Two balls of mass m and `2 m` each have momentum `2p` and p in the direction shown in figure. During collision they exert and impulse of magnitude p on each other.

`{:(,"Column I",,"Column II",),((A),"After collision momentum of m",(p),2p,),((B),"After collision momentum of 2m",(q),p,),((C ),"Coefficient of restituation between them",(r ),1,),(,,(s),"None",):}`

A particle of mass m, kinetic energy K and momentum p collision head on elastically with another particle of mass 2 m at rest. After collision. : {:(,"Column I",,"Column II",),((A),"Momentum of first particle",(p),3//4 p,),((B),"Momentum of second particle",(q),-K//9,),((C ),"Kinetic energy of first particle",(r ),-p//3,),((D),"Kinetic energy of second particle",(s),(8K)/(9),),(,,,"None",):}

If net force on a system of particles is zero. Then {:(,"Column I",,"Column II",),((A),"Acceleration of centre of mass",(p),"Constant",),((B),"Velocity of centre of mass",(q),"Zero",),((C ),"Momentum of centre of mass",(r ),"May br zero",),((D),"Velocity of an individual particle of the system",(s),"May be constant",):}

A particle of mass 1 kg has velocity vec(v)_(1) = (2t)hat(i) and another particle of mass 2 kg has velocity vec(v)_(2) = (t^(2))hat(j) {:(,"Column I",,"Column II",),((A),"Netforce on centre of mass at 2 s",(p),(20)/(9) unit,),((B),"Velocity of centre of mass at 2 s",(q),sqrt68 " unit",),((C ),"Displacement of centre of mass in 2s",(r ),(sqrt80)/(3) "unit",),(,,(s),"None",):}

Match Column-I with Column-II : {:("Column-I","Column-II"),("(1) Change in momentum","(a) Force"),("(2) Rate of change of momentum","(b) Impulse of force"),(,"(c) Momentum"):}

Collsion between ball and block A is perfectly inelastic as shown. If impulse on ball (at the time of collision ) is J then {:(,"Column I",,"Column I",),((A),"Net impulse on block A is",(P),J,),((B),"Net impulse on block B is",(Q),4J//9,),((C ),"Impulse due to rigid support Y is",(R ),16J//9,),((D),"Impulse due to rigid support X is",(S),2J//9,),(,,(T),J//9,):}

In the figure shown P is a point on the surface of an imaginary sphere. {:(,"Column-I",,,"Column-II"),((A),"Electric field at point P",,(p),"due to "q_(1) "only"),((B),"Electric flux through a small area at P",,(q),"due to "q_(2)"only"),((C),"Electric flux through whole sphere",,(r),"due to both "q_(1) and q_(2)):}

sqrtv versus Z graph for characteristic X-rays is as shown in figure. Match the following : {:(,"Column I",,"Column II"),((A),"Line-1",(p),L_(alpha)),((B),"Line-2",(q),L_(beta)),((C),"Line-3",(r),K_(alpha)),((D),"Line-4",(s),K_(beta)):} .

A particle is rotating in a circle of radius 1m with constant speed 4 m//s . In time 1s, match the following (in SI units) {:(,"Column I",,,"Column II"),((A),"Displacement",,(p),8 sin 2),((B),"Distance",,(q),4),((C),"Average velocity",,(r),2sin 2),((D),"Average acceleration",,(s),4 sin 2):}

For one mole of a monoatomic gas :- {:(,"Column-I",,"Column-II"),((A),"Isothermal bulk modulus, ",(p),-(RT)/(V^(2))),((B),"Adiabatic bulk modulus ",(q),-(5P)/(3V)),((C),"Slope of P-V graph in isothermal process " ,(r),"T/V"), ((D), "Slope of P-V graph in adiabatic process",(s),"4T/3V"),(,,(t),"None"):}

A smooth ball A of mass m is attached to one end of a light inextensible string, and is suspended form fixed point O. Another identical ball B, is dropped from a heigh h, so that the string just touches the surface of the sphere. {:(,"Column I",,"Column I",),((A),"If collision between balls is completely elastic then speed of ball A just after collision is",(P),(3m)/(5) sqrt(2gh),),((B),"If collision between balls is completely elastic then impulsive tension provided by string is",(Q),(sqrt6gh)/(5),),((C ),"If collision between balls is completely inelastic then speed of ball A just after collision is",(R ),(6m)/(5) sqrt(2gh),),((D),"If collision between balls is completely inelastic then impulsive tension provided by string is",(S),(2sqrt(6gh))/(5),),(,,(T),"None of these",):}