a conducting sphere of inner radius R_(1) and outer radius R_(2) . A point charge q is kept at a distance r(gt R_(2)) from the centre. If q experiences an electrostatic force 10 N then assuming that no other charges are present, electrostatic force experienced by Q will be :

A metal spherical shell has an inner radius R_(1) and outer radius R_(2) . A charge Q is placed at the center of the spherical cavity. What will be surface charge density on (i) the inner surface, and (ii) the outer surface ?

A horizontal cylinder is fixed, its inner surface is smooth and its radius is R. A small block is initially at the lowest point. The minimum velocity that should by given to the block at the lowest point, so that it can just cross the point P is u then

Inside a conducting hollow sphere of inner radius R_(1) and outer radius R_(2) , a point charge q is placed at a distance x from the center as shown in fig. Find. . (i) electric potential at C (ii) electric field and potential at a distance r from the center outside the shell.

An uncharged conductor of inner radius R_(1) and outer radius R_(2) constains a point charge q at the centre as shown in figure (i) Find vec(E) and V at points A, B and C (ii) If a pint charge Q is kept out side the sphere at a distance 'r' ( gt gt R_(2)) from centre then find out resultant force on charge Q and charge q.

Define mutual inductance between two long coaxial solenoids. Find out the expression for the mutual of inner solenoid of length 1 having the radius r_(1) and the number of turns n_(1) per unit length due to the second other solenoid of same length and n_(2) number of turns per unit length.