Glossary

10.2 Equilibrium constants and rate constants

2 min readjuly 22, 2024

Chemical reactions are all about balance and speed. Equilibrium constants tell us where reactions end up, while rate constants show how fast they get there. These two constants are closely linked, helping us understand and predict chemical behavior.

By comparing equilibrium and rate constants, we can figure out which direction a reaction will go and how quickly. This knowledge is crucial for controlling reactions in labs and industry, making it a key part of chemical kinetics.

Equilibrium Constants and Rate Constants

Equilibrium and rate constants

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  • (KK) represents the ratio of product concentrations to reactant concentrations at equilibrium, indicating the extent to which a reversible reaction proceeds at equilibrium and determining the equilibrium composition of a reaction mixture without depending on the initial concentrations of reactants or products
  • (kk) quantifies the speed of a chemical reaction, determining how quickly reactants are converted into products, and depends on factors such as , activation energy, and the presence of catalysts, being specific to each elementary step in a complex reaction mechanism

Relationship between constants

  • Consider a general reversible reaction: aA+bBcC+dDaA + bB \rightleftharpoons cC + dD
  • The rate law for the forward reaction: Ratef=kf[A]a[B]b\text{Rate}_f = k_f[A]^a[B]^b
  • The rate law for the reverse reaction: Rater=kr[C]c[D]d\text{Rate}_r = k_r[C]^c[D]^d
  • At equilibrium, the forward and reverse rates are equal: kf[A]a[B]b=kr[C]c[D]dk_f[A]^a[B]^b = k_r[C]^c[D]^d
  • Rearrange the equation to obtain the equilibrium constant expression: K=[C]c[D]d[A]a[B]b=kfkrK = \frac{[C]^c[D]^d}{[A]^a[B]^b} = \frac{k_f}{k_r}, showing that the equilibrium constant is equal to the ratio of the forward and reverse rate constants

Calculations with constants

  • Given the rate constants kfk_f and krk_r, calculate the equilibrium constant: K=kfkrK = \frac{k_f}{k_r} (example: if kf=2.5×103k_f = 2.5 \times 10^{-3} M1^{-1}s1^{-1} and kr=5.0×104k_r = 5.0 \times 10^{-4} s1^{-1}, then K=2.5×1035.0×104=5.0K = \frac{2.5 \times 10^{-3}}{5.0 \times 10^{-4}} = 5.0 M1^{-1})
  • Given the equilibrium constant KK and one of the rate constants, calculate the other rate constant:
    1. If KK and kfk_f are known, calculate krk_r: kr=kfKk_r = \frac{k_f}{K}
    2. If KK and krk_r are known, calculate kfk_f: kf=K×krk_f = K \times k_r

Reaction direction from constants

  • The magnitude of the equilibrium constant indicates the relative concentrations of products and reactants at equilibrium:
    • If K>1K > 1, the equilibrium favors the products (forward reaction is favored)
    • If K<1K < 1, the equilibrium favors the reactants (reverse reaction is favored)
    • If K=1K = 1, the concentrations of products and reactants are equal at equilibrium
  • The direction of a reaction can be predicted by comparing the (QQ) to the equilibrium constant (KK):
    1. If Q<KQ < K, the reaction will proceed in the forward direction to reach equilibrium
    2. If Q>KQ > K, the reaction will proceed in the reverse direction to reach equilibrium
    3. If Q=KQ = K, the reaction is at equilibrium, and no net change in concentrations will occur

Key Terms to Review (16)

Dynamic Equilibrium: Dynamic equilibrium is a state in which the rates of the forward and reverse reactions in a chemical system are equal, resulting in constant concentrations of reactants and products over time. This concept is essential to understanding how chemical reactions behave under different conditions and illustrates the balance between kinetics and thermodynamics within a reaction.
Equilibrium Constant: The equilibrium constant is a numerical value that expresses the ratio of the concentrations of products to reactants at equilibrium for a given chemical reaction at a specific temperature. This constant provides insights into the position of equilibrium and indicates whether products or reactants are favored in a reversible reaction, impacting various kinetics concepts.
Forward reactions: Forward reactions refer to the process in which reactants are converted into products in a chemical reaction. This term is important for understanding how the rate of a reaction progresses, as it directly relates to the concept of equilibrium and the dynamic state of chemical systems where reactants and products are continually transformed back and forth.
Henri-Louis Le Chatelier: Henri-Louis Le Chatelier was a French chemist best known for his principle, which states that if a system at equilibrium is disturbed, it will adjust to counteract the disturbance and restore a new equilibrium. This principle connects directly to concepts such as equilibrium constants and rate constants, highlighting how changes in concentration, temperature, or pressure affect the rates of reactions and the position of equilibrium.
Irreversible Reactions: Irreversible reactions are chemical reactions that proceed in one direction only, leading to the formation of products that cannot be converted back to reactants under standard conditions. This means that once the reaction has occurred, the reactants are permanently transformed into products, and the reaction does not reach a state of equilibrium. Understanding irreversible reactions is crucial because they can significantly influence the calculation of rate constants and equilibrium constants in chemical kinetics.
Kc: Kc, or the equilibrium constant, is a value that expresses the ratio of the concentrations of products to reactants at equilibrium for a given chemical reaction at a specific temperature. It provides insight into the extent to which a reaction proceeds, indicating whether products or reactants are favored when the system reaches equilibrium. Understanding Kc is essential for analyzing reaction dynamics and predicting the behavior of chemical systems.
Kp: The symbol $$k_p$$ refers to the equilibrium constant for a reaction when expressed in terms of partial pressures of the gaseous reactants and products. This constant is used in the context of gas-phase reactions, allowing chemists to relate the concentrations of gases at equilibrium to their pressures, which helps in understanding the extent of a reaction under specific conditions.
Le Chatelier's Principle: Le Chatelier's Principle states that if a dynamic equilibrium is disturbed by changing the conditions, the position of equilibrium shifts to counteract that change and restore a new equilibrium. This principle helps explain how systems respond to alterations in concentration, temperature, and pressure, connecting various aspects of chemical kinetics and thermodynamics, including the behavior of equilibrium constants and rate constants.
Le Chatelier's Principle Applications: Le Chatelier's Principle states that if an external change is applied to a system at equilibrium, the system will adjust to counteract that change and restore a new equilibrium. This principle is vital in understanding how changes in concentration, temperature, and pressure affect the position of equilibrium in chemical reactions, linking it closely to equilibrium constants and rate constants.
Rate Constant: The rate constant is a proportionality factor in the rate law that quantifies the speed of a chemical reaction at a given temperature. It connects the concentration of reactants to the reaction rate, showing how quickly the reaction proceeds. The value of the rate constant is influenced by factors such as temperature, activation energy, and the presence of catalysts, making it a key element in understanding reaction kinetics and dynamics.
Reaction quotient: The reaction quotient, denoted as Q, is a measure of the relative concentrations of reactants and products at any given point in a chemical reaction, not necessarily at equilibrium. It provides insight into the direction in which a reaction is likely to proceed, helping to predict whether a system will shift toward the products or reactants to reach equilibrium. Understanding Q is crucial for connecting the concepts of equilibrium constants and rate constants, as it helps in analyzing dynamic chemical processes.
Reverse reactions: Reverse reactions refer to the process in which the products of a chemical reaction react to form the original reactants. This concept is fundamental in understanding the dynamic nature of chemical equilibria, where both forward and reverse reactions occur simultaneously. Reverse reactions are crucial for explaining how equilibrium is achieved and maintained in a system, highlighting the interdependence between reaction rates and equilibrium constants.
Reversible reactions: Reversible reactions are chemical processes that can proceed in both the forward and reverse directions, allowing the reactants to form products and the products to reform reactants. This dynamic balance between the two states is characterized by the concept of chemical equilibrium, where the rate of the forward reaction equals the rate of the reverse reaction. Understanding reversible reactions is crucial for studying how reactions reach equilibrium and how various factors can affect that balance.
Shift in equilibrium: A shift in equilibrium refers to a change in the balance between reactants and products in a chemical reaction at equilibrium, often due to external changes in conditions such as concentration, temperature, or pressure. This dynamic process allows a reaction to respond to disturbances and re-establish a new equilibrium state, illustrating the principle of Le Chatelier's principle.
Svante Arrhenius: Svante Arrhenius was a Swedish scientist known for his contributions to physical chemistry, particularly in understanding reaction rates and the concept of activation energy. His work established a mathematical relationship between temperature and the speed of chemical reactions, leading to the development of the Arrhenius equation, which connects equilibrium constants and rate constants to temperature changes. This foundational concept helps explain how reactions proceed and the influence of various factors on reaction rates.
Temperature: Temperature is a measure of the average kinetic energy of the particles in a substance, influencing how fast molecules move and collide. It plays a crucial role in determining reaction rates, as higher temperatures generally increase the frequency and energy of collisions between reactant molecules, thus affecting reaction kinetics across various chemical processes.
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