Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models...
-
Upload
cornelius-zachary -
Category
Documents
-
view
218 -
download
1
Transcript of Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models...
![Page 1: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/1.jpg)
Zumdahl’sZumdahl’sChapter 14Chapter 14Zumdahl’sZumdahl’sChapter 14Chapter 14
AcidsAcids
BasesBasesAcidsAcids
BasesBases
![Page 2: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/2.jpg)
Chapter ContentsChapter ContentsChapter ContentsChapter Contents
Acid-Base ModelsAcid-Base Models Acidity and KAcidity and Kaa
pH, pOH, and pKpH, pOH, and pKaa
Calculating pHCalculating pH Dominant SourcesDominant Sources
Polyprotic AcidsPolyprotic Acids % dissociation% dissociation
Bases and KBases and Kbb
Conjugate Acids Conjugate Acids and Basesand Bases
Structure and Structure and StrengthStrength
OxoacidsOxoacids Lewis AcidsLewis Acids Acid-Base Solution Acid-Base Solution
Al Gore RhythmsAl Gore Rhythms
![Page 3: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/3.jpg)
Acid-Base ModelsAcid-Base ModelsAcid-Base ModelsAcid-Base Models
DefinitioDefinition of Acidn of Acid
Example Example of Acidof Acid
DefinitioDefinition of n of BaseBase
Example Example of Baseof Base
SvanteSvante
ArrheniuArrheniuss
Donates Donates HH++ HClHCl Donates Donates
OHOH–– NaOHNaOH
BrBrøsted-østed-LowryLowry
Donates Donates HH++ HClHCl Accepts Accepts
HH++
NHNH33 or or HH22OO
G.N.G.N.
LewisLewisAccepts Accepts electronelectron
BFBF33Donates Donates electronelectron
:: NH NH33
![Page 4: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/4.jpg)
CausticCaustic Characteristics CharacteristicsCausticCaustic Characteristics Characteristics
Greek: Greek: kaustikoskaustikos kaieinkaiein “to burn” “to burn” Acids & bases corrode nearly Acids & bases corrode nearly
everythingeverything HA(HA(aqaq) + H) + H22O(O(ll) ) H H33OO++((aqaq) + A) + A––((aqaq))
HA “acid” and AHA “acid” and A–– “conjugate base”“conjugate base” HH22O “base” and HO “base” and H33OO++ “conjugate acid”“conjugate acid”
HH33OO++ “hydronium ion”“hydronium ion” no free protons!no free protons!
KKaa = [H = [H++] [A] [A––] / [HA] ] / [HA] “acid dissociation contant”“acid dissociation contant”
![Page 5: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/5.jpg)
Acidity and KAcidity and KaaAcidity and KAcidity and Kaa
Strong acid: KStrong acid: Kaa meansmeans [HA] [HA]eqeq = 0 = 0
Weak acid: KWeak acid: Kaa 0 0 oror [HA] [HA]eqeq [HA] [HA]00
AA––((aqaq) + H) + H33OO++((aqaq) ) HA( HA(aqaq) + H) + H22O(O(ll)) K=KK=Kaa
––11 or weak acid is associated with a or weak acid is associated with a strong conjugate base and vice versa.strong conjugate base and vice versa.
AcidsAcids HHSOSO44–– HHCC22HH33OO22 HHCNCN
KKaa 1.21.21010––22 1.81.81010––55 6.26.21010––1010
![Page 6: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/6.jpg)
pH, pOH, and pKpH, pOH, and pKaapH, pOH, and pKpH, pOH, and pKaa
pX pX –– log log1010(X)(X) Reduces KReduces Kww = 1.01 = 1.01221010––1414 to pK to pKww = 13.995 = 13.995
to a manageable entity for comparisonto a manageable entity for comparison Actually pKActually pKww = 14 is usually memorized. = 14 is usually memorized.
2 H2 H22O(O(ll) ) H H33OO++((aqaq) + OH) + OH––((aqaq) K = K) K = Kww
pH+pOH=pKpH+pOH=pKww because K because Kww = [H = [H++][OH][OH––]] AcidAcid (pH<7), Neutral (pH=7), (pH<7), Neutral (pH=7), BaseBase (pH>7) (pH>7) E.g., pH(0.1 E.g., pH(0.1 MM acetic acid) = acetic acid) = 2.872.87
![Page 7: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/7.jpg)
Calculating pHCalculating pHCalculating pHCalculating pH
Strong acidsStrong acids [H[H++]]eqeq = [HA] = [HA]00
pH = p[HA]pH = p[HA]00
Strong basesStrong bases [OH[OH––]]eqeq = [BOH] = [BOH]00
pOH = p[BOH]pOH = p[BOH]00
pH = 14 – pOHpH = 14 – pOH Don’t be fooled Don’t be fooled
by [HA]by [HA]00 << 10 10––77
Weak AcidsWeak Acids KKaa = [H = [H++][A][A––] / [HA]] / [HA] KKaa = x = x22 / ( [HA] / ( [HA]00 – x) – x) KKaa x x22 / [HA] / [HA]00
x x ( K ( Kaa [HA] [HA]00 ) )½½
pH = – logpH = – log1010(x)(x) Weak BasesWeak Bases
x x ( K ( Kbb [MOH] [MOH]00 ) )½½
pH = 14 - pxpH = 14 - px
![Page 8: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/8.jpg)
Dominant SourcesDominant SourcesDominant SourcesDominant Sources
If more than one HIf more than one H++ source source (multiple (multiple
acids acids oror a polyprotic acid), a polyprotic acid), pK pKaa will usually will usually differ by a few units, and the differ by a few units, and the largestlargest will will determinedetermine [H [H++]]eqeq. . E.g., 0.01E.g., 0.01MM H H33POPO44
pKpKaa: 2.12, 7.21, and 12.32, respectively: 2.12, 7.21, and 12.32, respectively Use KUse Kaa for 1 for 1stst H H only:only: pH = 2.24 pH = 2.24 (quadratic formula)(quadratic formula)
DeterminesDetermines H H33POPO44, H, H22POPO44––, , andand H H++
Use other two pKUse other two pKaa to find HPO to find HPO4422–– and PO and PO44
33––
![Page 9: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/9.jpg)
% Dissociation% Dissociation% Dissociation% Dissociation
Weak electrolyte present in molecular Weak electrolyte present in molecular form mostly with few ions & will have form mostly with few ions & will have a small % dissociation a small % dissociation unlessunless diluted. diluted.
100% 100% [ionic form] / [initial amount] [ionic form] / [initial amount] E.g., 0.1 E.g., 0.1 MM acetic acid = [initial amount] acetic acid = [initial amount]
[acetate ion] [acetate ion] (0.10 K (0.10 Kaa))½½ = 0.0013 = 0.0013 MM % dissoc. % dissoc. 100% 100% (K (Kaa/0.1)/0.1)½½ = 1.3% = 1.3%
0.01 M gives 4.2% shows 0.01 M gives 4.2% shows moremore ionization ionization upon dilution upon dilution (but pushes the “5% approx.”)(but pushes the “5% approx.”)
![Page 10: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/10.jpg)
Bases and KBases and KbbBases and KBases and Kbb
Strong base: [OHStrong base: [OH––]]eqeq = [MOH] = [MOH]00 where M=metal and pH = 14 - pOHwhere M=metal and pH = 14 - pOH
Weak bases often Weak bases often aminesamines, , ::NRNR33
where R = H and/or organic groupswhere R = H and/or organic groups Amine steals HAmine steals H++ from H from H22O to leave OHO to leave OH––
KKbb = [NR = [NR33HH++] [OH] [OH––] / [] / [::NRNR33]]
For NHFor NH33 ((ammoniaammonia, , notnot an an amineamine),), K Kbb = 1.8 = 1.81010––55
Same pH rules & approximations apply.Same pH rules & approximations apply.
![Page 11: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/11.jpg)
Conjugate Acids and Conjugate Acids and BasesBasesConjugate Acids and Conjugate Acids and BasesBases
““Salt of a weak (Salt of a weak (acidacid/base) is itself a /base) is itself a weak (weak (basebase/acid).”/acid).” Example of a weak base, NHExample of a weak base, NH33
NHNH44++ + OH + OH–– NH NH33 + H + H22O K = KO K = Kbb
––11
HH22O O H H++ + OH + OH–– K = K K = Kww ((addadd eqns) eqns)
NHNH44++ NH NH33 + H + H++ K Kconjugateconjugate = K = Kww / K / Kbb
KKacidacid(NH(NH44++) = 10) = 10––1414/1.8/1.81010––55 = 5.5 = 5.51010––1010
Weaker parent yields Weaker parent yields strongerstronger conjugate!conjugate!
![Page 12: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/12.jpg)
Conjugate pH CalculationsConjugate pH CalculationsConjugate pH CalculationsConjugate pH Calculations
Salts of Salts of strongstrong parents are parents are neutral;neutral; those of very weak bases, very acidic:those of very weak bases, very acidic: Fe(HFe(H22O)O)66
3+3+ Fe(H Fe(H22O)O)55OHOH2+2+ + H + H++
pKpKa1a1 = 2.2 = 2.2 oror K Ka1a1 = 6.3 = 6.31010–3–3 (pK (pKbb = 11.8) = 11.8)
pH of 3 pH of 3 MM Fe(NO Fe(NO33))33 ? ? (HNO(HNO33 strong; ignore!) strong; ignore!)
KKa1a1 = [FeOH = [FeOH2+2+] [H] [H++] / [Fe] / [Fe3+3+] = x] = x22 / (3-x) / (3-x)
x x [3K [3Ka1a1]]½½ = 0.14 = 0.14 (5% OK)(5% OK) pH = 0.86 pH = 0.86 pKpKa2a2 = 3.5, pK = 3.5, pKa3a3 = 6, pK = 6, pKa4a4 = 10 = 10
![Page 13: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/13.jpg)
NON-Dominant SituationsNON-Dominant SituationsNON-Dominant SituationsNON-Dominant Situations
In that Fe complex, pKIn that Fe complex, pKa1a1 and pK and pKa2a2 are are very close (2.2 and 3.5), so the very close (2.2 and 3.5), so the second conjugate may be important:second conjugate may be important: Fe(HFe(H22O)O)55OHOH2+2+ Fe(H Fe(H22O)O)44(OH)(OH)22
++ + H + H++
This will certainly be the case at This will certainly be the case at lower formal iron concentrations, F, lower formal iron concentrations, F, since % dissociation is greater there. since % dissociation is greater there. Try F=0.01Try F=0.01
![Page 14: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/14.jpg)
Simplifing ApproximationsSimplifing ApproximationsSimplifing ApproximationsSimplifing Approximations
Even at F=0.01, we can safely Even at F=0.01, we can safely ignore pKignore pKa3a3, pK, pKa4a4, and pK, and pKww, since , since theythey are dominated by pKare dominated by pKa1a1 and pK and pKa2a2..
Abbreviate those equilibria asAbbreviate those equilibria as AA3+3+ B B2+2+ + H + H++ KK11 = B H / A = B H / A
BB2+2+ C C++ + H + H++ KK22 = C H / A = C H / A
But those are 2 eqns in 4 unknowns!But those are 2 eqns in 4 unknowns!
![Page 15: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/15.jpg)
2 Additional Conditions!2 Additional Conditions!2 Additional Conditions!2 Additional Conditions!
Conservation of iron requires thatConservation of iron requires that F = A + B + CF = A + B + C
Conservation of charge must include Conservation of charge must include a spectator anion for Aa spectator anion for A3+3+ such as 3 Cl such as 3 Cl––
3 A3 A3+3+ + 2 B + 2 B2+2+ + C + C++ + H + H++ = 3 F = 3 F (conc. Cl(conc. Cl––))
Notice that higher charges get scaled Notice that higher charges get scaled byby their charge for proper balance. their charge for proper balance.
![Page 16: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/16.jpg)
Solve 4 Solve 4 NonlinearNonlinear EquationsEquationsSolve 4 Solve 4 NonlinearNonlinear EquationsEquations
Original equations:Original equations: F = A + B + CF = A + B + C 3F = 3A + 2B + C + H3F = 3A + 2B + C + H B H = KB H = K11 A A
C H = KC H = K22 B B
Remove A by substituting from 1Remove A by substituting from 1stst eqneqn A = F – B – C A = F – B – C
![Page 17: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/17.jpg)
Solve 3 Nonlinear Solve 3 Nonlinear EquationsEquationsSolve 3 Nonlinear Solve 3 Nonlinear EquationsEquations
Remaining after substitutionRemaining after substitution 3F = 3F – 3B – 3C + 2B + C + H3F = 3F – 3B – 3C + 2B + C + H B H = KB H = K11 ( F – B – C ) ( F – B – C )
C H = KC H = K22 B B
SimplifySimplify H = B + 2CH = B + 2C B H = KB H = K11 F – K F – K11 B – K B – K11 C C
C H = KC H = K22 B B substitutesubstitute C = K C = K22 B / B / HH
![Page 18: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/18.jpg)
Solve 2 Nonlinear Solve 2 Nonlinear EquationsEquations
H = B + 2 KH = B + 2 K22 B / H B / H
B H = KB H = K11 F – K F – K11 B – K B – K11 K K22 B / H B / H
SimplifySimplify HH22 = B H + 2 K = B H + 2 K22 B B B = H B = H22 / (H + 2K / (H + 2K22))
B HB H22 = K = K11 F H – K F H – K11 B H – K B H – K11 K K22 B B
Substitute for BSubstitute for B HH33 + K + K11 H H22 – K – K11 (F – K (F – K22)H – 2 K)H – 2 K11 K K22 F = 0 F = 0
Only H remains as an unknown!Only H remains as an unknown!
![Page 19: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/19.jpg)
Solve 1 Cubic EquationSolve 1 Cubic EquationSolve 1 Cubic EquationSolve 1 Cubic Equation
Use the Use the dominantdominant solution as first guess solution as first guess in an iteration to the in an iteration to the non-dominantnon-dominant one. one. AA3+3+ B B2+2+ + H + H++ KK11 = B H / A = B H / A
KK11 = x = x22 / (F – x) / (F – x)
xx22 + K + K11 x – F K x – F K11 = 0 = 0
x = ( – Kx = ( – K11 + [K + [K1122 + 4F K + 4F K11]]½½) / 2) / 2
x = 5.3x = 5.31010–3–3 H H F = 0.01, KF = 0.01, K11 = 6 = 61010–3–3, and K, and K22 = 3 = 31010– 4– 4
![Page 20: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/20.jpg)
HH33 + 6 + 61010–3–3 H H22 – 5.8 – 5.81010–3–3 H – 3.6 H – 3.61010–8 –8 = 0= 0
HHoutout = (3.6 = (3.6 1010–8 –8 + + 5.85.81010–3–3 H Hinin – – 661010–3–3 HHinin
22))1/31/3
HHinin (the guess) (the guess) HHoutout (the refinement) (the refinement)
5.35.31010–3–3 5.65.61010–3–3
5.65.61010–3–3 5.585.581010–3–3
5.585.581010–3–3 5.585.581010–3–3
[H[H++] = 5.58] = 5.581010– 3– 3 MM and by B = H and by B = H22 / (H + / (H + 2K2K22),),
[B[B2+2+] = 5.04] = 5.041010– 3– 3 MM and by C = K and by C = K22 B / H, B / H,
[C[C++] = 2.7 ] = 2.7 1010– 3– 3 MM which makes [A which makes [A3+3+] = ] = 4.74.71010– 3– 3 MM
![Page 21: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/21.jpg)
More Conjugate More Conjugate CalculationsCalculationsMore Conjugate More Conjugate CalculationsCalculations
HCOHCO33–– H H++ + CO + CO33
22–– pK pKa2a2 = 10.25 = 10.25 pH of 0.10 pH of 0.10 MM Na Na22COCO33 ? ? (NaOH strong; ignore)(NaOH strong; ignore)
COCO3322–– + H + H22O O HCO HCO33
–– + OH + OH–– K = K K = Kww/K/Ka2a2
K = [HCOK = [HCO33––] [OH] [OH––] / [CO] / [CO33
2–2–] = x] = x22 / (0.10-x) / (0.10-x) x x [0.10 [0.10 1.8 1.81010–4–4 ] ]½½ = 4.2 = 4.21010–3–3 (5% OK)(5% OK)
pOH = 2.37 pOH = 2.37 pH = 14.00 – 2.37 = 11.63 pH = 14.00 – 2.37 = 11.63 Sodium carbonate is in laundry soap.Sodium carbonate is in laundry soap.
![Page 22: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/22.jpg)
Acid Structure and Acid Structure and StrengthStrengthAcid Structure and Acid Structure and StrengthStrength
Higher polarity liberates protons.Higher polarity liberates protons. While all hydrogen halides are strong While all hydrogen halides are strong
acids (save HF), acidity lessens with acids (save HF), acidity lessens with halide size.halide size.
Even non-adjacent electronegativity Even non-adjacent electronegativity drains edrains e–– density, liberating protons. density, liberating protons. HClO is weak but HClOHClO is weak but HClO44 is strong. is strong.
(the H is attached to only 1 of the oxygens)(the H is attached to only 1 of the oxygens)
ClCl33CCOCCO22H is much stronger than CHH is much stronger than CH33COCO22HH
![Page 23: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/23.jpg)
OxoacidsOxoacidsOxoacidsOxoacids
German: OGerman: O22 = = sauerstoffsauerstoff or the or the stuffstuff that makes that makes soursour oxoacids, oxoacids, ––XX––OO––HH
True when X is a fairly electronegative True when X is a fairly electronegative non-metal non-metal (halogen, N, P, S)(halogen, N, P, S) or a metal in a or a metal in a high oxidation state high oxidation state (e.g., H(e.g., H22CrOCrO44))
True as nonadjacent electronegativity True as nonadjacent electronegativity aids polarity (e.g., CHaids polarity (e.g., CH33COCO22H)H)
![Page 24: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/24.jpg)
Oxygen-containing BasesOxygen-containing BasesOxygen-containing BasesOxygen-containing Bases
M – O – HM – O – H Metals in lower oxidation states tend Metals in lower oxidation states tend
to give up the OHto give up the OH–– and not the H and not the H++
Sr(OH)Sr(OH)22 Sr Sr2+2+ + 2 OH + 2 OH––
Al(OH)Al(OH)33 is basic; Al is basic; Al3+3+ is acidic. is acidic.
Water is amphoteric too, acting as a Water is amphoteric too, acting as a base by becoming Hbase by becoming H33OO++, for example., for example.
– BrBrønsted definition: water ønsted definition: water acceptsaccepts the proton. the proton.
![Page 25: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/25.jpg)
Lewis Acids and BasesLewis Acids and BasesLewis Acids and BasesLewis Acids and Bases
Water is both acid & base by Lewis too.Water is both acid & base by Lewis too. Base via HBase via H22OO:: + H + H++ H H33OO++
donates lone pair edonates lone pair e–– to proton to proton
Acid via HAcid via H22O + SO + S2–2– OH OH–– + HS + HS–– accepts the one of sulfide’s electronsaccepts the one of sulfide’s electrons
Lewis’ is the most general definitionLewis’ is the most general definition E.g., CuE.g., Cu2+2+ + 6 + 6 ::NHNH33 Cu(NH Cu(NH33))66
2+2+ Cu’s the acid and Cu’s the acid and ::NHNH33’s the base.’s the base.
![Page 26: Zumdahl’s Chapter 14 AcidsBasesAcidsBases Chapter Contents Acid-Base Models Acid-Base Models Acidity and K a Acidity and K a pH, pOH, and pK a pH, pOH,](https://reader036.fdocuments.us/reader036/viewer/2022062417/551c490c5503467b488b4eb6/html5/thumbnails/26.jpg)
Acid-Base AlgorithmAcid-Base AlgorithmAcid-Base AlgorithmAcid-Base Algorithm
Know the Know the significant species significant species for the conditions.for the conditions.
Ignore the rest.Ignore the rest. For quantitative For quantitative
reactions, keep reactions, keep only the products.only the products.
Find acids & Find acids & bases.bases.
Solve controlling KSolve controlling K Write K expression.Write K expression. Set initial conditions Set initial conditions
for smallest change.for smallest change. Define all species in Define all species in
terms of x (change).terms of x (change). Find x solving K Find x solving K
exp.exp. Check any approx.Check any approx. Find pH & [species]Find pH & [species]