Consider the following reaction :- (a) `H_(aq)^(+)+CI_(aq)^(-)toHCI_(l),DeltaH=-X_(1) KJmol^(-1)` (b) `H_2(g)^(+)+CI_2(g)to2HCI_(l),DeltaH=-X_(2) KJmol^(-1)` ( c) `(1)/(2)H_(2(g))+(1)/(2)CI_(2(g))toHCI_(l),DeltaH=-X_(3) KJmol^(-1)`
(d) `H_((g))+CI_((g))toHCI_(l),DeltaH=-X_(4) KJmol^(-1)`
Enthalpy of formation of `HCI_(l)` is :-

Consider the following reactions: (i) H^(+)(aq)+OH^(-)(aq)rarrH_(2)O(l) , DeltaH==-X_(1)Kjmol^(-1) (ii) H_(2)(g)+(1)/(2)O_(2)(g)rarrH_(2)O(l),DeltaH=-X_(2)Kjmol^(-1) (iii) CO_(2)(g)+H_(2)(g)rarrCO(g)+H_(2)O(l) , DeltaH=-X_(3)KJmol^(-1) (iv) C_(2)H_(2)(g)+(5)/(2)O_(2)(g)rarr2CO_(2)(g)+H_(2)O(l) , DeltaH=+X_(4)KJmol^(-1) Enthanlpy of formation of H_(2)O(l) is

Consider the following reactions : (a) H_((aq))^(+)+OH_((aq))^(-)=H_(2)O_((l)), Delta H= - X_(1)"kJ mol"^(-1) (b) H_(2(g))+(1)/(2)O_(2(g))=H_(2)O_((l)), Delta H= - X_(2)"kJ mol"^(-1) (c ) CO_(2(g))+H_(2(g))=CO_((g))+H_(2)O_((l))- X_(3)"kJ mol"^(-1) (d) C_(2)H_(2(g))+(5)/(2)O_(2(g))=2CO_(2(g))+H_(2)O_((l))+X_(4)"kJ mol"^(-1) Enthalpy of formation of H_(2)O_((l)) is :

The average O-H Bond energy in H_(2)O with the help of following data : (P) H_(2)O(l)toH_(2)O(g)," "DeltaH=+40.6 kJ mol^(-1) (Q) 2H(g)toH_(2)(g)," "DeltaH=-435.0 kJ mol^(-1) (R ) O_(2)(g)to2O(g)," "DeltaH=+489.6 kJ mol^(-1) (S) 2H_(2)(g)+O_(2)(g)to2H_(2)O(l), " "DeltaH=-571.6 kJ mol^(-1)

Calculate the standard enthalpy of formation of acetylena from the following data: C(s)+O_(2)(g)to CO_(2)(g), DeltaH^(@)=-393.5KJmol^(-1) H_(2)(g)+(1)/(2)O_(2)(g)to H_(2)O(l),DeltaH^(@)=-285 .8KJmol^(-1) 2C_(2)H_(2)(g)+50_(2)(g)to 4Co_(2)(g)+2H_(2)O(l0, DeltaH^(@)=-2598.8KJmol^(-1)

The enthalpy of the reaction H_(2)(g)+(1)/(2)O_(2)(g)toH_(2)O(g) is DeltaH_(1) and that of H_(2)(g)+(1)/(2)O_(2)(g)toH_(2)O(l) is DeltaH_(2) . Then