Question

Using the bond enthalpy data given below, calculate the enthalpy of formation of acetone (g)
Bond energy $C-H=413.4kJ{mol}^{-1}$;
Bond energy $C-C=347.0kJ{mol}^{-1}$;
Bond energy $C=O=728.0kJ{mol}^{-1}$;
Bond energy $O=O=495.0kJ{mol}^{-1}$;
Bond energy $H-H=435.8kJ{mol}^{-1}$;
$\Delta H_{sub}C\left(s\right)=718.4kJ{mol}^{-1}$

Answer 1

$3C\left(g\right)+6H\left(g\right)+O\left(g\right)\to {CH}_{3}CO{CH}_3\left(g\right)$
In acetone, six $C-H$ bonds, one $C=O$ bond and two $C-C$ bonds are present. Energy released in the formation of these bonds is
$=-6\times 413.4-728.0-2\times 3470=-3902.4kJ{mol}^{-1}$
The equation of the enthalpy of formation of acetone is
$3C_{graphite}+3H_2\left(g\right)+\frac{1}{2}{O}_2\left(g\right)\to {CH}_{3}CO{CH}_3\left(g\right);\Delta H=?$
This equation can be obtained from the following equations by adding:
$3C\left(s\right)+6H\left(g\right)+O\left(g\right)\to {CH}_{3}CO{CH}_3\left(g\right);\Delta H=-3904kJ{mol}^{-1}$
$3C\left(s\right)\to 3C\left(g\right);\Delta H=2155.2kJ{mol}^{-1}$
$3H_2\to 6H\left(g\right);\Delta H=1307.4kJ{mol}^{-1}$
and $\frac{1}{2}{O}_2\left(g\right)\to O\left(g\right);\Delta H=247.5kJ{mol}^{-1}$
---------------------------------------------------------------------------------------------
$3C\left(s\right)+3H_2\left(g\right)+\frac{1}{2}{O}_2\left(g\right)\to {CH}_{3}CO{CH}_3\left(g\right);\Delta H=-192.3kJ{mol}^{-1}$