Write notes on diatomic molecules and polyatomic molecules with respect to bond dissociation enthalpy.
(N/A) Diatomic Molecules:
For diatomic molecules,the bond dissociation enthalpy is equal to the enthalpy of atomization.
$H_{2(g)} \rightarrow 2H_{(g)} ; \Delta_{H-H} H^{\ominus} = 435.0 \ kJ \ mol^{-1}$
$Cl_{2(g)} \rightarrow 2Cl_{(g)} ; \Delta_{Cl-Cl} H^{\ominus} = 242 \ kJ \ mol^{-1}$
$O_{2(g)} \rightarrow 2O_{(g)} ; \Delta_{O=O} H^{\ominus} = 428 \ kJ \ mol^{-1}$
Bond dissociation enthalpy is the change in enthalpy when one mole of a covalent bond in a gaseous molecule is broken to form products in the gaseous phase.
Polyatomic Molecules:
In polyatomic molecules,the bond dissociation enthalpy varies for the same type of bonds within the molecule due to the changing chemical environment.
Example: Methane $(CH_4)$
$CH_{4(g)} \rightarrow C_{(g)} + 4H_{(g)} ; \Delta_{a} H^{\ominus} = 1665 \ kJ \ mol^{-1}$
The individual steps for breaking $C-H$ bonds are:
$CH_{4(g)} \rightarrow CH_{3(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +427 \ kJ \ mol^{-1}$
$CH_{3(g)} \rightarrow CH_{2(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +439 \ kJ \ mol^{-1}$
$CH_{2(g)} \rightarrow CH_{(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +452 \ kJ \ mol^{-1}$
$CH_{(g)} \rightarrow C_{(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +347 \ kJ \ mol^{-1}$
Since the energies differ,we use the mean bond enthalpy:
$\Delta_{C-H} H^{\ominus} = \frac{1}{4} (1665) = 416 \ kJ \ mol^{-1}$
General formula for reaction enthalpy: $\Delta_{r} H^{\ominus} = \Sigma \text{bond enthalpies of reactants} - \Sigma \text{bond enthalpies of products}$.
For diatomic molecules,the bond dissociation enthalpy is equal to the enthalpy of atomization.
$H_{2(g)} \rightarrow 2H_{(g)} ; \Delta_{H-H} H^{\ominus} = 435.0 \ kJ \ mol^{-1}$
$Cl_{2(g)} \rightarrow 2Cl_{(g)} ; \Delta_{Cl-Cl} H^{\ominus} = 242 \ kJ \ mol^{-1}$
$O_{2(g)} \rightarrow 2O_{(g)} ; \Delta_{O=O} H^{\ominus} = 428 \ kJ \ mol^{-1}$
Bond dissociation enthalpy is the change in enthalpy when one mole of a covalent bond in a gaseous molecule is broken to form products in the gaseous phase.
Polyatomic Molecules:
In polyatomic molecules,the bond dissociation enthalpy varies for the same type of bonds within the molecule due to the changing chemical environment.
Example: Methane $(CH_4)$
$CH_{4(g)} \rightarrow C_{(g)} + 4H_{(g)} ; \Delta_{a} H^{\ominus} = 1665 \ kJ \ mol^{-1}$
The individual steps for breaking $C-H$ bonds are:
$CH_{4(g)} \rightarrow CH_{3(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +427 \ kJ \ mol^{-1}$
$CH_{3(g)} \rightarrow CH_{2(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +439 \ kJ \ mol^{-1}$
$CH_{2(g)} \rightarrow CH_{(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +452 \ kJ \ mol^{-1}$
$CH_{(g)} \rightarrow C_{(g)} + H_{(g)} ; \Delta_{bond} H^{\ominus} = +347 \ kJ \ mol^{-1}$
Since the energies differ,we use the mean bond enthalpy:
$\Delta_{C-H} H^{\ominus} = \frac{1}{4} (1665) = 416 \ kJ \ mol^{-1}$
General formula for reaction enthalpy: $\Delta_{r} H^{\ominus} = \Sigma \text{bond enthalpies of reactants} - \Sigma \text{bond enthalpies of products}$.
Explore More
Similar Questions
The enthalpy change $(\Delta H)$ for the process $N_2H_{4(g)} \to 2N_{(g)} + 4H_{(g)}$ is $1724 \ kJ \ mol^{-1}$. If the bond energy of $N-H$ bond in ammonia is $391 \ kJ \ mol^{-1}$,what is the bond energy of $N-N$ bond in $N_2H_4$ in $kJ \ mol^{-1}$?
Medium
View SolutionExplain Enthalpy of atomization $\left( \Delta_{a} H^{\theta} \right)$.
Medium
View SolutionCalculate $\Delta H \ (kJ/mol)$ for the reaction:
$2FeO_{(s)} + \frac{1}{2} O_{2_{(g)}} \to Fe_2O_{3_{(s)}}$
Given $\Delta H$ values:
$(i)$ $Fe_2O_{3_{(s)}} + 3C_{(graphite)} \to 2Fe_{(s)} + 3CO_{(g)}$ : $492 \ kJ/mol$
$(ii)$ $FeO_{(s)} + C_{(graphite)} \to Fe_{(s)} + CO_{(g)}$ : $156 \ kJ/mol$
$(iii)$ $C_{(graphite)} + O_{2_{(g)}} \to CO_{2_{(g)}}$ : $-393 \ kJ/mol$
$(iv)$ $CO_{(g)} + \frac{1}{2} O_{2_{(g)}} \to CO_{2_{(g)}}$ : $-283 \ kJ/mol$
$2FeO_{(s)} + \frac{1}{2} O_{2_{(g)}} \to Fe_2O_{3_{(s)}}$
Given $\Delta H$ values:
$(i)$ $Fe_2O_{3_{(s)}} + 3C_{(graphite)} \to 2Fe_{(s)} + 3CO_{(g)}$ : $492 \ kJ/mol$
$(ii)$ $FeO_{(s)} + C_{(graphite)} \to Fe_{(s)} + CO_{(g)}$ : $156 \ kJ/mol$
$(iii)$ $C_{(graphite)} + O_{2_{(g)}} \to CO_{2_{(g)}}$ : $-393 \ kJ/mol$
$(iv)$ $CO_{(g)} + \frac{1}{2} O_{2_{(g)}} \to CO_{2_{(g)}}$ : $-283 \ kJ/mol$
Medium
View SolutionThe calorific value of hydrogen gas is $-143 \ kJ \ g^{-1}$. The standard enthalpy of formation of $H_2O$ will be $—$
Easy
View SolutionGiven two processes:
$\frac{1}{2} P_{4(s)} + 3 Cl_{2(g)} \to 2 PCl_{3(l)} \;; \Delta H = -635 \ kJ$
$PCl_{3(l)} + Cl_{2(g)} \to PCl_{5(s)} \;; \Delta H = -137 \ kJ$
The value of the heat of formation of $PCl_{5(s)}$ is ...... $kJ \ mol^{-1}$.
$\frac{1}{2} P_{4(s)} + 3 Cl_{2(g)} \to 2 PCl_{3(l)} \;; \Delta H = -635 \ kJ$
$PCl_{3(l)} + Cl_{2(g)} \to PCl_{5(s)} \;; \Delta H = -137 \ kJ$
The value of the heat of formation of $PCl_{5(s)}$ is ...... $kJ \ mol^{-1}$.
Difficult
View SolutionVedclass Products
For Students
Vedclass Test Series
Mock tests in real JEE/NEET style with performance analysis. 5-day free trial.
Start Free TrialFor Teachers
Exam Paper Generator
Generate Set A/B/C/D exam papers from 7.5L+ questions in 2 minutes. 3 chapters free.
Try FreeFor Institutes
Online Exam Module
Live online exams with unlimited students, 360° analytics & white-label branding.
See Demo