The common-ion effect is an application of Le Chatelier\'s principle, which stat
ID: 683897 • Letter: T
Question
The common-ion effect is an application of Le Chatelier's principle, which states that an equilibrium system that is stressed will work to alleviate that stress and reestablish equilibrium. The common-ion effect and solubility The solubility of a slightly soluble salt can be greatly affected by the addition of a soluble salt with a common ion, that is. with one of the ions in the added soluble salt being identical to one of the ions of the slightly soluble salt. The general result of the addition of the common ion is to greatly reduce the solubility of the slightly soluble salt. In other words, the addition of the common ion results in a shift in the equilibrium of the slightly soluble salt. Part A Mg(OH)2 is a sparingly soluble salt with a solubility product, Ksp of 5.61 times 10-11 It is used to control the pH and provide nutrients in the biological (microbial) treatment of municipal wastewater streams. What is the ratio of solubility of Mg(OH)2 dissolved in pure H2O to Mg(OH)2 dissolved in a 0.ll 0 M NaOH solution? Express your answer numerically as the ratio of molar solubility in H2O to the molar solubility in NaOH The common-ion effect and buffer systems A buffer is a mixed solution of a weak acid or base, combined with its conjugate. Note that this can be understood essentially as a common-ion problem: The conjugate is a common ion added to an equilibrium system of a weak acid or base. The addition of the conjugate shifts the equilibrium of the system to relieve the stress of the added concentration of the common ion. In a solution consisting of a weak acid or base, the equilibrium shift also results in apH shift of the system. It is the presence of the common ion in the system that results in buffering behavior, because both added H+ or OH- ions can be neutralized. PartB What is the pK change of a 0.240 M solution of citric acid(pKa = 4.77) if citrate is added to a concentration of 0.165 M with no change in volume?Explanation / Answer
Part a: Mg(OH)2 = Mg+2 + 2OH- In water: Ksp = (x)(2x)^2 = 4x^3 = 5.61e-11 x = .000241 M In .110 M NaOH Ksp = (x)(2x+.110)^2 = 5.61e-11 x = 4.63e-9 M Compare the two: .000241/4.63e-9 = 5.21e4 Part 2: Ka = 10-pKa = 10-4.77 = 1.70e-5 1.70e-5 = x^2 / (0.240-x) x = [H+] =.00201M pH = - log 0.00201 = 2.697 pH = pKa + log 0.165 / 0.240 pH = (4.77+log .165/.240) pH = 4.61 Change in pH = 4.61 - 2.697 = 1.91