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"):}`

Match the following: {:(,"Column-I",,"Column-II"),((A),"Isobaric process",(p),"No heat exchange"),((B),"Isothermal process ",(q),"Constant pressure"),((C),"Isoentropy process",(r),"Constant internal energy"),((D),"Isochoric process",(s),"Work done is zero"):}

The straight lines in the figure depict the variations in temperature DeltaT as a function of the amount of heat supplied Q is different process involving the change of state of a monoatomic and a diatomic ideal gas . The initial states, ( P,V,T ) of the two gases are the same . Match the processes as described, with the straight lines in the graph as numbered. {:(,"Column-I",,"Column-II"),((A),"Isobaric process of monoatomic gas." ,(p),"1" ),((B),"Isobaric process of diatomic gas" ,(q),"2" ),((C),"Isochoric process of monoatomic gas" ,(r),"Minimum at section B"), ((D),"Isochoric process of diatomic gas" ,(s),"x-axis (i.e.'Q' axis)"):}

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",):}

{:(,"Column I",,,"Column II"),((A),"Moment of inertia",,(p),"newton"//"metre"^(2)),((B),"Surface tension",,(q),"kg"//("metre-sec")),((C),"Angular acceleration",,(r),"kg-metre"^(2)),((D),"Coefficient of viscosity",,(s),"newton"//"metre"),((E),"Modulus of elasticity",,(t),"radian"//"sec"^(2)):}

For the velocity -time graph shown in figure, in a time interval from t=0 to t=6 s , match the following: {:(,"Column I",,,"Column II"),((A),"Change in velocity",,(p),-5//3 SI "unit"),((B),"Average acceleration",,(q),-20 SI "unit"),((C),"Total displacement",,(r),-10 SI "unit"),((D),"Acceleration ay t=3s",,(s),-5 SI "unit"):}

In y = Asinomegat + Asin(omegat + (2pi)/(3)) |{:(,"Column-I",,"Column-II"),((A),"Motion",(p),"is periodic but no SHM"),((B),"Amplitude",(q),"is SHM"),((C),"Initial phase",(r),A),((D),"Maximum velocity",(s),pi//3),(,,(t),omegaA//2),(,,(u),"None"):}|

In the V-T graph shown in figure: {:(,"Column-I",,"Column-II"),((A),"Gas" A is ... and gas B is... ", E is ",(p),"monoatomic , diatomic"),((B),"P_(A)/P_(B) is ",(q),"diatomic , monoatomic"),((C),"n_(A)/n_(B) is " " ",(r),"gt1"),(,,(s),"lt1"),(,,(t),"cannot say any thing"):}

For the given process :- {:("Column-I","Column-II"),((A)Process " "JtoK,(P) Wgt0),((B)Process" "KtoL ,(q) Wlt0),((C)Process " "LtoM,(r)Qgt0),((D)Process" "MtoJ,(s)Qlt0):}

Draw P-V curves for isothermal and adiabatic processes of an ideal gas.