`{:("Column-"," Column-II "),("A) Boyle's law ","P)" P_("obs") = P_("atm") +P_("water vapour")),("B) Avagadro's law ","Q)" V_1 = n_1 ((V_2)/(n_2))),("C) Charles' law ","R)" V_t = V_0 (1 + t/273)),("D) Dalton's law ","S)" V_1 = P_2((V_2)/(P_1))):}`

{:("LIST - 1","LIST - 2"),("A) Boyle's law ",(1) P_("obs") =P_("atm") +P_("water vapour")),("B) Avagadro law ",(2) V_1 = n_1((V_2)/(n_2))),("C) Charles law ",(3) V_t = V_0(1 + t/(273))),("D) Dalton's law ",(4) V_1 = P_2((V_2)/(P_1))):} The correct match is

{:("Column-I ","Column-II "),("A) Boyle's law ","P)" (P_1)/(T_1) = (P_2)/(T_2)),("B) Avogadro law ","Q)" V_1 = n_t((V_2)/(n_2))),("C) Charles law ","R)" V_1 = V_0 (1 + t/(273))),("D) Gay Lussac's law ","S)" V_1 = P_2((V_2)/(P_1))):}

{:("Column-I ","Column-II "),("A) Low pressure ","P)" Z=1 ),("B) High pressure ","Q) "Z != 1 ),("C) Very high temperature ","R) "Pb a/V):}

{:("Column-I ","Column-II "),("A) Atm L mol"^(-1),"P)" a//Rb),("B) " sqrt((2RT)/(M)), "Q)" a//b),("C) Boyle temperature ","R)" V_m),("D) Volume of one mole","S) "u_(MP)):}

{:("Column-I ","Column-II "),("A) Hydrogen gas (P = 200 atm, T = 273K) ","P) Compressibility factor "!= 1 ),("B) Hydrogen gas "(P ~~ 0,T = 273K) ,"Q) Attractive forces are dominant "),("C)" CO_2 (P= 1 atm, T = 273K) ,"R)" PV = nRT ),("D) Real gas with very large molar volume ","S)" P(V - nb) = nRT ):}

{:("Column-l ","Column-II "),("(Gas) ","(Order of "T_B "Boyle Temp) (1.= min, 5 = max) "),("A)"He,"P) 3 "),("B)"CH_4 ,"Q) 5"),("C)" H_2,"R) 1 "),("D)" N_2 ,"S) 4"),("E)" NH_3 ,"T) 2 "):}

Consider a fixed number of moles of a gas at constant temperature for A, B, C cases of Column- I. {:("Column-I","Column-II"),("A) P-V graph","P) Straight line passing through origin"),("B)" P - (1)/( V) "graph", "Q) Straight line parallel to pressure axis"),("C) PV-P graph","R) Straight line cutting temperature axis at"-273°C),("D) P-T graph in","S) Rectangular hyperbola isochoric process"):}

The equation of motion of particle is described in column-I . At t=0 particle is at origin and at rest {:("Column-I"," Column-II"),("A) "x=3t^(2)+2t,"P) Velocity of particle at "t=1sec " is " 8m//s),("B) " V=8t,"Q) Particle moves with uniform acceleration"),("C) "a=16t,"R) Particle moves with variable acceleration"),("D) "V=6t-3t^(2),"S) Acceleration of the particle at " t=1 " is " 2 m//s),(,"T) Particle will change its direction of motion"):}

Take v = velocity given to satellite in its orbit v_(0) = sqrt((GM)/(R )), v_(e ) = escape velocity {:("Column-I",,"Column-II"),((A) v= V_(0),,"(P) Elliptical path"),((B) v_(0) lt v lt v_(e),,"(Q) Hyperbolic path"),((C) v = v_(e),,"(R) Circular path"),((D) v gt v_(e ),,"(S) Parabolic path"):}