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6: Chemical Equilibrium

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    556318

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    • 6.1: Equilibrium Results when Gibbs Energy is Minimized
      This page emphasizes the significance of chemical reactions in solutions, particularly in water, focusing on the extent of reaction (\(ξ\)) and its measurement through the indirect quantity \(q\). It outlines the relationship between Gibbs free energy and \(ξ\), highlighting that equilibrium is achieved when Gibbs energy is minimized. Additionally, it discusses gas reactions, introduces the reaction quotient \(Q\), and addresses varying standard potentials within thermodynamics.
    • 6.2: An Equilibrium Constant is a Function of Temperature Only
      This page explains the relationship between Gibbs energy and equilibrium constants using the Van't Hoff equation, which connects temperature, equilibrium constant \(K\), and reaction enthalpy \(\Delta_rH\). It discusses how pressure and temperature changes affect equilibrium positions per Le Chatelier's Principle and clarifies the relationship between concentration and pressure in ideal gases, including the influence of activity coefficients in non-ideal solutions.
    • 6.3: Gibbs Energy of a Reaction vs. Extent of Reaction is a Minimum at Equilibrium
      This page explains the extent of reaction (\(\xi\)), which quantifies the progress of a chemical reaction. It covers the changes in Gibbs free energy relative to \(\xi\), conditions for spontaneity and equilibrium, and the relationship between chemical potentials of reactants and products.
    • 6.4: The Sign of ΔG and not ΔG° Determines the Direction of Reaction Spontaneity
      This page explains the difference between Gibbs energy of reaction (\(\Delta_rG\)) and standard state Gibbs energy of reaction (\(\Delta_rG^\circ\)). It notes that \(\Delta_rG^\circ\) indicates that the formation of ammonia from nitrogen and hydrogen is favored under standard conditions. The Gibbs energy changes with composition and becomes zero at equilibrium when the reaction quotient matches the equilibrium constant.
    • 6.5: The van 't Hoff Equation
      This page explains the Gibbs-Helmholtz equation's significance in analyzing how the equilibrium constant \(K\) varies with temperature in chemical reactions, emphasizing the connection to the reaction's enthalpy \(ΔH^o\).

    This page titled 6: Chemical Equilibrium is shared under a not declared license and was authored, remixed, and/or curated by Kathryn Davis.