Column I gives certain situations involving two thin conducting shells connected by a conducting wire via a key K. In all situations, one sphere has net charge +q and other sphere has not net charge. After the key K is pressed, column II gives some resulting effects. Match the figures in Column I with the statement in Column II.

Column-I gives certain situations involving two thin conducting shells connected by a conducting wire via a key K. In all situation one sphere has net charge +q and other sphere has no net charge. After the key K is pressed, column-II gives some resulting effect.

Two wire each carrying a steady current I are shown in four configurations in Column I. Some of the resulting effects are described in column II. Match the statements in Column I with the statements in Column II.

The circuit involves two ideal cells connected to a 1 mu F capacitor via a key K. Initially the key K is in position 1 and the capacitor is charged fully by 2V cell. The key is then pushed to position 2. Column I gives physical quantities involving the circuit after the key is pushed from position 1. Column II gives corresponding results. Match the statements in Column I with the corresponding values in Column II. {:(" Column I ",,,"Column II"),("(A) The net charge crossing the 4 volt cell in "mu"C is",,,"(p) 2"),("(B) The magnitude of work done by 4 Volt cell in " mu "J is",,,"(q) 6"),("(C) The gain in potential energy of capacitor in " mu "J is ",,,"(r) 8"),("(D) The net heat produced in circuit in " mu"J is ",,,"(s) 16"):}

Column I gives a situation in which two dipoles of dipole moment p hat(i) and sqrt(3)phat(j) are placed at origin. A circle of radius R with centre at origin is drawn as shown in figure. Column II gives coordinates of certain positions on the circle. Match the statements in Column I with the statements in Column II.

Column II gives some equations. In these equations x is distance, t is time , m is mass, v is velocity u is initial velocity and F is force . Match the statements in Column I to the equations in Column II.

In each situation of column-I, a circuit involving two non-ideal cells of unequal emf E_(1) and E_(2)(E_(1) gt E_(2)) and equal internal resistance r are given. A resistor of resistance R is connected in all four situations and a capacitor of capacitance C is connected in last two situations as shown. Assume battery can supply infinity charge to the circuit (r, R!=0, E_(1), E_(2)!=0 ). Four statements are given in column-II. Match the situation of column-I with statements in column-II.

Column-I gives physical quantities based on a situation in which an ideal cell of e.m.f. V is connected across a cylindrical rod of uniform cross-section area and conductivity ( sigma ) as shown in figure. E, J, phi and i are electric field, current density, electric flux and current through shaded cross-section respectively as shown in figure. Physical quantities in Column-II are equal to those in column I. Match the expression in Column-I with the statements in Column-II.

Column - I gives physical quantities of a situation in which a current I passes through two rods I and II of equal length that are joined in series. The ratio of free electron density (n), resistivity (rho) and corss - section area (A) of both are in ratio n_(1):n_(2)=2:1 and A_(1):A_(2)=1:2 respectively. Column II gives corresponding results. Match the ratios in the column I with the values in column II

Figure shows two conducting thin concentric shells of radii r and 3 r . The outer shell carries charge q and the inner shell is neutral . The amount of charge that flows from the inner shell to the earth after the key K is closed is equal to (1//n)^(th) of the charge on the outer shell. What is the value of n ? .

One mole of a monatomic ideal gas is taken through a cycle ABCDA as shown in the P-V diagram. Column II gives the characteristics involved in the cycle. Match them with each of the processes given in Column I.