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Chapter 7 Electrochemistry

Chapter 7 Electrochemistry. Strong electrolyte. Real electrolyte. Weak el ectrolyte. Potential electrolyte. 7.1 Thermodynamic Properties of Electrolyte Solutions. 7.1.1 Electrolyte. NaNO 3 z + = 1 | z - |= 1 1-1 ; BaSO 4 z + = 2 | z - |= 2 2-2 ;

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Chapter 7 Electrochemistry

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  1. Chapter 7 Electrochemistry Strong electrolyte Real electrolyte Weak el ectrolyte Potential electrolyte 7.1 Thermodynamic Properties of Electrolyte Solutions 7.1.1 Electrolyte NaNO3z+=1 |z-|=1 1-1; BaSO4z+=2 |z-|=2 2-2; Na2SO4 z+=1 |z-|=2 1-2; Ba(NO3)2 z+=2 |z-|=1 2-1。

  2. 7.1.2 Chemical Potential of Electrolyte and Ions B = ++ + 

  3. dT=0, dp=0, dnA=0 B = ++ + 

  4. ideal solution real solution 7.1.3 Activity and Activity Coefficient

  5. 7.1.4 Mean Activity of Ions and Mean Activity Coefficients

  6. 7.1.5 The Debye - Hückel Limiting Law Ionic atmosphere

  7. H2O b<0.01~0.001mol·kg-1 I — Ionic Strength

  8. 7.1.6 Ionic Strength I<0.01mol·kg-1

  9. 7.2 Conductive Properties of Electrolyte Solutions 7.2.1 Conductance G Conductance;unit Simens S,1S=1Ω-1。  Resistivity ; Ω·m.   Conductivity ; S·m-1.  =K(l/A)G K Cell constant

  10. Λm(K2SO4)= 0.02485 S·m2·mol-1 Λm( K2SO4)= 0.01243 S · m2 · mol-1 7.2.2 Molar Conductance Λm unit S · m2 · mol-1。

  11. 400 300 200 100 HCl 80 H2SO4 m/(Scm2 mol-1) 60 k/(Sm-1) KOH NaOH KCl 40 AgNO3 20 MgSO4 CH3COOH CH3COOH 0 0.5 1.0 1.5 0 5 10 14 c/(moldm-3) m  c   c cB=0 molar conductivity of infinite dilution 7.2.3 Concentration dependence of  andΛm

  12. At equilibrium 7.2.4 Independent Migration of Ion 7.2.5. Electrolytic Equilibrium of Weak Electrolytes

  13. HOAc H+ + OAc- au=ubu/b=(1-α)u b/b 

  14. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + Metal Metal 7.3 Electrochemical system

  15. Metal 1 Metal 2 + + + + + + + + + + Contact potential

  16. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + Liquid-junction potential (diffusion potential)

  17. 7.4 Equilibrium electrochemistry 7.4.1 Reversible cell (1) Electrode reactions and cell reaction are reversible (2) I  0 (equilibrium)

  18. 7.4.2 The Cell Potentials of Reversible Cell

  19. ---Standard Cell Potentials 7.4.3 The Nernst Equation

  20. 7.4.4 Standard Electrode Potential Standard Hydrogen Electrode ---SHE H+ [a(H+) =1 ] | H2 (p=100kPa) | Pt E=0 SHE  electrode in question (reduction)

  21. Table 11-1 25℃时某些电极的标准电极电势 (p=100kPa)

  22. For example Cl- -(a)|Cl2|Pt: Oxidation state + 2e-  Reduction state EMF = E (R,Reduction)- E (L,Reduction)

  23. Temperature coefficient of cell 7.5 Application of EMF Measurements 7.5.1 Determination of thermodynamics quantities ΔrGm,ΔrSm andΔrHm ΔrGm= - zFEMF

  24. 7.5.2 Determination of γ±

  25. -OH HO- Q QH2 7.5.3 Determination of pH Pt|H2(p )|solution(pH=x) |KCl (a)|Hg2Cl2|Hg QQH2 H+|Q,QH2|Pt Q[a(Q)]+2H+[a(H+)]+2e-QH2[a(QH2)] a(Q)≈a(QH2) 25℃,E=(0.6997-0.05916pH) V

  26. 7.5.4 Determination ofK and Ksp 7.5.5 Determination of reaction direction ΔrGm=-ZFEMF< 0

  27. a c M  c a Ea M Ec M+ + e- M M++e Cathode process υc; anode process υa; 7.6 kinetics of electrochemical system 7.6.1 Rate of electrochemical reaction

  28. v - Rate of electrochemical reaction molm-2s-1 Current density j j=ZFυ j0:exchange current density

  29. { } { }   { c,e} { a} {a} {c} { c} { a ,e}   {e} { } { e} { }   { c,e} { a} {c} {a} { c} { a,e}   {j} {j} polarization curve (a) electrolytic cell (b)chemical electric source 7.6.2 Polarization and Overpotential Overpotential: ηa —anode overpotential ηc—anode overpotential

  30. Ag+ c0 Ag c'  M+ + e- M Diffusion layer (1). Diffusion overpotential (2). Electrochemical overpotential

  31. + — Power supply I anode(+) cathode(-) Pt Pt O2 H2 H2O H2O 7.6.3 Electrolytic cell (-)Pt| H2|OH-(H2O)| O2(p) |Pt(+)

  32. _ 外电源 + 电阻 I R V 伏特计 A 电流计 Pt  V  Vd KOH KOH Decomposition voltage Theory decomposition voltage Real decomposition voltage Δ (real)=Δ (theory) + (ηa+|ηc|) + IR

  33. Negative electrode:Zn + 2NH4Cl  Zn(NH3)2Cl2 + 2H++ 2e- positive electrode :2MnO2 + 2H+ + 2e- 2MnOOH Cell reaction:Zn + 2MnO2 + 2NH4Cl Zn(NH3)2Cl2 + 2MnOOH 7.7 Power production and corrosion 7.7.1 Dry Cell Zn|NH4Cl|MnO2|C

  34. Negative electrode :Pb + H2SO4  PbSO4 + 2H+ + 2e- positive electrode : PbO2 + H2SO4 + 2H+ + 2e- PbSO4 + 2H2O Cell reaction:PbO2 + Pb + 2H2SO4 2PbSO4 + 2H2O 11.7.2 Storage Cell Pb|H2SO4(ρ=1.28gcm-3)|PbO2

  35. Negative electrode: 2Zn + 4OH- 2Zn(OH)2 + 4e- positive electrode : Ag2O2 + 2H2O+ 4e- 2Ag+ 4OH- Cell reaction:2Zn+ Ag2O2 + 2H2O 2Ag+ 2Zn(OH)2 11.7.3.Silver-zinc Cell Zn|KOH(ωB=0.40)|Ag2O|Ag

  36. 7.7.4. Fuel cell M|H2(g)|KOH|O2(g)|M

  37. Efficiency of Chemical Electric Source

  38. 7.7.5 Electrochemical corrosion

  39. M+ M+ 2H+ 2H+ H2 H2 2e 2e M M2 M1 Anode process: FeFe2++2e- Cathode process: (i)2H++2e-H2↑ (ii)O2+4H++4e-2H2O (i) cell reaction:Fe+2H+Fe2++H2 (ii) cell reaction:Fe+(1/2)O2+2H+Fe2++H2O

  40. { c,e} S {)} { a,e} I

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