Let V and E denote the gravitational potential and gravitational field at a point. Then, match the following columns
`{:(,"Column-I",,"Column-II"),("(A)",E = 0","V = 0,"(p)","At centre of spherical shell"),("(B)",E ne0","V=0,"(q)","At centre of solid sphere"),("(C)",V ne0","E=0,"(r)","At centre of circular ring"),("(D)",V ne0","E ne0,"(s)","At cetre of two point masses of equal magnitude"),(,,"(t)","None"):}`

Let V and E denote the gravitational potential and gravitational field at a point. It is possile to have

In the diagram shown in figure mass of both the balls in same. Match the following columns. {:("Column1","Column2"),("A For" v^(')=v,"P e=0"),("B For" v^(')=v//2,"Q e=1"),("C For" v^(')= 3//4v,"R e=1/2"),("-","(S data is insufficient"):}

A disc rolls on ground without slipping. Velocity of centre of mass is v . There is a point P on circumference of disc at angle theta . Suppose, v_(P) is the speed of this point. Then, match the following columns {:(,"Column-I",,"Column-II"),("(A)","If" theta=60^(@),"(p)",v_(P)=sqrt(2)v),("(B)","If" theta=90^(@),"(q)",v_(P)=v),("(C)","If" theta=120^(@),"(r)",v_(P)=2v),("D)","If" theta=180^(@),"(s)",v_(P)=sqrt(3)v):}

In the circuit shown in figure, E = 10 V, r = 1Omega , R = 4Omega and L = 5H. The circuit is closed at time t = 0. Then, match the following two columns. {:(,"Column I",,"Column II"),(A.,V_(AD)" at t = 0",p,4 V),(B.,V_(BC)" at t = 0",q,8 V),(C.,V_(AB)" at t ="oo,r.,0V),(D.,V_(AD)" at t"=oo,s.,10V):}

Let V_(0) be the potential at the origin in an electric field vecE=E_(x)hati+E_(y)hatj . The potential at the point (x,y) is

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"):}

Given that the gravitation potential on Earth surface is V_(0) . The potential at a point distant half the radius of earth from the cetre will be

{:(,"Column I",,"Column II"),(("A"),R//L,(p),"Time"),(("B"),C//R,(q),"Frequency"),(("C"),E//B,(r),"Speed"),(("D"),sqrt(epsilon_(0)mu_(0)),(s),"None"):}

Let V and E represent the gravitational potential and field at a distance r from the centre of a uniform solid sphere. Consider the two statements. A. the plot of V agasinst r is discotinuous B. The plot of E against r is discontinuous.

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)):}