Use (IE) and (EA) listed below to determine whether the following process is endothermic exothermic.
`Mg_((s)) + 2F_((g)) to Mg_((g))^(2+) + 2F_((g))^(-)`
`(IE)_1` of `Mg_((g))=737.7 "kJ mol"^(-1)`
`(IE)_2` of `Mg_((g))=1451 "kJ mol"^(-1)`
`(EA)` of `F_((g))=-328 "kJ mol"^(-1)`

DeltaH in terms of 'x' xx 10^(3) KJ is if M_((g)) + 2X_((g)) rarr M_((g))^(2+) + 2X_((g))^(-) Given : (I.E)_(1) of M (g) = 705.7 kJ mol^(-1), (I.E)_(2) " of" M(g) = 951 kJ mol^(-1) and (E.A)_(1) of X(g) = -328 kJ mol^(-1) 'x' is

The enthalpy changes for the following processes are listed below: Cl_(2(g)) rarr 2Cl_((g)) , DeltaH = 242.3 kJ mol^(-1) I_(2(g)) rarrr 2I_((g)) , DeltaH = 151.0 kJ mol^(-1) ICl_((g)) rarr I_((g)) + Cl_((g)) , DeltaH = 211.3 kJ mol^(-1) I_(2(s)) rarr I_(2(g)) , DeltaH = 62.76 kJ mol^(-1) Given that the standard states for iodine and chlorine are I_(2(s)) and Cl_(2(g)) , the standard enthalpy of formation for ICT is:

The enthalpy change for the following reaction is 368kJ. Calculate the average O-F bond energy. OF_(2(g)) rarr O_((g)) + 2F_((g))

The formation of the oxide ion O _((g)) ^(2-) from oxygen atom requires first an exothermic and then an endothermic step as shown below : O _((g)) + e ^(-) to O _((g )) ^(-) ,Delta _(f) H^(0) =-141 kJ mol ^(-1) O _((g)) ^(-) +e ^(-) to O _((g)) ^(-2) ,Delta _(f) H^(0) =+ 780 kJ mol ^(-1) Thus, process of formation of O^(2-) in gas phase is unfavourable even thrugh O ^(2-) is isoelectronic with neon. It is due to the fact that (2015)

(IE)_1 and (IE)_2 of Mg_((g)) are 740, 1540 kJ mol^(-1) . Calculate percentage of Mg_((g))^(+) and Mg_((g))^(2+) if 1 g of Mg_((s)) absorbs 50.0 kJ of energy.

Standard molar entropies of Mg_((s)) , C_((s)), MgO_((s)) & CO_((g)) respectively are S_1,S_2,S_3, & S_4 J//K//mol . Then DeltaS_("sys") for MgO_((s)) + C_((s)) rarr Mg_((s)) + CO_((g))