oxidising power of chlorine in aqueous solution can be determined by the parameters indicated below: Calculate the energy involved in the conversion of
`(1)/(2)Cl_(2)(g)"to"Cl^(-)(aq)`
Using the data ,
`DeltaH_("disso"(Cl_(2)))^(@)=240KJmol^(-1),`
`DeltaH_("eg"(Cl_(2)))^(@)=-349KJmol^(-1),`
`DeltaH_("hydroation"(Cl_(2)))^(@)=-381KJmol^(-1),`

Oxidising power of chlorine in aqueous solution can be determined by the parameters indicated below (1)/(2)CL_(2)(g)overset((1)/(2)Delta_(diss)H^(Theta))(rarr)Cl(g)overset(DeltaH_(Eg)^(Theta))(rarr) Cl^(-)(g)overset(Delta_(hyd)H^(Theta))(rarr)Cl^(-)(aq) The energy involved in the conversion of (1)/(2)Cl_(2)(g) to Cl^(-)(aq) (Using the data Delta_(diss)H_(Cl_(2))^(Theta)=240KJ mol^(-1) ) Delta_(Eg)H_(Cl)^(Theta)=-349KJmol^(-1) , Delta_(Eg)H_(Cl)^(Theta)=-381KJmol^(-1) ) will be

Calculate the free eneryg change at 298 K for the reaction , Br_(2)(l)+Cl_(2)(g) to BrCl(g) . For the reaction DeltaH^(@)=29.3 kJ &

Using the data given below, establish that the vaporization of C Cl_(4)(l) 298 K to produce C Cl_(4)(g) at 1atm pressure does not occur spontaneously. Given : C Cl_(4)(l,1"atm")toC Cl_(4)(g 1 "atm") , DeltaS^(@)=94.98JK^(-1)mol^(-1) DeltaH_(f)^(@)(C Cl_(4),g)=-106.7kJmol^(-1) &DeltaH_(f)^(@)(C Cl_(4),l)=-139.3kJmol^(-1)

Calculate the entropy change for the conservation of following: (a) 1g ice to water at 273K , DeltaH_f for ice=6.025kJmol^(-1) . (b) 36g water to vapour at 373K, DeltaH_v for H_2O=40.63kJmol(-1)