For the change,`C_("diamond") rarr C_("graphite"), Delta H = -1.89 kJ` , if 6 g of diamond and 6 g of graphite are separately burnt to yield `CO_2` the heat liberated in first case is:

The enthalpy change for chemical reaction is denoted as DeltaH^(Theta) and DeltaH^(Theta) = H_(P)^(Theta) - H_(R)^(Theta) . The relation between enthalpy and internal enegry is expressed by equation: DeltaH = DeltaU +DeltanRT where DeltaU = change in internal enegry Deltan = change in number of moles, R = gas constant. For the change, C_("diamond") rarr C_("graphite"), DeltaH =- 1.89 kJ , if 6g of diamond and 6g of graphite are seperately burnt to yield CO_(2) the heat liberated in first case is

Given that: i. C("graphite") +O_(2)(g) rarr CO_(2)(g), DeltaH =- 393.7 kJ ii. C("diamond") rarr C("graphite"), DeltaH =- 2.1 kJ a. Calculate DeltaH for buring of diamond of CO_(2) . b. Calculate the quantity of graphite that must be burnt to evolve 5000 kJ of heta.

C(s) to C(g) , DeltaH = 716.7 kJ DeltaH is the heat of …………… of graphite.

C_("graphite") + O_(2(g)) : Delta H = -393.7 kJ . Calculate the quantity of graphite(in gm) that must be burnt to evolve 5000 kj of heat

One gram-atom of graphite and one gram-atom of diamond were separately burnt to CO_(2) . The amount of heat liberated was 393.5KJ and 305.4KJ respectively. It is apparent that

A : C_("diamond") rightarrow C_("graphite") Delta H and Delta U are same for this reaction. R: Entropy increases during the conversion of diamond to graphite.

Given : C("diamond")+O_(2)rarrCO_(2),DeltaH=-395 kJ C("graphite")+O_(2)rarrCO_(2),DeltaH=-393 kJ The enthalpy of formation of diamond from graphite is

Densities of diamond and graphite are 3.5 and 2.5 gm/ml. C_("daimond") hArr C_("graphite") , Delta_(t) H = -1.9 KJ/ mole favourable conditions for formation of diamond are

Two reactions are given below : C_("(graphite)")+O_(2(g))rarrCO_(2(g)),DeltaH=-393.7kJ C_("(diamond)")rarrC_("(graphite)"),DeltaH=-2.1kJ What quantity of diamond will give 800 kJ of heat on burning ?

The value of DeltaH_("transition") of C (graphite) rarr C (diamond) is 1.9 kJ/mol at 25^(@)C . Entropy of graphite is higher than entropy of diamond. This implies that :