`{:(Column-I,Column-II),((A)"Electrolytic cell",(p)-DeltaG^(@)),((B)nFE_(cell)^(0),(q)"Concentration cell"),((C)E_(cell)=(0.059)/(n)log.(C_("cathode"))/(C_("anode")),(r)96500 "Coulombs"),((D)"Diffusion of ions",(s)"Device converting electrical energy into chemical energy"),((E)1"Farday",(u)"Salt bridge"):}`

{:(Column-I,Column-II),((A)"Cathode",(p)"Primary cell"),((B)1"Coulomb",(q)"Secondary cell"),((C)"Dry cell",(r)6.24 xx 10^(18) "electrons"),((D)"Lead stron cell",(s)"Concentration cell"),((E)Zn|Zn^(2+)(0.10M)||Zn^(2+)(0.1M)|Zn,(u)"Positive terminal of electrochemical cell"):}

{:(,"Column I",,"Column II"),((A),"Dimensional variable",(p),pi),((B),"Dimensionless variable",(q),"Force"),((C),"Dimensional constant",(r),"Angle"),((D),"Dimensionless constant",(s),"Gravitational constant"):}

{:(Column-I,Column-II),((a)"Acetone" +CHCI_(3),(p)DeltaS gt 0),((b)"Ethanol +water",(q)DeltaH gt 0),((c)C_(2)H_(5)Br+C_(2)H_(5)I,(r)DeltaH lt 0),((d)"Acetone+Benzne",(s)"Maximum boiling azetropes"),(,(t)"Minimum boiling azeotropes"):}

Some laws/processes are given in column-I. Match these with the physical phenomena given in column-II. {:(,"Column I",,"Column II"),((A),"Transition between two atomic energy levels".,(p),"Characteristic X-rays"),((B),"Electron emission from a material",(q),"Photoelectric effect"),((C),"Moaley's law",(r),"Hydrogen spectrum"),((D),"Change of photon energy into kinetic energy of electrons",(s),beta-"decay"):}

Match the items of column I to those of column I: {:(Column-I, Column-II),((A)"Cell constant",(p) E_("cathode")^(0)+E_("anode")^(0)),((B)Anode,(q)l//A),((C)"Conductance",(r)"Mass of product by 1 coulomb of electricity"),((D)"Electrochemical equivalent",(s)("Resistance")^(-1)),((E)E_(cell)^(0),(u)"Involve oxidation"):}

{:(Column-I,Column-II),((A)"Conductance",(p)Cm^(-1)),((B)"Specific condutance",(q)Ohm^(-1)cm^(2)mol^(-1)),((C)"Cell constant",(r)Ohm^(1-)),((D)"Equivalent conductance",(s)Ohm^(-1)cm^(-1)),((E)"Molar conductance",(u)Ohm^(-1)cm^(2) "equivalent"^(-1)):}

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"):}

{:(,"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)):}

Two blocks A and B of mass m and 2m respectively are connected by a massless spring of spring constant K . This system lies over a smooth horizontal surface. At t=0 the bolck A has velocity u towards right as shown while the speed of block B is zero, and the length of spring is equal to its natural length at that at that instant. {:(,"Column I",,"Column II"),((A),"The velocity of block A",(P),"can never be zero"),((B),"The velocity of block B",(Q),"may be zero at certain instants of time"),((C),"The kinetic energy of system of two block",(R),"is minimum at maximum compression of spring"),((D),"The potential energy of spring",(S),"is maximum at maximum extension of spring"):}