Download presentation
Presentation is loading. Please wait.
Published byMaude Burns Modified over 9 years ago
2
Electrochemical CellElectrochemical Cell Electrochemical device with 2 half-cells connecting electrodes and solutions Electrode —metal strip in electrochemical cell
3
2 types of electrochemical cells2 types of electrochemical cells 1)Voltaic Cells/Galvanic Cell 2)Electrolytic Cells Still dealing with oxidation-reduction reactions Physical separation of oxidation and reduction processes
4
1) Voltaic Cells/Galvanic Cell “simple battery” Electric current generated from a redox reaction Pathway of electron transfer Redox reactions in this cell are always SPONTANEOUS ( Δ G < 0 ) Physically separates oxidation process from reduction process
6
Voltaic Cell—Oxidation Process Anode Electrode where oxidation occurs Negative charge, source of electrons Metal electrode dissolves and metallic ions form in solution Electrons released into solution and buildup NEGATIVE charge at electrode---electrons migrate out through connecting wire GIVING UP ELECTRONS !!
8
Voltaic Cell—Reduction Process Cathode Electrode where reduction occurs Positive charge, electron receiver, ion source Metallic ions (cations) attracted to electrons on electrode surface and accept electrons coming from the anode through the connecting wire. Metallic ions converted to solid metal on the electrode
10
Salt BridgeSalt Bridge U-shaped tube containing a soluble salt in a saturated solution (ex. KNO 3 ) Salt solution MUST be soluble, not form precipitate Maintains electrical neutrality within cell solutions Electrons do NOT go through bridge, only through wire Salt dissociates into ions, ions move to balance charges Negative ions move to ANODE, minimize POSITIVE charge Positive ions move to CATHODE, minimize NEGATIVE charge No acting role in redox reaction
12
General Points for Voltaic Cells Electrons move from ANODE (-) to CATHODE (+) Electrons have HIGH potential energy at anode, not cathode Naturally favor a state of low potential energy Electron movement through the connecting wire generates an electric current that can be utilized.
14
Cell Potential (E cell )Cell Potential (E cell ) Also called “ cell voltage ” “Driving force” transferring electrons from anode to cathode Difference between the electric potential between the electrodes in an electrochemical cell Magnitude indicates amount of current generated through redox reaction Measured by voltmeter, units = volts (V)
15
Cell DiagramsCell Diagrams Representation of an electrochemical cell, short-hand method to actual drawing of cell Anode--- Left portion Cathode--- Right portion Single line— Boundary between electrode and solution Double line— Represents salt bridge
16
Example 1:Example 1: Oxidation: Zn (s) Zn +2 + 2e - Reduction: Cu +2 + 2e - Cu (s) Remember to combine reactions by balancing elements and electrons in half reactions.
17
Example 2:Example 2: Write the equation for the redox reaction occurring in this voltaic cell. Al (s) Al +3 (aq) H + (aq) H 2(g) Pt (s)
19
How do we cell potential/voltage? 1)Voltmeter 2)Calculation of cell voltages Find cell potentials for each half-cell reaction and combine these potentials Need to set a baseline or zero point for measuring electrode potentials for half-cell reactions
20
Standard Hydrogen Electrode (SHE) Assigned zero point/baseline for electrode potentials All electrode potentials based on this point H 2 gas passed over Pt electrode at standard conditions 1 atm, 1M, 25°C° 2H + + 2e - H 2(g) E° = 0V
22
Standard Electrode Potential (E°) Also known as “reduction potentials” Tendency for reduction to happen at an electrode Measured with solutions at 1M and gases at 1atm, 25°C Used to determine standard cell potential (E°cell) for an overall reaction
23
Standard Cell Potential (E°cell) Difference between the standard potential of the cathode and the standard potential of the anode. Measured with a voltmeter E°cell = E°cathode –E°anode OR E° cell = E° ox + E° red Enables us to indirectly calculate the standard electrode potentials for chemical compounds with unknown potentials.
24
Standard Electrode Potentials Located in reference tables for common reduction half- reactions (Table 18.1 p. 762, Appendix C) Arranged from increasing to decreasing E° values Compounds favoring reduction, high on table Compounds favoring oxidation, low on table
25
Example 1:Example 1: Find E° Cu+2/Cu based on the following reaction. Pt H 2(g) H + (aq) Cu +2 (aq) Cu (s) E°cell = 0.340V
26
Example 2:Example 2: Find E° Zn+2/Zn based on the following reaction. Pt H 2(g) H + (aq) Zn +2 (aq) Zn (s) E°cell = -0.763V
27
Example 3:Example 3: Calculate the standard cell potential (E°cell) for the following voltaic cell: Zn (s) Zn +2 (aq) Cu +2 (aq) Cu (s)
28
Example 4:Example 4: Determine the standard electrode potential (E° Sm+2/Sm ) Sm (s) Sm +2 I - I 2(s) Pt (s) E°cell = 3.21V
29
Example 5:Example 5: Balance the following redox reaction and determine the E°cell. O 2(g) + H + (aq) + I - (aq) H 2 O (l) + I 2(s)
30
Example 6:Example 6: Zn +2 + 2e - Zn (s) E° = -0.7628 V Zn (s) Zn +2 + 2e - E° = +0.7628V
31
Homework p.759 #18.3B p. 792-793 #33, 34, 35, 37-40
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.