`{:(,"ColumnI",, "ColumnII"),((A),"Gas A is ... and gas B is ...",(p),"Monoatomic, diatomic"),((B),p_(A)//p_(B) "is",(q),"Diatomic, monoatomic"),((C),n_(A)//n_(B)"is",(r), gt 1),(,,(s), lt1),(,,(t),"cannot say anything"):}`

In the proscess T prop W, pressure of the gas increase from p_(o) to t_(o) Match the columns. {:(,"ColumnI",, "ColumnII"),((A),"Temperature of teh gas",(p),"Pssitive"),((B),"Volume of the gas",(q),"Nagative"),((C),"work done by the gas",(r),"Two times"),((D),"Heat supplies to the gas",(s),"Cannot say anything"):}

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)"):}

{:(,"ColumnI",,"ColumnII"),((A),(K.E.)/(P.E.),(P),2),((B),P.E+2K.E.,(Q),-(1)/(2)),((C),(P.E.)/(T.E.),(R),1),((D),(K.E.)/(T.E.),(S),0):}

{:("ColumnI" (Shell),"ColumnII(Value of l)"),((A)2nd,(P)1),((B)3rd,(Q)2),((C)4th,(R)3),((D)1st,(S)0):}

{:(,"ColumnI",,"ColumnII"),((A),"Number of orbitials in the" n^(th)"shell",(P),2(2l+1)),((B),"Maximum number of electrons in a subshell",(Q),n),((C),"Number of subshell in" n^(th)"shell",(R),2l+1),((D),"Number of orbitals in a subshell",(S),n^(2)):}

If one mole each of a monoatomic and diatomic gases are mixed at low temperature then C_(p)//C_(v) ratio for the mixture is :

If a ,b ,a n dc are in A.P. p ,q ,a n dr are in H.P., and a p ,b q ,a n dc r are in G.P., then p/r+r/p is equal to a/c+c/a

If P(A/C) gt P(B/C) and P(A/(bar C)) gt P(B/(bar C)), then the relationship between P(A) and P(B) is (A) P(A)=P(B) (B) P(A) le P(B) (C) P(A) gt P(B) (D) P(A) ge P(B)

On mole of a monoatomic ideal gas is taken through the cycle shown in figure . A rarr B : Adiabatic expansion " " BrarrC : Cooling at constant volume CrarrD : Adiabatic compression " " D rarr A : Heating at constant volume The pressure and temperature at A , B , etc, are denoted by P_(A) , T_(A) , P_(B) , T_(B) etc., respectively . Given that T_(A) = 1000K, P_(B) = ((2)/(3))P_(A)"and"P_(C) = ((1)/(3))P_(A) . Calculate the following quantities: (i) The work done by the gas in the processs A rarr B (ii) The heat lost by the gas in the process B rarr C (iii) The temperature T_(D). ("Given" : ((2)/(3))^(2//5) = 0.85 )

If n(A)=p,n(B)=q and total number of functions from A to B is 343, then p-q (A) 3 (B) -3 (C) 4 (D) none of these