Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 19 Electrochemistry Mr. Watson HST. Mr. Watson Redox Reactions Oxidation loss of electrons Reduction gain of electrons oxidizing agent substance.

Published byAbigayle McCoy Modified over 9 years ago

Similar presentations

Presentation on theme: "Chapter 19 Electrochemistry Mr. Watson HST. Mr. Watson Redox Reactions Oxidation loss of electrons Reduction gain of electrons oxidizing agent substance."— Presentation transcript:

1 Chapter 19 Electrochemistry Mr. Watson HST

2 Mr. Watson Redox Reactions Oxidation loss of electrons Reduction gain of electrons oxidizing agent substance that cause oxidation by being reduced reducing agent substance that cause oxidation by being oxidized

3 HST Mr. Watson Electrochemistry In the broadest sense, electrochemistry is the study of chemical reactions that produce electrical effects and of the chemical phenomena that are caused by the action of currents or voltages.

4 HST Mr. Watson Oxidation-Reduction Reactions

5 HST Mr. Watson Voltaic Cells harnessed chemical reaction which produces an electric current

6 HST Mr. Watson Voltaic Cells Cells and Cell Reactions Daniel's Cell Zn (s) + Cu +2 (aq) ---> Zn +2 (aq) + Cu (s) oxidation half reaction anodeZn (s) ---> Zn +2 (aq) + 2 e - reduction half reaction cathodeCu +2 (aq) + 2 e - ---> Cu (s)

7 HST Mr. Watson Voltaic Cells copper electrode dipped into a solution of copper(II) sulfate zinc electrode dipped into a solution of zinc sulfate

8 HST Mr. Watson Voltaic Cells

9 HST Mr. Watson Hydrogen Electrode consists of a platinum electrode covered with a fine powder of platinum around which H 2(g) is bubbled. Its potential is defined as zero volts. Hydrogen Half-Cell H 2(g) = 2 H + (aq) + 2 e - reversible reaction

10 HST Mr. Watson

11 HST Mr. Watson

12 HST Mr. Watson Standard Reduction Potentials the potential under standard conditions (25 o C with all ions at 1 M concentrations and all gases at 1 atm pressure) of a half- reaction in which reduction is occurring

13 HST Mr. Watson Some Standard Reduction Potentials Table 18-1, pg 837 Li + + e - ---> Li-3.045 v Zn +2 + 2 e - ---> Zn-0.763v Fe +2 + 2 e - ---> Fe-0.44v 2 H + (aq) + 2 e - ---> H 2(g) 0.00v Cu +2 + 2 e - ---> Cu+0.337v O 2(g) + 4 H + (aq) + 4 e - ---> 2 H 2 O (l) +1.229v F 2 + 2e - ---> 2 F - +2.87v

14 HST Mr. Watson If the reduction of mercury (I) in a voltaic cell is desired, the half reaction is: Which of the following reactions could be used as the anode (oxidation)? A, B

15 HST Mr. Watson Cell Potential the potential difference, in volts, between the electrodes of an electrochemical cell Direction of Oxidation-Reduction Reactions positive value indicates a spontaneous reaction

16 HST Mr. Watson Standard Cell Potential the potential difference, in volts, between the electrodes of an electrochemical cell when the all concentrations of all solutes is 1 molar, all the partial pressures of any gases are 1 atm, and the temperature at 25 o C

17 HST Mr. Watson Cell Diagram the shorthand representation of an electrochemical cell showing the two half- cells connected by a salt bridge or porous barrier, such as: Zn (s) /ZnSO 4(aq) //CuSO 4(aq) /Cu (s) anode cathode

18 HST Mr. Watson Metal Displacement Reactions solid of more reactive metals will displace ions of a less reactive metal from solution relative reactivity based on potentials of half reactions metals with very different potentials react most vigorously

19 HST Mr. Watson Ag+ + e- --->Ag E°= 0.80 V Cu 2+ + 2e- ---> Cu E°= 0.34 V Will Ag react with Cu 2+ ? yes, no Will Cu react with Ag+? yes, no

20 HST Mr. Watson Gibbs Free Energy and Cell Potential  G = - nFE wheren => number of electrons changed F => Faraday’s constant E => cell potential

21 HST Mr. Watson Applications of Electrochemical Cells Batteries – device that converts chemical energy into electricity Primary Cells – non-reversible electrochemical cell – non-rechargeable cell Secondary Cells – reversible electrochemical cell – rechargeable cell

22 HST Mr. Watson Applications of Electrochemical Cells Batteries Primary Cells "dry" cell & alkaline cell 1.5 v/cell mercury cell 1.34 v/cell fuel cell 1.23v/cell Secondary Cells lead-acid (automobile battery) 2 v/cell NiCad 1.25 v/cell

23 HST Mr. Watson “Dry” Cell

24 HST Mr. Watson “Dry” Cell

25 HST Mr. Watson “Flash Light” Batteries "Dry" Cell Zn (s) + 2 MnO 2(s) + 2 NH 4 + -----> Zn +2 (aq) + 2 MnO(OH) (s) + 2 NH 3 Alkaline Cell Zn (s) + 2 MnO 2(s) ---> ZnO (s) + Mn 2 O 3 (s)

26 HST Mr. Watson “New” Super Iron Battery Mfe(VI)O 4 + 3/2 Zn 1/2 Fe(III) 2 O 3 + 1/2 ZnO + MZnO 2 (M = K 2 or Ba) Environmentally friendlier than MnO 2 containing batteries.

27 HST Mr. Watson Mercury Cell

28 HST Mr. Watson Lead-Acid (Automobile Battery)

29 HST Mr. Watson Lead-Acid (Automobile Battery) Pb (s) + PbO 2(s) + 2 H 2 SO 4 = 2 PbSO 4(s) + 2 H 2 O 2 v/cell

30 HST Mr. Watson Nickel-Cadmium (Ni-Cad) Cd (s) + 2 Ni(OH) 3(s) = Cd(OH) 2(s) + 2 Ni(OH) 2(s) NiCad 1.25 v/cell

31 HST Mr. Watson Hydrogen-Oxygen Fuel Cell

32 HST Mr. Watson Automobile Oxygen Sensor

33 HST Mr. Watson Automobile Oxygen Sensor see Oxygen Sensor Movie from Solid-State Resources CD-ROM

34 HST Mr. Watson pH = (E glass electrode - constant)/0.0592 pH Meter

35 HST Mr. Watson Effect of Concentration on Cell Voltage: The Nernst Equation E cell = E o cell - (RT/nF)ln Q E cell = E o cell - (0.0592/n)log Q whereQ => reaction quotient Q = [products]/[reactants]

36 HST Mr. Watson EXAMPLE: What is the cell potential for the Daniel's cell when the [Zn +2 ] = 10 [Cu +2 ] ? Q = ([Zn +2 ]/[Cu +2 ] = (10 [Cu +2 ])/[Cu +2 ] = 10 E o = (0.34 V) Cu couple + (-(-0.76 V) Zn couple n = 2, 2 electron changeE cell = E o cell - (0.0257/n)ln Q thusE cell = (1.10 - (0.0257/2)ln 10) V E cell = (1.10 - (0.0257/2)2.303) V E cell = (1.10 - 0.0296) V = 1.07 V

37 HST Mr. Watson Nernst Equation [H + ] acid side  [H + ] base side E = E o – RT nF ln Q = – 2.3 RT F log [H + ] base side [H + ] acid side [h + ] p-type side  [h + ] n-type side E (in volts) = – 2.3 RT F log [h + ] n-type side [h + ] p-type side

38 HST Mr. Watson Electrolysis non-spontaneous reaction is caused by the passage of an electric current through a solution

39 HST Mr. Watson Electrolysis of KI (aq)

40 HST Mr. Watson Electrolysis Electrolysis of Sodium chloride (chlor-alkali process) molten reactants =>liquid sodium and chlorine gas aqueous reactants => caustic soda (sodium hydroxide) and chlorine gas

41 HST Mr. Watson Aqueous Reactants => caustic soda (sodium hydroxide) and chlorine gas

42 HST Mr. Watson Molten Reactants => liquid sodium and chlorine gas

43 HST Mr. Watson Electrolysis Preparation of Aluminum (Hall process)

44 HST Mr. Watson Electrolytic Refining of Copper Cu (s) + Cu +2 (aq) --> Cu +2 (aq) + Cu (s) impure pure anode cathode impurities: anode mud; Ag, Au, Pb

45 HST Mr. Watson Copper Purification

46 HST Mr. Watson Copper Purification

47 HST Mr. Watson Hall Process for Aluminum

48 HST Mr. Watson Quantitative Aspects of Electrolysis 1 coulomb = 1 amp sec 1 mole e - = 96,500 coulombs

49 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current?

50 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current? (45 min) #g Cr = ------------

51 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current? definition of minute (45 min)(60 sec) #g Cr = --------------------- (1 min)

52 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current? (45) (60 sec) (25 amp) #g Cr = --------------------------- (1)

53 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current? definition of a coulomb (45)(60 sec)(25 amp)(1 C) #g Cr = ----------------------------- (1) (1 amp sec)

54 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current? Faraday’s constant (45)(25)(60)(1 C)(1 mol e - ) #g Cr = ---------------------------------- (1)(1)(96,500 C)

55 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current? atomic weight (45)(60)(25)(1)(1 mol e - )(52 g Cr) #g Cr = ------------------------------------------- (1)(1)(96,500) (6 mol e - )

56 HST Mr. Watson Electroplating EXAMPLE: How many grams of chromium can be plated from a Cr +6 solution in 45 minutes at a 25 amp current? (45)(60)(25)(1)(1 mol e - )(52 g Cr) #g Cr = ------------------------------------------- (1)(1)(96,500)(6 mol e - ) = 58 g Cr

57 HST Mr. Watson Rusting of Iron

58 HST Mr. Watson Corrosion O 2(g) + 4 H + (aq) + 4 e - -----> 2 H 2 O (l) E o = 1.23 V Rusting Fe (s) -----> Fe +2 (aq) + 2 e - E o = 0.44 V O 2(g) + 4 H + (aq) + 4 e - -----> 2 H 2 O (l) E o = 1.23 V ------------------------------------------- -------------- 2 Fe (s) + O 2(g) + 4 H + (aq) -----> 2 H 2 O (l) + Fe +2 (aq) E o = 1.67 V

59 HST Mr. Watson Preventing Corrosion painting galvanizing sacrificial anode

Download ppt "Chapter 19 Electrochemistry Mr. Watson HST. Mr. Watson Redox Reactions Oxidation loss of electrons Reduction gain of electrons oxidizing agent substance."

Similar presentations

Redox potentials Electrochemistry ICS.

Redox potentials Electrochemistry ICS.
Electrochemistry Applications of Redox.

Electrochemistry Applications of Redox.
Chapter 20: Electrochemistry

Chapter 20: Electrochemistry
Electricity from Chemical Reactions

Electricity from Chemical Reactions
1 Electrochemistry Chapter 18, 19-20. 2 Electrochemical processes are oxidation-reduction reactions in which: the energy released by a spontaneous reaction.

1 Electrochemistry Chapter 18, Electrochemical processes are oxidation-reduction reactions in which: the energy released by a spontaneous reaction.
Chapter 17 Electrochemistry

Chapter 17 Electrochemistry
Elektrokeemia alused.

Elektrokeemia alused.
The Study of the Interchange of Chemical and Electrical Energy

The Study of the Interchange of Chemical and Electrical Energy
Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Electrochemistry The study of the interchange of chemical and electrical energy.

Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Electrochemistry The study of the interchange of chemical and electrical energy.
Electrolysis non-spontaneous reaction is caused by the passage of an electric current through a solution.

Electrolysis non-spontaneous reaction is caused by the passage of an electric current through a solution.
Electrochemistry 18.1 Balancing Oxidation–Reduction Reactions

Electrochemistry 18.1 Balancing Oxidation–Reduction Reactions
Chapter 18 Electrochemistry

Chapter 18 Electrochemistry
Predicting Spontaneous Reactions

Predicting Spontaneous Reactions
1 Electrochemistry Chapter 17 Seneca Valley SHS. 2 17.1Voltaic (Galvanic) Cells: Oxidation-Reduction Reactions Oxidation-Reduction Reactions Zn added.

1 Electrochemistry Chapter 17 Seneca Valley SHS Voltaic (Galvanic) Cells: Oxidation-Reduction Reactions Oxidation-Reduction Reactions Zn added.
CHEM 160 General Chemistry II Lecture Presentation Electrochemistry December 1, 2004 Chapter 20.

CHEM 160 General Chemistry II Lecture Presentation Electrochemistry December 1, 2004 Chapter 20.
Electrochemistry Lincoln High School Version 1.04

Electrochemistry Lincoln High School Version 1.04
Electrochemistry Electrochemical Cell – an apparatus that uses redox reactions to produce electrical energy. Voltaic Cell – a type of electrochemical cell.

Electrochemistry Electrochemical Cell – an apparatus that uses redox reactions to produce electrical energy. Voltaic Cell – a type of electrochemical cell.
Section 18.1 Electron Transfer Reactions 1.To learn about metal-nonmetal oxidation–reduction reactions 2.To learn to assign oxidation states Objectives.

Section 18.1 Electron Transfer Reactions 1.To learn about metal-nonmetal oxidation–reduction reactions 2.To learn to assign oxidation states Objectives.
Electrochemistry Lincoln High School Version 1.03

Electrochemistry Lincoln High School Version 1.03
ELECTROCHEMISTRY CHARGE (Q) – A property of matter which causes it to experience the electromagnetic force COULOMB (C) – The quantity of charge equal to.

ELECTROCHEMISTRY CHARGE (Q) – A property of matter which causes it to experience the electromagnetic force COULOMB (C) – The quantity of charge equal to.

Similar presentations

Ads by Google