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Chapter 16: Problem 80

The equilibrium constant \(K\) for the reaction $$2 \mathrm{Cl}(g) \rightleftharpoons \mathrm{Cl}_{2}(g)$$ was measured as a function of temperature (Kelvin). A graph of \(\ln (K)\) versus \(1 / T\) for this reaction gives a straight line with a slope of \(1.352 \times 10^{4} \mathrm{K}\) and a \(y\) -intercept of \(-14.51 .\) Determine the values of \(\Delta H^{\circ}\) and \(\Delta S^{\circ}\) for this reaction. See Exercise 79.

Short Answer

Expert verified
The values of 螖H鈦 and 螖S鈦 for the given reaction are \(-1.124 \times 10^5 \textrm{ J mol}^{-1}\) and \(-120.6 \textrm{ J K}^{-1}\textrm{mol}^{-1}\), respectively.

Step by step solution

01

Write down the Van't Hoff equation

The Van't Hoff equation is given by the following formula: \[\ln K = -\frac{\Delta H^{\circ}}{RT} + \frac{\Delta S^{\circ}}{R}\] Here, \(K\) is the equilibrium constant, \(R\) is the ideal gas constant, which is equal to \(8.314 \textrm{ J K}^{-1}\textrm{mol}^{-1}\), \(T\) is the temperature in Kelvin, 螖H鈦 is the change in enthalpy, and 螖S鈦 is the change in entropy.
02

Express the equation in the form of y = mx + b

We can rewrite the Van't Hoff equation as: \[\ln K = \left(-\frac{\Delta H^{\circ}}{R}\right) \times \frac{1}{T} +\frac{\Delta S^{\circ}}{R}\] Now, comparing it with the linear equation form, \(y = mx + b\), we can identify the following: \(y = \ln K\) \(m = -\frac{\Delta H^{\circ}}{R}\) \(x = \frac{1}{T}\) \(b = \frac{\Delta S^{\circ}}{R}\)
03

Use the given slope and y-intercept to calculate 螖H鈦 and 螖S鈦

We are given the slope, m, as \(1.352 \times 10^4 \textrm{K}\), and the y-intercept, b, as \(-14.51\). Therefore, we can find 螖H鈦 and 螖S鈦 as follows: First, find 螖H鈦 using the slope: \[m = -\frac{\Delta H^{\circ}}{R} \implies \Delta H^{\circ} = -m \times R\] Using the given slope, \(m = 1.352 \times 10^4 \textrm{K}\) and the gas constant, \(R = 8.314 \textrm{ J K}^{-1}\textrm{mol}^{-1}\), we get: \[\Delta H^{\circ} = -(1.352 \times 10^4 \textrm{K}) \times (8.314 \textrm{ J K}^{-1}\textrm{mol}^{-1}) = -1.124 \times 10^5 \textrm{ J mol}^{-1}\] Next, find 螖S鈦 using the y-intercept: \[b = \frac{\Delta S^{\circ}}{R} \implies \Delta S^{\circ} = b \times R\] Using the given y-intercept, \(b = -14.51\) and the gas constant, \(R = 8.314 \textrm{ J K}^{-1}\textrm{mol}^{-1}\), we get: \[\Delta S^{\circ} = (-14.51) \times (8.314 \textrm{ J K}^{-1}\textrm{mol}^{-1}) = -120.6 \textrm{ J K}^{-1}\textrm{mol}^{-1}\] Thus, the values of 螖H鈦 and 螖S鈦 for this reaction are \(-1.124 \times 10^5 \textrm{ J mol}^{-1}\) and \(-120.6 \textrm{ J K}^{-1}\textrm{mol}^{-1}\), respectively.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Equilibrium Constant
For any chemical reaction, the equilibrium constant, denoted as \( K \), plays a crucial role in understanding the reaction's dynamics. It quantifies the ratio of product concentrations to reactant concentrations when a reaction reaches a state of equilibrium. This means no further net change in the concentrations of the reactants or products occurs.
Various factors can affect \( K \), including the nature of the reactants, the concentration, and the temperature. In a simple sense:
  • A higher \( K \) value indicates that the reaction favors the formation of products.
  • A lower \( K \) value suggests that reactants are favored.
In the context of Van't Hoff equation, \( K \) can vary with temperature, which is essential for deriving thermodynamic parameters like enthalpy and entropy changes.
Enthalpy Change (螖H掳)
Enthalpy change, expressed as \( \Delta H^{\circ} \), is a measure of the total energy change during a reaction. It indicates whether a reaction is exothermic (releases heat) or endothermic (absorbs heat).
When calculated, a negative \( \Delta H^{\circ} \) suggests an exothermic process, with the system releasing heat to the surroundings. Conversely, a positive \( \Delta H^{\circ} \) indicates an endothermic process, requiring heat from the surroundings.
  • The Van't Hoff equation uses the slope from a graph of \( \ln(K) \) vs. \( 1/T \) to calculate \( \Delta H^{\circ} \).
  • The slope is related to \( -\Delta H^{\circ}/R \), showing that the enthalpy change is directly proportional to this slope.
Understanding \( \Delta H^{\circ} \) is critical for predicting how temperature changes influence the reaction's equilibrium.
Entropy Change (螖S掳)
Entropy change, denoted as \( \Delta S^{\circ} \), reflects the disorder or randomness in a system. It's a measure of the amount of disorder introduced during a reaction.
When a reaction results in a higher disorder, \( \Delta S^{\circ} \) is positive, indicating a spontaneous increase in entropy. Conversely, a negative \( \Delta S^{\circ} \) means a decrease in randomness.
  • In the Van't Hoff equation, we find \( \Delta S^{\circ} \) using the y-intercept, where \( b = \Delta S^{\circ} / R \).
  • A positive \( \Delta S^{\circ} \) hints at higher spontaneity, often favoring the forward reaction.
Entropy is central to determining the direction and feasibility of chemical processes at varying temperatures.
Ideal Gas Constant
The ideal gas constant, often represented as \( R \), is a fundamental constant in thermodynamics. Its value is approximately \( 8.314 \,\mathrm{J \, K^{-1} \, mol^{-1}} \).
The purpose of \( R \) is to relate thermal energy to mechanical work in ideal gas laws and thermodynamic equations.
  • In the context of the Van't Hoff equation, \( R \) acts as a proportionality constant connecting changes in enthalpy and entropy to temperature variations.
  • It's a bridge between macroscopic and molecular-level descriptions of gases.
Understanding \( R \) is essential for applying thermodynamic calculations involving gases, linking energy transfer to physical phenomena like pressure and volume.

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Most popular questions from this chapter

Is \(\Delta S_{\text {surr favorable or unfavorable for exothermic reactions? }}\) Endothermic reactions? Explain.

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