MCQEasyJEE 2024Hess's Law

JEE Chemistry 2024 Question with Solution

Two reactions are given below: 2Fe3++3O2(g)Fe2O3(s),ΔHf=822kJ/mol2\text{Fe}^{3+} + 3\text{O}_2\text{(g)} \rightarrow \text{Fe}_2\text{O}_3\text{(s)}, \Delta H_f = -822 \, \text{kJ/mol} C(g)+12O2(g)CO(g),ΔHf=110kJ/mol\text{C}\text{(g)} + \frac{1}{2}\text{O}_2\text{(g)} \rightarrow \text{CO}\text{(g)}, \Delta H_f = -110 \, \text{kJ/mol} Enthalpy change for the reaction: 3C(g)+Fe2O3(s)2Fe(g)+3CO(g),ΔH=?3\text{C}\text{(g)} + \text{Fe}_2\text{O}_3\text{(s)} \rightarrow 2\text{Fe}\text{(g)} + 3\text{CO}\text{(g)}, \Delta H = ?

  • A

    492492

  • B

    494494

  • C

    496496

  • D

    498498

Answer

Correct answer:A

Step-by-step solution

Standard Method

Given:

  • 2Fe(s)+32O2(g)Fe2O3(s)2\text{Fe}_{(s)} + \frac{3}{2}\text{O}_{2(g)} \rightarrow \text{Fe}_2\text{O}_{3(s)} with ΔH=822kJ/mol\Delta H = -822 \, \text{kJ/mol}
  • C(s)+12O2(g)CO(g)\text{C}_{(s)} + \frac{1}{2}\text{O}_{2(g)} \rightarrow \text{CO}_{(g)} with ΔH=110kJ/mol\Delta H = -110 \, \text{kJ/mol}

Find: Enthalpy change for

3C(s)+Fe2O3(s)2Fe(s)+3CO(g)3\text{C}_{(s)} + \text{Fe}_2\text{O}_{3(s)} \rightarrow 2\text{Fe}_{(s)} + 3\text{CO}_{(g)}

Using Hess's law, reverse the first reaction and multiply the second reaction by 33.

Reversed first reaction:

Fe2O3(s)2Fe(s)+32O2(g)\text{Fe}_2\text{O}_{3(s)} \rightarrow 2\text{Fe}_{(s)} + \frac{3}{2}\text{O}_{2(g)}

ΔH=+822kJ\Delta H = +822 \, \text{kJ}

Second reaction multiplied by 33:

3C(s)+32O2(g)3CO(g)3\text{C}_{(s)} + \frac{3}{2}\text{O}_{2(g)} \rightarrow 3\text{CO}_{(g)}

ΔH=3×(110)=330kJ\Delta H = 3 \times (-110) = -330 \, \text{kJ}

Adding these two reactions, 32O2(g)\frac{3}{2}\text{O}_{2(g)} cancels from both sides and we get

3C(s)+Fe2O3(s)2Fe(s)+3CO(g)3\text{C}_{(s)} + \text{Fe}_2\text{O}_{3(s)} \rightarrow 2\text{Fe}_{(s)} + 3\text{CO}_{(g)}

So,

ΔH=(+822)+(330)=+492kJ\Delta H = (+822) + (-330) = +492 \, \text{kJ}

Therefore, the enthalpy change for the reaction is +492kJ+492 \, \text{kJ}, so the correct option is A.

Step-by-step Hess's law approach

Given: The standard enthalpy changes are:

(1)  2Fe(s)+32O2(g)Fe2O3(s),ΔH1=822kJ/mol(2)  C(s)+12O2(g)CO(g),ΔH2=110kJ/mol\begin{aligned} (1)\;& 2\text{Fe}_{(s)} + \frac{3}{2}\text{O}_{2(g)} \rightarrow \text{Fe}_2\text{O}_{3(s)}, & \Delta H_1 &= -822 \, \text{kJ/mol} \\ (2)\;& \text{C}_{(s)} + \frac{1}{2}\text{O}_{2(g)} \rightarrow \text{CO}_{(g)}, & \Delta H_2 &= -110 \, \text{kJ/mol} \end{aligned}

Find:

3C(s)+Fe2O3(s)2Fe(s)+3CO(g)3\text{C}_{(s)} + \text{Fe}_2\text{O}_{3(s)} \rightarrow 2\text{Fe}_{(s)} + 3\text{CO}_{(g)}

Apply the principle: According to Hess's law, when a reaction is reversed, the sign of ΔH\Delta H changes, and when a reaction is multiplied by a number, ΔH\Delta H is multiplied by the same number.

Step 1: Reverse reaction (1)(1) because Fe2O3(s)\text{Fe}_2\text{O}_{3(s)} must appear on the reactant side.

Fe2O3(s)2Fe(s)+32O2(g)\text{Fe}_2\text{O}_{3(s)} \rightarrow 2\text{Fe}_{(s)} + \frac{3}{2}\text{O}_{2(g)}

ΔH=+822kJ/mol\Delta H = +822 \, \text{kJ/mol}

Step 2: Multiply reaction (2)(2) by 33 to produce 3CO(g)3\text{CO}_{(g)}.

3C(s)+32O2(g)3CO(g)3\text{C}_{(s)} + \frac{3}{2}\text{O}_{2(g)} \rightarrow 3\text{CO}_{(g)}

ΔH=3×(110)=330kJ/mol\Delta H = 3 \times (-110) = -330 \, \text{kJ/mol}

Step 3: Add the manipulated equations.

Fe2O3(s)2Fe(s)+32O2(g)+  3C(s)+32O2(g)3CO(g)\begin{aligned} &\text{Fe}_2\text{O}_{3(s)} \rightarrow 2\text{Fe}_{(s)} + \frac{3}{2}\text{O}_{2(g)} \\ +\;&3\text{C}_{(s)} + \frac{3}{2}\text{O}_{2(g)} \rightarrow 3\text{CO}_{(g)} \end{aligned}

After cancellation of 32O2(g)\frac{3}{2}\text{O}_{2(g)}, the net reaction becomes

3C(s)+Fe2O3(s)2Fe(s)+3CO(g)3\text{C}_{(s)} + \text{Fe}_2\text{O}_{3(s)} \rightarrow 2\text{Fe}_{(s)} + 3\text{CO}_{(g)}

Step 4: Sum the enthalpy changes.

ΔHrxn=+822+(330)=+492kJ\Delta H_{\text{rxn}} = +822 + (-330) = +492 \, \text{kJ}

Conclude: Therefore, the enthalpy change is +492kJ/mol+492 \, \text{kJ/mol} and the correct option is A.

Common mistakes

  • Reversing the first reaction without changing the sign of ΔH\Delta H. When a thermochemical equation is reversed, the enthalpy sign must also reverse. Here, 822kJ/mol-822 \, \text{kJ/mol} becomes +822kJ/mol+822 \, \text{kJ/mol}.

  • Forgetting to multiply the second reaction by 33. The target reaction forms 3CO3\text{CO}, so both the equation and its enthalpy must be multiplied by 33, giving 330kJ/mol-330 \, \text{kJ/mol}.

  • Adding the enthalpy values without checking species cancellation. Always write the manipulated equations explicitly and cancel common species like 32O2(g)\frac{3}{2}\text{O}_{2(g)} before concluding the net reaction.

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