CH. 17 ACID -- BASE EQUILIBRA & BUFFERS 17.1 Common ion effect 17.1 Calculation Henderson- Hasselbalch eqn Buffers how works ion effect pH range 17.3 Titration Curves indicators SA/SB - SA/WB WA/SB - Poly Calculation pH 17.4 Solubility Calculation Ksp (Qsp) precipation 17.5 Solubility; pH Complex Ions 17.6 &.7 Ion Groups Separation
COMMON ION EFFECT The shift in the position of an equilibrium on addition of a subst that provides an ion in common w / one of the ions already involved in the equilibrium process. Also, decr solubility of soluble aqueous portion of ionic cmpd Dissolve HNO 2 in NaNO 2 soln (H 2 O ) LeChatilier add NO 2 - ; from NaNO 2 H 3 O + + NO 2 - H 3 O + lowers pH; shifts away NO 2 - already formed
BUFFERS resist es in pH composed of: WA & CB or WB & CA Add sm amt base to buffer soln Acidic component neutralize base added BIO SYS: blood pH 7.4 control buffer of H 2 O / HCO 3 - Add sm amt acid to buffer soln Basic component neutralize acid added
Fig pg 664
HENDERSON -- HASSELBALCH To prep buffer soln select WA w / pK a close to 1 pH unit of buffer soln How pH affects % dissoc WA pH of buffer soln not depend on soln vol but on pK a & molar amt WA-CB EX. Titrant M NaOH and neutralize 40.0 ml of M butanoic acid (HC 4 H 7 O 2 ) K a = 1.54*10 -4 Find pH add ml of titrant Find pH at equivalence pt & determine best indicator to use
1 st determine # mmol HC 4 H 7 O 2 present mol HC 4 H 7 O 2 = 40.0 mL * (0.100 mmol / 1 mL) = 4.00 mmol need 4.00 mmol NaOH to reach equiv pt means need 40.0 ml of M NaOH b) Add ml NaOH, also midpoint so pH = pKa moles WA: 4.00 mmol mol NaOH added: ml*0.100 M= 2.00 mmol 2.0 mmol / 60 ml = M ratio of [HC 4 H 7 O 2 ] / [C 4 H 7 O 2 - ] = / = 1 a) No base, NaOH, added; butanoic WA: K a = x 2 / [HA] x 2 = (1.54*10 -4 )*(0.100) = pH = -Log( ) = 2.41
c) Add 40.0 ml equiv pt All HC 4 H 7 O 2 neutralized, find [C 4 H 7 O 2 - ] [C 4 H 7 O 2 - ] = mmol / tot mL pH = -Log(5.56*10 -9 ) = 8.25 indicator: PHENOLPHTHALEIN mmol C 4 H 7 O 2 - = ml * (0.100 mmol / ml) = 4.0 mmol [C 4 H 7 O 2 - ] = 4.0 mmol / 80.0 ml = 0.05 M
TITRATION CURVES Monoprotic Acids pH Vol SB 7 SA - SB
TITRATION CURVES Monoprotic Acids pH Vol SB 9 WA - SB
TITRATION CURVES Monoprotic Acids pH Vol SA 3.5 SA - WB
TITRATION CURVES Polyprotic Acids pH Vol Base H 2 SO 4 HSO 4 - pK a1 SO 4 -2 pK a2
Problem 25.0-mL of M HCl soln is titrated by M KOH. How many mL of base must be added to reach the end point. Want: mL KOH Data: 25.0-mL mol/L mol/L KOH HCl + KOH --- H 2 O + KCl 1 mol HCl = 1 mol KOH
Problem What is the pH at each point in the titration of mL of M HAc with M NaOH? a) before NaOH added b) after mL c) after mL d) after mL (these are volumes added to original 25 ml) a. Find initial [H 3 O + ]; use Ka (1.8*10 -5 ) HC 2 H 3 O 2 + H 2 O - H 3 O + + C 2 H 3 O 2 - Eq: x x x = 1.3*10 -3 pH = -log(1.3*10 -3 ) = 2.89 b. 35-mL tot vol; amt neutralize= L*(0.100 mol/L) = mol base added = 0.01 L*(0.100 M) = mol HC 2 H 3 O 2 + OH - H 2 O + C 2 H 3 O 2 - I C E Convert to M using vol:.0015/.035 =.0429 M.001/.035 =.0286 M
c mL tot vol; NaOH added= L*(0.100 mol/L) = mol HC 2 H 3 O 2 + OH - H 2 O + C 2 H 3 O 2 - I C E Convert to M using vol:.00125/.0375 =.0333 M.00125/.0375 =.0333 M d. Add 25-mL at eq.pt, neutralization complete; mL tot vol amt C 2 H 3 O 2 - present = mol/0.050 L = 0.05 M C 2 H 3 O H 2 O - HC 2 H 3 O 2 + OH - Eq: 0.05-x x x K b = K w /K a = 5.6* K b = x 2 /0.05 x = 2.53*10 -6 pOH = 5.28 then pH = 8.72
e. Follow up. What happens beyond the equivalence pt? pH is determined from excess base present. - add 26.0 mL, what is the pH? tot vol mL (0.026 L)*(0.100 M) = mol – = mol OH - excess M = /.051 = 1.96*10 -3
Problem 25.0-mL of M HCl soln is titrated by M KOH. How many mL of base must be added to reach the end point. Want: mL KOH Data: 25.0-mL mol/L mol/L KOH HCl + KOH --- H 2 O + KCl 1 mol HCl = 1 mol KOH
Problem What is the pH at each point in the titration of mL of M HAc with M NaOH? a) before NaOH added b) after mL c) after mL d) after mL (these are volumes added to original 25 ml) a. Find initial [H 3 O + ]; use Ka (1.8*10 -5 ) HC 2 H 3 O 2 + H 2 O - H 3 O + + C 2 H 3 O 2 - Eq: x x x = 1.3*10 -3 pH = -log(1.3*10 -3 ) = 2.89 b. 35-mL tot vol; amt neutralize=0.025L*(0.100 mol/L) = mol base added = 0.01 L*(0.100 M) = mol HC 2 H 3 O 2 + OH - H 2 O + C 2 H 3 O 2 - I C E Convert to M using vol:.0015/.035 =.0429 M.001/.035 =.0286 M
c mL tot vol; NaOH added= L*(0.100 mol/L) = mol HC 2 H 3 O 2 + OH - H 2 O + C 2 H 3 O 2 - I C E Convert to M using vol:.00125/.0375 =.0333 M.00125/.0375 =.0333 M d. Add 25-mL at eq.pt, neutralization complete; mL tot vol amt C 2 H 3 O 2 - present = mol/0.050 L = 0.05 M C 2 H 3 O H 2 O - HC 2 H 3 O 2 + OH - Eq: 0.05-x x x K b = K w /K a = 5.6* K b = x 2 /0.05 x = 2.53*10 -6 pOH = 5.28 then pH = 8.72
SOLUBILITY EQUILIBRA Principals: examines quantitative aspects of solubility & ppt process K sp = solubility constant Cr 2 (SO 4 ) 3 (s) > 2 Cr +3 (aq) + 3 SO 4 -2 (aq) Q c + solid = K sp
K sp 1. temp dependant 2. used to calc solubility of cmpd Comparing K sp cmpds w / same total # ions formed, then, higher K sp is greater the solubility Write dissoc eqn, # mols each ion Write K sp expression Find Molarity - convert solubility to molar CALCULATIONS Find K sp Solubility of silver 15 o C is 8.3*10 -3 g / 100 mL Ag 2 Cr 2 O 7 (s) > 2 Ag +1 (aq) + Cr 2 O 7 -2 (aq)
[Cr ] = 2 [Ag + ] = 2* = Find Solubility K sp = [0.0384] 2 [0.0192] = 2.83*10 -5 What is the molar solubility of iron III hydroxide in water? K sp = 6.3* Write dissoc eqn, ion expression, ICE table
K sp = [Fe +3 ] [OH - ] 3 K sp = [x] [3x] 3 = 27x 4 K sp = 27x 4 Fe(OH) 3 (s) > Fe +3 (aq) + 3 OH -1 (aq) I C -x +x +3x E -x x 3x Ignore: solid
PPT FORMATION - - will or not form ??? Q sp = K sp soln satur, no Q sp < K sp soln unsat, no ppt Q sp > K sp ppt form till soln satur Will ppt form, if so, what is it? 0.20 L of M Na 3 PO 4 & 0.10 L of 0.20 M Ca(NO 3 ) 2 Ions present: Na +1 PO 4 -3 Ca +2 NO 3 -1 solubility rules: Ca 3 (PO 4 ) 2 (s) the ppt, insoluble Ca 3 (PO 4 ) 2 (s) 3 Ca +2 (aq) +2 PO 4 -3 (aq) K sp = [Ca +2 ] 3 [PO 4 -3 ] 2 K sp = 1.2*10 -29
Q sp = [Ca +2 ] 3 [PO 4 -3 ] 2 = (0.067) 3 (0.033) 2 = 3.28*10 -7 mols Ca +2 = 0.10 L * 0.20 M = mols [Ca +2 ] = mols / 0.30 L = M Q sp > K sp, so ppt will form Ca 3 (PO 4 ) 2 ppt till Q sp = 1.2* mols PO 4 -3 = 0.20 L * 0.05 M = 0.10 mols [PO 4 -3 ] = 0.10 mols / 0.30 L = M If Q sp = 6.7* What then??? Q sp < K sp, no ppt
COMPLEX IONS Central METAL ion covalent bonded to 2+ LIGANDS Metal ion acts as Lewis Acid, Ligand acts as Base Can separate metal from its ore, isolate & remove toxic metal, convert metal ion to diff form
ION GROUPS Separation of 2 competing ppting metal ions thru diff properties of solubility of cmpds Add ppting ion till Q sp of more soluble ion close to its K sp This allows max amt of less soluble cmpd ppt out, while none of the more soluble Mixture of many diff metal ions, use various techniques to sep ions into characteristic groups pg 737
Group 1 Insol Chlorides ppt w / HCl Ag + Hg 2 +2 Pb +2 Group 2 Acid-insol Sulfides ppt w / H 2 S Cu +2 Cd +2 As +3 Sb +3 Bi +3 Sn +2 Sn +4 Hg +2 Pb +2 Group 3 Base-insol S -2 & OH -1 ppt w / NH 4 + -NH 3 buffer Zn +2 Mn +2 Ni +2 Fe +2 Co +2 as S -2 Al +3 Cr +3 as OH - Group 4 Insol PO 4 -3 ppt w / (NH 4 ) 2 HPO 4, NaCO 3 Mg +2 Ca +2 Ba +2 Group 5 Alkali & NH 4 + Ions generally speaking, what’s left Use various techniques to ppt out specific ions from each group
Calculate the pH of a soln that is M pyridinium chloride (C 5 H 5 NHCl) and M pyridine (C 5 H 5 N). WB C 5 H 5 N & C 5 H 5 NHCl contain common ion effect: C 5 H 5 NH + I C -x +x +x E x x x C 5 H 5 N(aq) ) + H 2 O(l) C 5 H 5 NH + (aq) + OH - (aq) assume 5% rule for WA
x = [OH - ] = 1.02*10 -9 pOH = -Log(1.02*10 -9 ) = 8.99 pH = 14 – 8.99 = 5.01 Kb = 1.7*10 -9
The addition of bromide ion will decrease the water solubility of which of the following salts? a.BaSO 4 b. Li 2 CO 3 c. PbS d. AgBr AgBr Which pair of compounds will form a buffer solution when dissolved in water in equimolar amounts? a. HCl and KCl b. HNO 3 and NaNO 3 c. HCl and NH 4 Cl d. NH 3 and NH 4 Cl NH 3 and NH 4 Cl
The K a of HCN is 4.9 x What is the pH of a buffer solution that is M in both HCN and KCN? a. 4.7 b. 7.0 c. 9.3 d same concentrations, -log(4.9* ) The K a of HCN is 4.9 x What is the pH of a buffer solution that is M in HCN and M in KCN? a. 7.0 b. 9.0 c. 9.3 d pH = pKa + log[KCN]/[HCN]
The K a of HCN is 4.9 x What is the pH of a buffer solution that is 1.00 M in HCN and M in KCN? a. 7.0 b. 8.3 c. 9.0 d pH = pKa + log[KCN]/[HCN]
In titrating a weak base with a strong acid, the best indicator to use would be: a.methyl red (changes color at pH = 5). b.bromothymol blue (changes at pH = 7). c.phenolphthalein (changes at pH = 9). d.none of the above. methyl red (changes color at pH = 5) Titrating a weak acid with a strong base, best indicator to use would be: a.methyl red (changes color at pH = 5). b.bromothymol blue (changes at pH = 7). c.phenolphthalein (changes at pH = 9). d.none of the above. phenolphthalein (changes at pH = 9)
The K sp of BaCO 3 is 5.0 x What is the concentration of barium ion in a saturated aqueous solution of BaCO 3 ? a. 7.1 x M b. 2.5 x M c. 5.0 x M d. 1.0 x M 7.1 x M 5.0*10 -9 = x*x 5.0*10 -9 = x 2 The K sp of BaF 2 is 1.7 x What is the concentration of barium ion in a saturated aqueous solution of BaF 2 ? a. 1.7 x M b. 3.4 x M c. 7.5 x M d. 1.5 x M 7.5 x M K sp = [Ba +2 ][F - ] 2 = (x)*(2x) 2 1.7*10 -6 = 4x 3
The K sp of BaF 2 is 1.7 x What is the concentration of fluoride ion in a saturated aqueous solution of BaF 2 ? a. 1.7 x M b. 5.7 x M c. 7.6 x M d. 1.5 x M 1.5 x M BaF 2 -- Ba F - [F - ] =2x = 2(7.5*10 -3 )
Which of the following substances will be more soluble in acidic solution than in basic solution: (a)Ni(OH) 2 (s), (b) CaCO 3 (s), (c) BaF 2 (s), (d) AgCl(s)? So, which is more soluble at low pH than high pH Ni(OH) 2 more soluble in acidic, basicity of OH - CaCO 3 dissolves in acidic, as CO 3 - basic anion BaF 2 dissolves, as F - basic anion (d) The solubility of AgCl is unaffected by changes in pH because Cl – is the anion of a strong acid and therefore has negligible basicity.
Addition of _____ will increase the solubility of MgCO 3. MgCO 3 (s) Mg 2+ (aq) + CO 3 2– (aq) MgCl 2 Na 2 CO 3 NaOH HCl KHCO 3 HCl
Predict the order of precipitation of Ba 2+, Pb 2+, Ca 2+ with the addition of NaF. Ca 2+ then Ba 2+ then Pb 2+ Pb 2+ then Ba 2+ then Ca 2+ Pb 2+ then Ca 2+ then Ba 2+ Ca 2+ then Pb 2+ then Ba 2+ Ba 2+ then Pb 2+ then Ca 2+ K sp BaF x 10 –6 PbF x 10 –8 CaF x 10 –11 Ca 2+ then Pb 2+ then Ba 2+
Predict the order of precipitation of Cl –, CO 3 2–, Br – upon the addition of AgNO 3. Br – then CO 3 2– then Cl – Br – then Cl – then CO 3 2– Cl – then CO 3 2– then Br – Cl – then Br – then CO 3 2– CO 3 2– then Cl – then Br – K sp AgCl1.8 x 10 –10 Ag 2 CO x 10 –12 AgBr5.0 x 10 –13 Br – then Cl – then CO 3 2–
A solution contains 1.0 × M Ag + and 2.0 ×10 -2 M Pb 2+. When Cl – is added to the solution, both AgCl (K sp = 1.8× ) and PbCl 2 (K sp = 1.7×10 -5 ) precipitate from the solution. What concentration of Cl – is necessary to begin the precipitation of each salt? Which salt precipitates first? We are given K sp values for the two possible precipitates. Using these and the metal ion concentrations, we can calculate what concentration of Cl – ion would be necessary to begin precipitation of each. The salt requiring the lower Cl – ion concentration will precipitate first.