Acid-base theory pH calculations

Acid-base theorypH calculations Joško Ivica

REVIEW QUESTIONS • Write the formulas for hydrochloric acid, potassium hydroxide and their dissociation reactions in water • Write the formulas for acetic acid, ammonia and their dissociation reactions in water • Write the equation for equilibrium dissociation constant of acetic acid • Write the formula for sodium acetate and its dissociation reaction in water • What is pH? • Ionic product of water

REVIEW H2O KA • HCl H+ + Cl-or HCl + H2O H3O+ + Cl- KOH K+ + OH- • CH3COOH + H2O CH3COO- + H3O+ CH3COOH CH3COO- + H+ NH3 + H2O NH4+ + OH- 3) [CH3COO-] [H+] • CH3COONa CH3COO-+ Na+ • pH = -log[H+] • KW = [H+][OH-] = 1,008·10-14at 25°C pOH = -log[OH-] pH + pOH = 14 = pKW! KA KB KA = [CH3COOH]

ACIDS AND BASES Arrhenius theory: Acids are compounds able to dissociate in water producing a hydrogen ion (H+) and a corresponding anion (only in aqueous solutions) HNO3 H+ + NO3- Bases are compounds which dissociate in water producing a hydroxide ion and a cation NaOH  Na+ + OH- Brønsted - Lowry theory:Acids are compounds that release H+, whereas bases are compounds that are able to bind H+ (applicable also in non-aqueous solutions) acidH+ +base conjugated pair

pH of strong acids and bases c(HA) = [H+] = [A-] HA H+ + A- complete dissociation of an acid pH = -log a(H+) a – activity a(H+) = γ±·c(HA) γ± - mean activity coefficient In very diluted solutions: γ± = 1! pH = -log[H+]

pH of strong acids and bases complete dissociation of a base pOH = -log[OH-] c(BOH) = [OH-] = [B+] BOH B+ + OH- pH = 14 - pOH = 14 + [log a(OH-)] a(OH-) = γ±·c(BOH) In very diluted solutions: γ± = 1! pH = 14 - pOH= 14 + log [OH-]

pH of weak acids and bases c-x x x [A-][H3O+] x2 x2 [HA] Dissociation of weak acids(Ka< 10-4) HA + H2O A- + H3O+Ka= = = c-x c c-x = concentration of an acid at equilibrium x = concentration of products at equilibrium c = concentration of an acid at the beginning c >> x for diluted weak acids pKa = -logKa [H3O+] = x = (Ka c)1/2/ log pH = -log[H3O+] pH = -log [H3O+] = ½ [pKa – log(c)]

pH of weak acids and bases c-x x x [BH+][OH-] x2 x2 B + H2O BH+ + OH- Kb = = = [B] c-x c Dissociation of weak bases c-x = concentration of a base at equilibrium x = concentration of products at equilibrium c >> x for diluted weak bases c = concentration of a base at the beginning pKb = -logKb [OH-] = x = (Kb c)1/2/ log pOH = -log[OH-] pH = 14 - pOH pH = 14 – pOH = 14 – ½ [pKb – log(c)]

Salt hydrolysis • When salts composed of ions of a strong electrolyte (acid or base) and ions of a weak electrolyte are dissolved, complete salt dissociation occurs because ions of a strong electrolyte can exist only in ionized form • Ions originating from a weak electrolyte react with water producing their conjugated particle • Examples: CH3COONa, KCN, NH4Cl, NH4NO3

Salts of weak acids and strong bases [CH3COO-] [H+] KA = [CH3COOH] [CH3COOH] [ OH- ] CH3COO- + H2O CH3COOH + OH- KH = CH3COONa CH3COO- + Na+ [CH3COO-] [H+][OH-] = Kv KH·KA = KW  KH= KW/KA c-x x x CH3COO- + H2O CH3COOH + OH- [CH3COOH] = [OH-] c = concentration of salt at the beginning c-x = concentration of anion of a weak acid at equilibrium x = concentration of products at equilibrium [OH-]2 KW = 10-14 = c-x = c c KA

[OH-]2 = KW · c (salt) pOH = 7 – 1/2[pKA – log(c)] KA pH = 14 - pOH [pKA + log(c)] pH = 7 + ½

Salts of weak bases and strong acids [NH4+] [OH-] [NH3] NH4Cl NH4+ + Cl-KB = NH4+ + H2O NH3 + H3O+ KH = [H+][OH-] = Kv [NH3] [H3O+] [NH4+] KH·KB = KW  KH= KW/KB NH4+ + H2O NH3 + H3O+ [H3O+] = [NH3] c-x x x c = concentration of salt at the beginning KW [H3O+]2 = c c-x = c KB c-x = concentration of a cation of a weak base at equilibrium x = concentration of products at equilibrium

[H3O+]2 = KW· c(salt) KB pH = 7 - ½[pKB + log(c)]

Salts of weak acids and weak bases Anions andcations of weak acids and bases, that produce salt – having concentration c, react with water e.g. NH4CN CN- + H2O = HCN + OH- NH4+ + H2O = NH3 + H3O+ NH4++ CN-HCN + NH3 c-xc-x x x c-x = c KH= [HCN][NH3]/[CN-][NH4+] = [HCN]2/[CN-]2 KH ·KA·KB = KW KH = KW/KA KB KA = [H3O+][CN-]/[HCN]  (1/KH)1/2 [H3O+]2 = KA2KH = KW · KA/KB [H3O+]2 = KW· KA KB pH = 7 + ½[pKA - pKB]

BUFFERS • BUFFERS = conjugated pairof acid or base, which is able to maintain pH in particular (narrow) interval after adding strong acid or base into solution (system) • Buffers are typically mixtures of weak acids and their salts with strong bases ormixtures of weak bases and their salts with strong acids • Buffer systems in organism are of a great importance (blood, intercellular space, cells)

pH calculations of buffer solutions Buffer consisting of a weak acid and its salt with a strong base HA + H2O A- + H3O+ Ka Henderson – Hasselbalch equation pH = pKa + log[A-]/[HA] HA – weak acid A- – conjugated base Buffer consisting of a weak base and its salt with a strong acid B + H2O BH+ + OH- pOH = pKb + log[BH+]/[B] B – weak base BH+ - conjugated acid

pH calculations • Calculatethe pH of 1 mM KOH • Calculatethe pH of 0.01 M formic acid (HCOOH) at 25°C, pKa = 3.8! • Calculatethe pH of 0.001 M NH3at 25°C, pKb = 4.8! • Calculatethe pH of 0.1 M NaCN at 25°C, pKa = 9.21! • Calculatethe pH of 0.7 M NH4Cl at 25°C, pKb = 4.8! • Calculatethe pH of 5 mM ammonium lactate CH3CH(OH)COONH4at 25°C, pKa = 3.86, pKb = 4.8 • Calculatethe pH of a buffer solution that contains 0.1 M CH3COONa and 0.1 M CH3COOH, pKa = 4.8! • Calculatethe pH of a buffer solution that contains 0.1 M NH4Cl and 1 M NH3, pKb = 4.8!

1. c(KOH) = 0,001 M = [K+] = [OH-] KOH  K+ + OH- pOH = -log [OH-] = 3 pH = 14 – pOH = 11

c(HCOOH) = 0.01 M, pKa = 3.8 HCOOH ↔ HCOO-+ H+ 0.01-x=cx x x = conc. of productsat equilibrium ↓ conc. of HCOOH at equilibrium Ka =[HCOO-][H+]/[HCOOH] = x2/c = [H+]2/0.01 [H+] = (Ka·0.01)1/2 pH = -log[H+] = ½ [3.8 – log(0.01)]= 2.9 2.

H2O NH3NH4+ + OH- 0.001-x x x x = conc. of productsat equilibrium ↓ conc. ofNH3at equilibrium0.001-x = c Kb=[NH4+][OH-]/[NH3] = x2/c = [OH-]2/0.001 [OH-] = (Kb·0.001)1/2 3. c(NH3) = 0.001 M, pKb = 4.8 pOH = -log[OH-] =½[pKb - log(0.001)] pH = 14 - ½[4.8 - log(0.001)] = 14 – 3.9 = 10.1

4. c(NaCN) = 0.1 M, pKa = 9.21 NaCN  Na+ + CN- HCN H+ + CN- Ka=[H+][CN-]/[HCN] CN- + H2O HCN + OH- KH = [OH-][HCN]/[CN-] c-x = c x x [HCN] = [OH-] Kv = Ka KH  Kv/ Ka = [OH-]2/c  [OH-] = (Kvc/ Ka)1/2 pOH = ½(pKv – pKa + log c)  pH = 14 - ½(pKW – pKa + log c) = pH = 7 + ½ [pKA + log(c)] = 7 + ½ (9.21 + log 0.1) = 11.1

H2O 5. c(NH4Cl) = 0.7 M, pKb = 4.8 NH4Cl  NH4+ + Cl- NH3NH4+ + OH- Kb = [NH4+][OH-]/[NH3] NH4+ + H2O NH3 + H3O+ KH = [NH3][H3O+]/[NH4+] c-x = c x x [NH3] = [H3O+] Kv = Ka KH  Kv/ Ka = [H3O+]2/c  [H3O+] = (Kvc/Kb)1/2 pH = 7 - ½[pKB + log(c)] = 7 – ½ (4.8 – 0.15) = 4.68

6. c(CH3CH(OH)COONH4) = 0.005 M, pKa = 3.86, pKb = 4.8 CH3CH(OH)COO- + H2O CH3CH(OH)COOH + OH- NH4+ + H2O NH3 + H3O+ CH3CH(OH)COO- + NH4+ CH3CH(OH)COOH + NH3 c-x c-x x x KH = [CH3CH(OH)COOH][NH3]/[CH3CH(OH)COO-][NH4+] = [CH3CH(OH)COOH]2/[CH3CH(OH)COO-]2 KW = KH KA KB KH = KW/KA KB KA = [H3O+][CH3CH(OH)COO-]/[CH3CH(OH)COOH] [H3O+]2 = KA2KH = KW · KA/KB pH = 7 + ½[pKA - pKB]= 7 + ½ [3.86 – 4.8] = 6.53 (1/KH)1/2

7. 0.1 M CH3COONa, 0.1 M CH3COOH, pKa = 4.8 CH3COOH + H2O CH3COO- + H3O+ Ka pH = pKa + log [CH3COO-]/[CH3COOH] = 4.8 + 0 = 4.8

8. 0.1 M NH4Cl a 1 M NH3, pKb = 4.8 NH3+ H2O NH4+ + OH- Kb pOH = pKb + log [NH4Cl]/[NH3] = 4.8 – 1 = 3.8 pH = 14 – pOH = 10.2

Acid-base theory pH calculations