Post on 23-Feb-2016
description
GALVANIC CELLSAHAR ADHAM
LECTUERE OF PHYSICAL CHEMISTRY
galvanic electrolytic
needpowersourcetwo
electrodes
produces electrical current
anode (-)cathode (+)
anode (+)cathode (-)
salt bridge vessel
conductive medium
Comparison of Electrochemical Cells
E°cell > 0.E°cell < 0.
ELECTRON TRANSFER REACTIONS
Electron transfer reactions are oxidation-reduction or redox reactions.
Results in the generation of an electric current (electricity) or be caused by imposing an electric current.
Therefore, this field of chemistry is often called ELECTROCHEMISTRY.
YOU CAN’T HAVE ONE… WITHOUT THE OTHER!
oxidation: loss of electronsreduction: gain of electrons
LEO the lion says GER!
GER!
WHY STUDY ELECTROCHEMISTRY? Batteries Corrosion Industrial production
of chemicals such as Cl2, NaOH, F2 and Al
Biological redox reactions
The heme group
GALVANIC CELLS
One ½ cell rxn. occurs in each compartment.
Zn Zn2+ + 2e– in the anode.
Cu2+ + 2e– Cu in cathode.
But not without a connection.
Zn
Zn2+ Cu2+
Zn + Cu2+ Zn2+ + Cu
SO42– SO4
2–
CuAnode=Oxidation
Cathode=Reduction
ION (“SALT”) BRIDGE
But even with a connection of the electrodes, no current flows.
We need to allow neutrality in the solutions with a salt bridge to shift counterions.
Zn
Zn2+ Cu2+
Zn + Cu2+ Zn2+ + Cu
SO42– SO4
2–
Cu
2e– 2e–
Cell Potential
•Cell Potential or Electromotive Force (emf): The “pull” or driving force on the electrons.
STANDARD REDUCTION POTENTIALS, E°
The voltage generated by the Zn/Cu galvanic cell is +1.1V under standard conditions.
Standard conditions are: T = 25°C and P = 1 bar for gases. Solids and liquids are pure. Solutions are 1 M in all species.
E°cell is sum of ½ cell E° values.
CELL POTENTIALS AND REDUCTION POTENTIALS
E°cell = E°reduced - E°oxidized
E°cell = E°cathode - E°anode
½ CELL REDUCTION POTENTIALS All ½ cells are catalogued as reduction
reactions & assigned reduction potentials, E°. The lower reduction potential ½ rxn is
reversed to become the oxidation. E°oxidation = –E°reduction
That makes spontaneous E°cell > 0. But E°red can’t be found w/o E°ox!
ORIGIN FOR REDUCTION POTENTIALS
We need a standard electrode to make measurements against!
The Standard Hydrogen Electrode (SHE) 2H+(aq) + 2e– H2(1 bar) E° 0 V
1 bar H2 flows over a Pt electrode, and the full E°cell is assigned to the other electrode. E°SHE = 0 V.
E.g., standard calomel electrode: Hg2Cl2(s) + 2e– 2 Hg(l) + Cl– E°SCE = +0.27V a more physically convenient reference.
GALVANIC LINE NOTATION
Shorthand for a complete redox cell is of the form:
Anode | anodic soln. || cathodic soln. | Cathode
So making a cell of Cu corrosion,
Cu | Cu2+ || NO3–, NO(g), H+ |Pt
where all ions should be suffixed (aq) and both metals should have (s).
TYPES OF GALVANIC CELLSPrimary Battery: can not be recharged e.g. Mercury Battery
Secondary Battery: rechargeable (storage batteries) e.g. Ni-Cad Battery
Fuel Cell: reactants supplied from an external source e.g.
H2/O2 fuel cells.
MERCURY BATTERYAnode:
Zn is reducing agent under basic conditions
Cathode:HgO + H2O + 2e- ---> Hg + 2 OH-
can not be recharged
NI-CAD BATTERYAnode (-)Cd + 2 OH- ---> Cd(OH)2 + 2e-Cathode (+) NiO(OH) + H2O + e- ---> Ni(OH)2 + OH-
rechargeable
WHY RECHARGEABLE?.It is because the products of the reaction are solids that the Ni-Cd battery can be recharged
The solid hydroxides are sticky, and remain in place.
If current is applied, the reaction can be driven
backwards!
HOW TO CHARGE?
When you charge a battery, you are forcing the electrons backwards (from the + to the -). To do this, you will need a higher voltage backwards than forwards.
WHY NOT RECHARGEABLE ?
But in mercury battery the ZnO is not sticky, and doesn’t remain attached to the electrode. This battery is not rechargeable
H2 AS A FUEL
Cars can use electricity generated by H2/O2 fuel cells.H2 carried in tanks or generated from hydrocarbons
17-44
Galvanic cells for which the reactants are continuously supplied.anode: 2H2 + 4OH 4H2O + 4e
cathode :4e + O2 + 2H2O 4OH
2H2(g) + O2(g) 2H2O(l)
Fuel Cells
Mercury batteries take advantage of the high density of Hg to be quite small: used in watches, hearing aids, calculators, etc.
Lithium-iodine batteries are particularly small and lightweight, but also very long-lived
Often used in pacemakers, where they can last for 10 years
THE END
V1.06
QUESTION 1For a galvanic cell, the electrode at which reduction occurs is called the:
A: Anode B: Cathode
ANSWERFor a galvanic cell, the electrode at which reduction occurs is called the:
B: Cathode
QUESTION 2For a galvanic cell, the electrode with negative polarity is called the:
A: Anode B: Cathode
ANSWERFor a galvanic cell, the electrode with negative polarity is called the:
A: Anode
QUESTION 3Which of the following statements is incorrect
a. In a galvanic cell, reduction occurs at the anode.
b. The cathode is labeled "+" in a voltaic cell.
c. Oxidation occurs at the anode in a voltaic cell.
d. Electrons flow from the anode to the cathode in all electrochemical cells.
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ANSWERa. In a galvanic cell, reduction occurs at the
anode.
QUESTION 4Consider the following notation for an electrochemical cell
Zn|Zn2+ (1M)||Fe3+ (1M), Fe2+ (1M)|Pt
What is the balanced equation for the cell reaction?
a.Zn(s) + 2Fe3+(aq) → 2Fe2+(aq) + Zn2+(aq)b.Zn2+(aq) + 2Fe2+(aq) → Zn(s) + 2Fe3+(aq)c.Zn(s) + 2Fe2+(aq) → 2Fe3+(aq) + Zn2+(aq)d.Zn(s) + Fe3+(aq) → Fe2+(aq) + Zn2+(aq)e.Zn(s) + Fe2+(aq) → Fe(s) + Zn2+(aq)
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ANSWER
Zn(s) + 2Fe3+(aq) → 2Fe2+(aq) + Zn2+(aq)
QUESTION 5 What is the oxidation state of nitrogen in HNO3?
A: +3 B: +4
C: +5 D: -5
ANSWERWhat is the oxidation state of nitrogen in HNO3?
C: +5
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QUESTION 6Consider the following electrode potentials:Mg2+ + 2e– Mg E° = –2.37 VV2+ + 2e– V E° = –1.18 VCu2+ + e– Cu+ E° = 0.15 VWhich one of the reactions below will proceed
spontaneously from left to right?
a. Mg2+ + V V2+ + Mgb. Mg2+ + 2Cu+ 2Cu2+ + Mgc. V2+ + 2Cu+ V +2 + Cu2+
d. V + 2Cu2+ V2+ + 2Cu+
e. none of these
ANSWER
d. V + 2Cu2+ V2+ + 2Cu+
QUESTION 7What is the oxidative state of iodine in IO3
-?
A: +7 B: +6
C: +5 D: +4
ANSWERWhat is the oxidative state of iodine in IO3
-?
C: +5