Match the following
`{:(,"Column I",,"Column II"),((A),E prop (1)/(r^(2)),(p),"Point charge"),((B),E prop r,(q),"Spherically symmetric charge distribution"),((C ),V prop (1)/(r ),(r ),"Long line charge"),((D),V_(2)-V_(1)=f((r_(2))/(r_(1))),(s),"Plane sheet of charge"),((E ),V_(2)-V_(1) prop r_(2)-r_(1),(t ),"Electric dipole"):}`

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)):}

[" Consider a spherical symmetric "],[" charge distribution with charge "],[" density varying as "],[[rho={[rho_(0)(1-(r)/(R)),r R]]

Consider a spherical symmetric charge distribution with charge density varying as rho={[rho_(0)(1-(r)/(R)),r R]} The electric field at r , r le R will be

{:(,"Column I",,"Column II"),((A),"Isothermal process",(p),q=DeltaU),((B),"Adiabatic process",(p),w=-pPDeltaV),((C ),"Isobaric process",(r),w=DeltaU),((D),"Isochoric process",(s),w=nRT ln(V_(2)//V_(1))):} (a) A -s,B-q,C-r,D-p (b) A-s,B-r,C-q,D-p (c ) A-p, B-r,C-q,D-s (d) A-r,B-p,C-s,D-q

On the surface of earth acceleration due gravity is g and gravitational potential is V. Match of following columns {:(,"Column-I",,"Column-II"),("(A)","At height h=R, value of g","(p)","Decreases by a factor" (1)/(4)),("(B)","At depth " h =(R)/(2)"," "value of g","(q)","Decrease by a factor" (1)/(2)),("(C)","At height "h=R",""value of V","(r)","Increase by a factor" (11)/(8)),("(D)","At height "h=(R)/(2)"," "value of V","(s)","Increase by a factor 2"),(,,"(t)","None"):}

A particle is moving on a straight line. It is initially at rest v= instantaneous velocity P = instantaneous power S = displacement F= force t = time Match the possible expression of the quantities in column-1 with the situation in column-2 {:(,"Column-1",,"Column-2"),("(A)",v^(3) prop S,"(P)","P = constant"),("(B)",v^(2) prop t,"(Q)",P prop v),("(C)",v^(2) prop S,"(R)","F = constant"),("(D)",v prop t,"(S)",F prop (1)/(v)),(,,"(T)",P prop t):}

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)) .

Match the half-life in Column-I with the order in Column-II : Column-I ( Half- life) Column-II ( order) ( A ) t_(1//2) = constant ( p ) First order ( B) t_(1//2) prop a ( q ) Pseudo first order ( C ) t_(1//2) prop ( 1)/( a) (r) Second order ( D ) t_(1//2) prop p^(-1) (s) Zero order where a = Initial concentration of the reactant p = Initial pressure of the reactant

nto Orbit no , zto Atomic no implies r_(n.z)to Radius v_(n.z)to Velocity T_(n.z)to Time period of Revolution implies K_(n.z)to kinetic energy of the electron {:("Column-I","Column-II"),("(for single electron species)","(Ratio)"),((A)r_(2,1):r_(1,2),(P)"9:1"),((B)V_(1,3):V_(3,1),(Q)"8:1"),((C )T_(1,2):T_(2,1),(R)"16:1"),((D)K_(1,2):K_(2,1),(S) "1:32"):}

Consider two concentric spherical metal shells of radii r_(1) and r_(2) (r_(2) gt r_(1)) . Find the charge on the inner shell and charge distribution.