Chapter 16

Chapter 16 Acids and Bases

Arrhenius Acid-Base Theory Arrhenius, Svante August • (1859-1927), Swedish chemist • 1903 Nobel Prize in chemistry acid - hydrogen ion (proton) donor base - hydroxide ion donor

Bronsted-LowreyAcid-Base Theory acid - proton donor base - proton acceptor strong vs. weak acids and bases • strong - completely ionized • weak - partially ionized

Brönsted-LowryAcid-Base Systems Acid-Base Conjugate Pairs conjugate base => what results when an acid looses its proton conjugate acid => what results when a base gains its proton

Water’s Role as Acid or Base Water acting as a Base HA + H2O  H3O+ + A- acid base Water acting as an Acid B + H2O  BH+ + OH- base acid

Conjugate Acid-Base Pairs

Relative Strengths of Acid and Bases

Strong vs. Weak Acids and Bases strong acid • completely ionized weak acid • partially ionized

Mixtures of Strong and Weak Acids • the presence of the strong acid retards the dissociation of the weak acid

Carboxylic Acids

Amines

Autoionization of Water H2O + H2O  H3O+ + OH- [H3O+][OH-] K = [H2O]2 Kw = K [H2O]2 = [H3O+][OH-] = 1.0  10-14

Autoionization of Water Kw = [H3O+][OH-] = 1.0  10-14 for a neutral solution [H3O+] = [OH-] [H3O+][H3O+] = 1.0 x 10-14 [H3O+]2 = 1.0 x 10-14 [H3O+] = 1.0 x 10-7 -log([H3O+]) = -log(1.0  10-7) pH = -log([H3O+]) = 7.00

Autoionization of Water a solution is considered acidic when [H3O+] > 1.0  10-7 M [OH-] < 1.0  10-7 M a solution is considered bacic when [H3O+] < 1.0  10-7 M [OH-] > 1.0  10-7 M

pH Scale pH = - log10[H3O+] pH Scale @ -2 => @ +16

pOH Scale pOH = - log10[OH-] pOH Scale @ -2 => @ +16

Solutions of Strong Acids [H3O+] = Macid pH = - log10[H3O+] = - log10(Macid)

pH of Aqueous Solutions

Concentration Scales a solution is considered acidic when pH < 7 and pOH > 7 a solution is considered bacic when pH > 7 and pOH < 7 pKw = pH + pOH = 14.00

EXAMPLE: What is the pH of a solution that has a [H3O+] = 0.435 M? pH = - log10[H3O+] = - log10(0.435) = 0.362

EXAMPLE: What is the pH of a solution that has a [OH-] = 25M? pOH = - log10[OH-] = - log10(25) = - 1.40 = 14.00 - (- 1.40) pH = 14.00 - pOH = 15.40

Measuring pH Arnold Beckman • inventor of the pH meter • father of electronic instrumentation

pH Meter Photo by George Lisensky

Acid Dissociation Constant HC2H3O2 + H2O  H3O+ + C2H3O2- [H3O+][C2H3O2-] K = [H2O][HC2H3O2] [H3O+][C2H3O2-] Ka = K  [H2O] = [HC2H3O2]

Base Dissociation Constant NH3 + H2O  NH4+ + OH- [NH4+][OH-] K = [H2O][NH3] [NH4+][OH-] Kb = K  [H2O] = [NH3]

Hydrated Metal Ions as Acids

Ionization Constants for Acids

Polyprotic Acids • acids where more than one hydrogen per molecule is released

Polyprotic Acids

EXAMPLE: Calculate the [H3O+] in an aqueous 0.140 M acetic acid solution. HC2H3O2 + H2O  H3O+ + C2H3O2- CHA = 0.140 M [H3O+]e[C2H3O2-]e Ka = = 1.75  10-5 M [HC2H3O2]e let [H3O+]e» [C2H3O2-]e [HC2H3O2]e= 0.140M - [H3O+]e

EXAMPLE: Calculate the [H3O+] in an aqueous 0.140 M acetic acid solution. CHA = 0.140 M Ka = 1.75  10-5 M let [H3O+]e» [C2H3O2-]e [HC2H3O2]e= 0.140M - [H3O+]e using the quadratic equation - Ka + (Ka2 + 4KaCHA)1/2 [H3O+]e = 2 [H3O+]e = 1.56  10-3 M

EXAMPLE: A saturated aqueous solution of caproic acid contains 11 g/L and has a pH = 2.94. What is its Ka? HC6H11O2 + H2O  H3O+ + C6H11O2- [H3O+]e[C6H11O2-]e Ka = = ? [HC6H11O2]e [H3O+]e = 10-pH = 10-2.94 = 1.1  10-3 M [C6H11O2-]e = [H3O+]e = 1.1  10-3 M [HC6H11O2]i = (11 g/L)(1 mol/116 g) = 9.5  10-2 M

EXAMPLE: A saturated aqueous solution of caproic acid contains 11 g/L and has a pH = 2.94. What is its Ka? [C6H11O2-]e = [H3O+]e = 1.1  10-3 M [HC6H11O2]e = 9.4 x 10-2 M [H3O+]e[C6H11O2-]e Ka = [HC6H11O2]e (1.1  10-3 M)2 Ka = = 1.3  10-5 M 9.4  10-2 M

Influence of Molecular Structure on Acid Strength Binary Hydrides • hydrogen & one other element • Bond Strengths • weaker the bond, the stronger the acid • Stability of Anion • higher the electronegativity, stronger the acid

Influence of Molecular Structure on Acid Strength Oxyacids • hydrogen, oxygen, & one other element H-O-E • higher the electronegativity on E, stronger the acid as this weakens the bond between the O and H

The Conjugate Partners of Strong Acids and Bases • the conjugate base of a strong acid has no net effect on the pH of a solution

Weak Acids and Bases:Qualitative Aspects The Competition for Protons acid1 + base2 base1 + acid2

Weak Acids and Bases:Qualitative Aspects The Leveling Effect of the Solvent in water both HClO4 and HCl are strong acids

Weak Acids and Bases:Qualitative Aspects The Leveling Effect of the Solvent in glacial acetic acid HClO4 + CH3COOH(l) => CH3COOH2+ + ClO4- complete dissociation, thus strong acid HCl + CH3COOH(l) CH3COOH2+ + Cl- incomplete dissociation, equilibrium established, weak acid

Solutions of Salts of Weak Acids A- + H2O  HA + OH- Kw [HA][OH-] Kh = K'b = = Ka [A-]

Acid-Base Properties of Typical Ions

Acid-Base Chemistryof Some Antacids

Acid-Base in the Kitchen vinegar - acetic acid lemon juice (citrus juice) - citric acid baking soda - NaHCO3 milk - lactic acid baking powder - H2PO4- & HCO3-

Household Cleaners

Lewis Acids and Bases • acid => electron pair acceptor • base => electron pair donor the base donates a pair of electrons to the acid forming a coordinate covalent bond

Lewis Acids and Bases Reactions H+ + NH3  NH4+ acid base Cu+2 + 4 NH3 [Cu(NH3)4+2] acid base

Chapter 16

Chapter 16

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Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

CHAPTER 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16

Chapter 16