Two conducting circular loops of radii `R_1 and R_2` are placed in the same plane with their centres coincidingt. Find the mutual inductane between them assuming `R_2ltltR_1`.

Two concentric circular coils, one of small radius r_(1) and the other of large radius r_(2) , such that r_(1)ltltr_(2) , are placed co-axially with centres coinciding. Obtain the mutual inductance of the arrangement.

Two thin metallic spherical shells of radii r_(1) and r_(2) (r_(1)lt r_(2)) are placed with their centres coinciding. A material of thermal conductivity K is filled in the space between the shells. The inner shells is maintained at temperature theta_(1) .and the outer shell at temperature theta_(2) (theta_(1)lt theta_(2)) . Calculate the rate at which heat flows radially through the material.

Two circles with r_1=6.3cm and r_2=3.7cm touch externally. What is the distance between their centres?

A solenoid S_1 is placed inside another solenoid S_2 as shown in the fig. The radii of the inner and the outer solenoids are r_1 and r_2 respectively and the numbers of turns per unit length are n_1 and n_2 respectively. Consider a length I of each solenoid. Calculate the mutual inductance between them.

Two identical solid copper sphere of radius R are placed in contact with each other. The gravitational force between them is proportional to.

Two isolated, charged coducting spheres of radii R_(1) and R_(2) produce the same electric field near their surfaces. The ratio of electric potentials on their surfaces is

Two charged spherical conductors of radii R_(1) and R_(2) are connected by a wire. Then the ratio of surface charge densitites of the spheres sigma_(1)//sigma_(2) is

Two cells of emf E_1 and E_2 are joined in opposition (such that E_1>E_2 ). If r_1 and r_2 be the internal resistances and R be the external resistance, then the terminal potential difference is: