Name the types of interaction or intermolecular forces of which potential energy-distance function are given below
(a) `Eprop (1)/ (r ) ` (b) `E prop (1)/(r^(2))` (c ) `E prop (1)/(r^(3))`
(d) `E prop (1)/(r^(4))` (e) `E prop (1)/(r^(6))` .

Which of the following intermolecular forces have a potential energy distance function as E prop (1)/(r^(2)) (i) Ion -dipole (ii) Dipole -dipole (iii) Ion -induced dipole (iv) London dispersion forces .

Match the type of interaction in column A with the distance dependence of their interaction energy in column B : {:(,A,,B),((I),"ion-ion",(a),(1)/(r)),((II),"dipole-dipole",(b),(1)/(r^(2))),((III),"London dispersion",(c),(1)/(r^(3))),(,,(d),(1)/(r^(6))):}

Column I shows charge distribution and column II shows electrostatic field created by that charge at a point r distance from its centre. {:(,"Column I ",,"Column II"),((A),"A stationary point charge",(p),E prop r^(0)),((B),"A stationary uniformly long charge rod",(q),Eprop r^(1)),((C ), "A stationary electric dipole",(r ),E prop r^(*-1)),,(s),E prop r^(-2) ),(,,(t ),E propr^(-3)):}

The electirc potential between a proton and an electron is given by V = V_0 ln (r /r_0) , where r_0 is a constant. Assuming Bhor model to be applicable, write variation of r_n with n, being the principal quantum number. (a) r_n prop n (b) r_n prop (1)/(n) (c ) r_n^2 (d) r_n prop (1)/(n^2)

Draw E-r and V-r graphs due to two charged spherical shells as shown in figure (along the line between C and prop )

Study the graph given below and choose the option that is correctly describing the relationship between dissolved oxygen (DO) and biochemical oxygen demand (BOD) : (a) DO prop 3BOD (b) DO prop 2BOD (c) DO prop 1/(BOD) (d) DO prop BOD

For x in R , lim_(xrarroo)((x-3)/(x+2))^x is equal to (a) e (b) e^(-1) (c) e^(-5) (d) e^5

Assume that the force of gravitation F prop 1/(r^(n)) . Then show that the orbital speed in a circular orbit of radius r is proportional to 1/(r^((n-1)//2)) , while its period T is proportional to r^((n+1)//2)

In the given circuit, if the potential difference across the internal resistance r_1 is equal to E, then the resistance R is equal to:

Assertion : For a first order reaction, t_(1//2) is indepent of rate constant. Reason : For a first reaction t_(1//2) prop [R]_(0) .