The enthalpy change for the process
`C("graphite") rarr C(g)`is called

Calculate the enthalpy change for the process C Cl_(4)(g) rarr C(g)+4Cl(g) and calculate bond enthalpy of C-Cl in C Cl_(4)(g) . Delta_(vap)H^(Θ)(C Cl_(4))=30.5 kJ mol^(-1) Delta_(f)H^(Θ)(C Cl_(4))=-135.5 kJ mol^(-1) Delta_(a)H^(Θ)(C )=715.0 kJ mol^(-1) , where Delta_(a)H^(Θ) is enthalpy of atomisation Delta_(a)H^(Θ)(Cl_(2))=242 kJ mol^(-1)

The enthalpy change for the reaction 2C("graphite")+3H_(2)(g)rarrC_(2)H_(6)(g) is called

If the enthalpy of combustion of diamond and graphite are -395.4 kJ mol^(-1) and -393.6 kJ mol^(-1) , what is enthalpy change for the C("graphite") rarr C("diamond") ?

4.8 g of C (diamond) on complete combustion evolves 1584 kJ of heat. The standard heat of formation of gaseous carbon is 725 kJ//mol . The energy required for the process C(graphite) rarr C(gas) C(diamond) rarr C(gas) are

Look at the following diagram: The enthalpy change for the reaction A rarr B will be

A schematic representation of enthalpy changes for the reaction, C_("graphite") + 1/2 O_(2)(g) rightarrow CO(g) is given below. The missing value is

The enthalpy change for the reaction, C_(2)H_(6)(g)rarr2C(g)+6H(g) is X kJ. The bond energy of C-H bond is :

Assertion : The enthalpy change for the reaction CaO_((s))+CO_(2(g)) rarr CaCO_(3(s)) is called enthalpy of formation of calcium carbonate. Reason : The reaction involves formation of 1 mole of CaCO_(3) from its constituent elements.

The enthalpy change for the reaction H_(2)(g)+C_(2)H_(4)(g)rarr C_(2)H_(6)(g) is ……………… The bond energies are, H - H=103, C-H=99, C-C=80 & C=C=145 "K cal mol"^(-1)

18.0 g of water completely vaporises at 100^(@)C and 1 bar pressure and the enthalpy change in the process is 40.79 kJ mol^(-1) . What will be the enthalpy change for vaporising two moles of water under the same conditions ? What is the standard enthalpy of vaporisation for water ?