14.5 : Reaction Quotient

The equilibrium constant expression is written as the molar concentrations of the products, C and D, over the reactants, A and B, at equilibrium, each raised to their respective stoichiometric coefficients. When solved, the expression is equal to the equilibrium constant, K_c.

An expression in the same form can also be written for the reactants and products at any concentration, and the calculated quantity is known as the reaction quotient, Q_c.

Like Q_c, the Q_p expression can be written for gaseous reactions using partial pressures.

While K remains constant at a specific temperature irrespective of concentration, the value of Q changes as the reaction proceeds towards the products or the reactants.

The reaction quotient can be used to determine the direction a reaction will proceed in order to reach equilibrium.

At the start of a given reaction, if the concentration of the products is zero, the reaction quotient is zero.

Whenever the concentration of the reactants in the denominator is high, such that Q is smaller than K, the reaction will move to the right to synthesize more products until the system reaches equilibrium.

If the concentration of the reactants is zero, the reaction quotient is infinite.

Whenever the concentration of the products in the numerator is high, such that Q is larger than K, the reaction will move to the left to produce more reactants.

If Q is equal to K, the system is at equilibrium, and the rate of the forward and reverse reactions are equal.

Consider the given reaction with an equilibrium constant 50. If the reaction mixture contains 0.20 molar hydrogen, 0.20 molar iodine, and 1.7 molar hydrogen iodide, the direction of the reaction shown can be determined by calculating Q.

Substituting the given concentrations into the expression, Q equals 72, which is greater than K. Therefore, the reaction will shift towards the left.

The status of a reversible reaction is conveniently assessed by evaluating its reaction quotient (Q). For a reversible reaction described by m A + n B ÃÂ¢ÃÂÃÂ x C + y D, the reaction quotient is derived directly from the stoichiometry of the balanced equation as

Fourier transform diagram with mathematical symbols illustrating signal processing concepts.

where the subscript c denotes the use of molar concentrations in the expression. If the reactants and products are gaseous, a reaction quotient may be similarly derived using partial pressures:

Dynamic equilibrium; reversible reaction; equation: A + B ⇌ C + D; chemical balance diagram.

Note that the reaction quotient equations above are a simplification of more rigorous expressions that use relative values for concentrations and pressures rather than absolute values. These relative concentration and pressure values are dimensionless (they have no units); consequently, so are the reaction quotients.

The numerical value of Q varies as a reaction proceeds towards equilibrium; therefore, it can serve as a useful indicator of the reactionÃÂ¢ÃÂÃÂs status. To illustrate this point, consider the oxidation of sulfur dioxide:

Static equilibrium, ΣFx=0, free-body diagram, depicting forces, showing tension and gravity balance.

Two different experimental scenarios are possible here, one in which this reaction is initiated with a mixture of reactants only, SO₂ and O₂, and another that begins with only product, SO₃. For the reaction that begins with a mixture of reactants only, Q is initially equal to zero:

Chemical structure of dopamine; neuromodulator molecule diagram, biomedical research keyword.

As the reaction proceeds toward equilibrium in the forward direction, reactant concentrations decrease (as does the denominator of Q_c), product concentration increases (as does the numerator of Q_c), and the reaction quotient consequently increases. When equilibrium is achieved, the concentrations of reactants and product remain constant, as does the value of Q_c.

If the reaction begins with only product present, the value of Q_c is initially undefined (immeasurably large, or infinite):

Evolutionary tree diagram showing species divergence based on sequence homology.

In this case, the reaction proceeds toward equilibrium in the reverse direction. The product concentration and the numerator of Q_c decrease with time, the reactant concentrations and the denominator of Q_c increase, and the reaction quotient consequently decreases until it becomes constant at equilibrium. The constant value of Q exhibited by a system at equilibrium is called the equilibrium constant, K:

Kirchhoff's Circuit Laws, electrical circuit diagram, equations ΣV=0, ∑I=0, current analysis.

Evaluating a Reaction Quotient

Gaseous nitrogen dioxide forms dinitrogen tetroxide according to this equation:

Kirchhoff's voltage law circuit diagram, loop equation ΣV=0, basic electrical concept for analysis.

When 0.10 mol NO₂ is added to a 1.0-L flask at 25 ÃÂÃÂ°C, the concentration changes so that at equilibrium, [NO₂] = 0.016 M and [N₂O₄] = 0.042 M. Before any product is formed, [NO₂] = 0.10 M and [N₂O₄] = 0 M. Thus,

Bohr model diagram, electron orbits, hydrogen atom energy levels, quantum physics.

At equilibrium,

$General formula for kinetic energy \( KE = \frac{1}{2}mv^2 \) in physics equation format.$

This text has been adapted from Openstax, Chemistry 2e, Section 13.2 Equilibrium Constants.

Tags

Reaction Quotient Equilibrium Constant Expression Molar Concentrations Stoichiometric Coefficients Equilibrium Constant Kc Qc Qp Gaseous Reactions Partial Pressures Direction Of Reaction System At Equilibrium Reactants Products

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