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Equilibrium Expressions

Equilibrium Expressions. The law of chemical equilibrium The equilibrium constant expression Expressions for homogeneous equilibria Expressions for heterogeneous equilibria Equilibrium constants. Equilibrium Reviewed.

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Equilibrium Expressions

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  1. Equilibrium Expressions The law of chemical equilibrium The equilibrium constant expression Expressions for homogeneous equilibria Expressions for heterogeneous equilibria Equilibrium constants

  2. Equilibrium Reviewed • Some chemical systems have little tendency to react. Others go to completion. • The majority of reactions reach a state of equilibrium with some of the reactants unconsumed. • If the reactants are not all consumed, then the amount of products produced is less than the amount predicted b y the balanced chemical reaction (think % yield from when we originally did stoichiometry). • According to the equation for the ammonia-producing reaction, 2 mol of ammonia should be produced when 1 mol of nitrogen and 3 mol of hydrogen react. • However, because the reaction reaches a state of equilibrium, less than 2 mol of ammonia are obtained.

  3. The Law of Chemical Equilibrium • In 1864, Norwegian chemists Cato Maximilian Guldberg and Peter Waage jointly proposed and developed the law of chemical equilibrium, which states that at a given temperature, a chemical system might reach a state in which a particular ratio of reactant and product concentrations has a constant value.

  4. The Equilibrium Constant Expression • The general equation for a reaction at equilibrium is as follows: aA + bB cC + dD • If the law of chemical equilibrium is applied to this reaction, the following ratio is obtained: Keq = [A] and [B] are the concentrations of the reactants and [C] and [D] are the concentrations of the products; a, b, c, and d are the coefficients from the balanced chemical equation.

  5. WARNING: Be Careful! • The equilibrium constant expression is the ration of the molar concentrations of the PRODUCTS to the molar concentrations of the reactants with each concentration raised to a power equal to its coefficient in the balanced chemical equation. • In other words, the NUMERATOR = PRODUCTS, and the DENOMINATOR = REACTANTS

  6. The Equilibrium Constant • The equilibrium constant, Keq, is the numerical value of the ratio of product concentrations to reactant concentrations, with each concentration raised to its coefficient in the balanced equation. • The value of Keq is constant only at specified temperatures.

  7. Interpreting the size of Keq • Recall that a fraction with a numerator greater than its denominator has a value greater than 1. • A fraction with a numerator less than its denominator has a value less than 1. • For example, compare the ratios 5/1 and 1/5. • Five is a larger number than one-fifth. • Because the PRODUCT concentrations are in the numerator of the equilibrium expression, a numerically large Keq means that the equilibrium mixture contains more products than reactants. • Similarly, a Keq less than 1 means that the equilibrium mixture contains more reactants than products. Keq >1: Products are favored at equilibrium Keq <1: Reactants are favored at equilibrium

  8. Expressions for Homogenous Equilibria • Gaseous hydrogen iodide is produced by the equilibrium reaction of gaseous hydrogen gas with iodine. • How would you write the equilibrium constant expression for this reaction in which hydrogen and iodine react to form hydrogen iodide? H2 (g) + I2 (g)  2 HI (g) • This reaction is a homogeneous equilibrium, which means that all the reactants and products are in the same physical state. • Since all the chemicals are gases, instead of molar concentration expressed with [], we use partial pressures of the gases, expressed with (). • The expression would become: Keq =

  9. Expressions for Heterogeneous Equilibria • When the reactants and products are in more than one physical state, the equilibrium is called heterogeneous equilibrium. • For example, when ethanol is placed in a closed flask, a liquid-vapor equilibrium is established: C2H5OH (l)  C2H5OH (g) • To write the equilibrium constant expression for this process, you would form a ratio of the product to the reactant.

  10. What is the “concentration” of a pure liquid? • Note that the concentration of liquid ethanol is in the denominator. • Liquid ethanol is a pure substance, so its concentration is its density expressed in moles per liter. • Recall that at any given temperature, density is constant. • No matter how much or how little C2H5OH is present, its concentration remains constant. • Therefore, the “concentration” of the pure liquid is said to be 1, and the term drops out of the equilibrium expression. • Keq = = = (PC2H5OH (g))

  11. States of Matter Summary • Solids behave the same way liquids do in terms of “concentrations” at equilibrium – they don’t have one! • ONLY gases and aqueous solutions are represented by equilibrium expressions. • Remember to use partial pressure and () for gases, and molarity and [] for solutions!

  12. Equilibrium Constants • For a given reaction at a given temperature, Keq will always be the same regardless of the initial concentrations of reactants and products. • To test this statement, three experiments were carried out using the following reaction: H2 (g) + I2 (g)  2 HI (g) Keq = • The results are summarized on the following slide. NOTE: I used [] instead of () to make my life easier on the computer. Since the chemicals are all gases, they should partial pressures in ().

  13. Experimental Data for HI Reaction Equilibrium

  14. Experimental Set-Up • In Trial 1, 1.0000 mol of H2 and 2.0000 mol of I2 were placed in a 1.0000-L vessel. • No HI was present at the beginning of Trial 1. • In Trial 2, only HI was present a the start of the experiment. • In Trial 3, each of the three substances had the same initial concentration. • The reactions were carried out at 731 K.

  15. Equilibrium Concentrations • When equilibrium was established, the concentration of each substance was determined experimentally. • Note that the equilibrium concentrations are not the same in the three trials, yet when each set of equilibrium concentrations is put into the equilibrium constant expression, the value of Keq is the same. • Each set of equilibrium concentrations represents an equilibrium position.

  16. The Value of Keq • Although an equilibrium system has only one value for Keq at a particular temperature, it has an unlimited number of equilibrium positions. • Equilibrium positions depend on the initial concentrations of reactants and products. • The large value of Keq for the H2 (g) + I2 (g)  2 HI (g) reaction means that at equilibrium, the product is present in larger amounts than the reactants. • However, many equilibria have small Keq values. • For the equilibrium N2 (g) + O2 (g)  2 NO (g), Keq equals 4.6 x 10-31 at 298 K. • A Keq this small means that the product, NO, is practically nonexistent at equilibrium. • BTW, Keq is unit-less.

  17. Equilibrium Characteristics • All chemical reactions that reach equilibrium have the following three things in common: • The reaction must take place in a closed system – no reactant or product can enter or leave the system. • The temperature must remain constant. • All reactants and products are present, and they are in constant dynamic motion.

  18. HOMEWORK • Write equilibrium constant expressions for these equilibria: • N2O4 (g)  2 NO2 (g) • CH4 (g) + 2 H2S (g)  CS2 (g) + 4 H2 (g) • Write the chemical equilibrium equation that has the equilibrium constant expression Keq =

  19. MORE HOMEWORK 3) Write equilibrium constant expressions for these heterogeneous equilibria: a) C10H8 (s)  C10H8 (g) b) FeO (s) + CO (g) Fe (s) + CO2 (g) 4) Solid iron reacts with chlorine gas to form solid iron (III) chloride (FeCl3). Write the balanced equation and the equilibrium constant expression for the reaction.

  20. LAST HOMEWORK SLIDE 5) Calculate Keq for the reaction CO (g) + 3 H2 (g)  CH4 (g) + H2O (g) using the data [CO] = 0.0613 mol/L, [H2] = 0.1839 mol/L, [CH4] = 0.0387 mol/L and [H2O] = 0.0387 mol/L. 6) The reaction CoCl2 (g)  CO (g) + Cl2 (g) reaches equilibrium at 900 K. Keq is 8.2 x 10-2. If the equilibrium concentrations of CO and Cl2 are 0.150 M, what is the equilibrium concentration of CoCl2?

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