Statement-1 : `Delta H_(f)^(@)` is zero for oxygen `(O_(2))`.
And
Statement-2 : `Delta H_(f)^(@)` for all the elements at S.T.P. is zero.

Why Delta H_(f)^(@) of elements is zero?

From the following data at 25^(@)C {:(Reaction ,Delta_(r)H^(o)kJ//mol),((1)/(2)H_(2)(g)+(1)/(2)O_(2)(g)toOH(g),42),(H_(2)(g)+(1)/(2)O_(2)(g)to H_(2)O(g),-242),(H_(2)(g)to 2H(g),436),(O_(2)(g)to2O(g),495):} Which of the following Statement (s) is /are Correct: StatementA: Delta_(r)H^(@) "for the reaction" H_(2)O(g)to2H(g)+O(g)"is 925.5kJ/mol" Statement B: Delta_(r)H^(@) "for the reaction" H_(2)O(g)toH(g)+O(g)"is 423.5kJ/mol" Statement C:Enthalpy of formation of H(g) is-218 kJ/mol Statement D: Enthalpy of formation of OH(g) is 42 kJ/mol

Statement-1 : Entropy of all elements is zero at zero Kelvin. Statement-2 : Standard entropy of all elements is greater than zero. Statement-3 : Entropy of all elements and compounds decreases with decrease of temperature and becomes zero at absolute zero temperature.

At 1 atm will the Delta_(f)H^(@) be zero for CI_(2)(g) and Br_(2)(g) ? Explain.

Statement-1: The O-O bond length in H_(2)O_(2) is longer than that of O_(2)F_(2) . Statement-2: H_(2)O_(2) is a polar covalent molcule.

Statement-1 : In a cyclic process, both Delta H and Delta U are zero. And Statement-2 : Delta H and Delta U are path dependent functions.