5 Must Know Facts For Your Next Test

1. The value of the equilibrium constant is temperature-dependent; changing the temperature can alter the ratio of products to reactants at equilibrium.
2. For a given reaction: $$aA + bB \rightleftharpoons cC + dD$$, the equilibrium constant is expressed as: $$K = \frac{[C]^c[D]^d}{[A]^a[B]^b}$$.
3. If K > 1, the products are favored at equilibrium; if K < 1, the reactants are favored.
4. The equilibrium constant can be derived from Gibbs free energy change ($$\Delta G$$), where $$K = e^{-\Delta G^\circ/(RT)}$$.
5. In reactions involving gases, the equilibrium constant can also be expressed in terms of partial pressures instead of concentrations.

Review Questions

• How does the equilibrium constant relate to Gibbs free energy and spontaneity in chemical reactions?
  • The equilibrium constant and Gibbs free energy are interconnected through the relationship that links them mathematically. The equation $$K = e^{-\Delta G^\circ/(RT)}$$ shows that at equilibrium, the value of K can indicate whether a reaction is spontaneous. If $$\Delta G < 0$$ (spontaneous), K will be greater than 1, favoring products. Conversely, if $$\Delta G > 0$$ (non-spontaneous), K will be less than 1, indicating that reactants are favored.
• Discuss how changes in concentration or temperature affect the equilibrium constant according to Le Chatelier's Principle.
  • According to Le Chatelier's Principle, when a change is imposed on a system at equilibrium—like altering concentrations or temperature—the system will adjust to minimize that change. However, while changes in concentration affect the position of equilibrium, they do not change the value of the equilibrium constant itself. On the other hand, altering temperature does affect K; increasing temperature typically favors endothermic reactions and decreases K for exothermic reactions.
• Evaluate how understanding equilibrium constants can impact real-world applications such as chemical manufacturing or environmental science.
  • Understanding equilibrium constants is crucial for optimizing conditions in chemical manufacturing processes, enabling industries to produce desired products more efficiently by favoring favorable reactions through temperature and concentration adjustments. For instance, knowing K helps engineers design reactors that maximize yield. In environmental science, knowledge of K aids in predicting how pollutants will behave in natural systems, informing remediation strategies by assessing how changes in conditions might shift equilibria and influence contaminant concentrations in ecosystems.

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