N2+O2⟶2NO
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Bond dissociation energy of N₂ = 958.38 kJ/mol
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Bond dissociation energy of O₂ = 498 kJ/mol
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Bond formation energy of NO = –626 kJ/mol
Solution:
To find the enthalpy change (ΔH) of the reaction, we can use the following formula:
ΔH=∑(Bond dissociation energies of reactants)−∑(Bond formation energies of products)
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Bond Dissociation Energies (Reactants):
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For N₂: To break the N≡N triple bond in one molecule of nitrogen, 958.38 kJ/mol is required.
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For O₂: To break the O=O double bond in one molecule of oxygen, 498 kJ/mol is required.
The total bond dissociation energy for the reactants is:
958.38 kJ/mol (N₂)+498 kJ/mol (O₂)=1456.38 kJ/mol
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- Bond Formation Energies (Products):
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For each molecule of NO, 626 kJ/mol is released. Since the reaction produces 2 moles of NO, the total bond formation energy is:
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2×(−626)=−1252 kJ/mol
Now, applying the formula for ΔH:
ΔH=1456.38 kJ/mol−(−1252 kJ/mol)=1456.38+1252=2708.38 kJ/mol
Conclusion: The enthalpy change for the reaction is +2708.38 kJ/mol, indicating that the reaction is endothermic, meaning it absorbs energy from the surroundings.