electrochemistry oxidation reduction reactions
DESCRIPTION
ELECTROCHEMISTRY OXIDATION REDUCTION REACTIONS. OXIDATION REDUCTION Reactions and Electrochemical Cells. Voltaic Cells: Using Spontaneous Reactions to Generate Electrical Energy. Cell Potential: Output of a Voltaic Cell. Free Energy and Electrical Work. - PowerPoint PPT PresentationTRANSCRIPT
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ELECTROCHEMISTRYOXIDATION REDUCTION REACTIONS
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OXIDATION REDUCTION Reactions and Electrochemical Cells
Voltaic Cells: Using Spontaneous Reactions to Generate Electrical Energy
Cell Potential: Output of a Voltaic Cell
Free Energy and Electrical WorkElectrolytic Cells: Using Electrical Energy to Drive Nonspontaneous Reactions
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Key Points About Redox Reactions
o Oxidation (electron loss) always accompanies reduction (electron gain).
o The oxidizing agent is reduced, and the reducing agent is oxidized.
o The number of electrons gained by the oxidizing agent always equals the number lost by the reducing agent.
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REDOX reactions - transfer of electrons between species.
All the redox reactions have two parts:
Oxidation Reduction
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• The Loss of Electrons is Oxidation.• An element that loses electrons is said to be
oxidized. • The species in which that element is present in a
reaction is called the reducing agent.
• The Gain of Electrons is Reduction.• An element that gains electrons is said to be
reduced.• The species in which that element is present in a
reaction is called the oxidizing agent.
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A summary of terminology for oxidation-reduction (redox) reactions.
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OXIDATION STATES
The oxidation state (oxidation number) is an indicator of the degree of oxidation of an atom in a chemical compound. The formal oxidation state is the hypothetical charge that an atom would have if all bonds to atoms of different elements were 100% ionic.
Oxidation states are typically represented by integers, which can be positive, negative, or zero. In some cases, the average oxidation state of an element is a fraction, such as 8/3 for iron in magnetite (Fe3O4)
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ASSIGNING OXIDATION STATES (IUPAC)
the oxidation state of a free element (uncombined element) is zerofor a simple (monatomic) ion, the oxidation state is equal to the net charge on the ion
hydrogen has an oxidation state of 1 and oxygen has an oxidation state of −2 when they are present in most compounds. (Exceptions hydrides and peroxides)
the algebraic sum of oxidation states of all atoms in a neutral molecule must be zero, while in ions the algebraic sum of the oxidation states of the constituent atoms must be equal to the charge on the ion
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A SUMMARY OF REDOX TERMINOLOGY
Zn loses electrons.Zn is the reducing agent and becomes oxidized.The oxidation number of Zn increases from 0 to +2.REDUCTION
One reactant loses electrons.Reducing agent is oxidized.
Oxidation number increases.
Hydrogen ion gains electrons.Hydrogen ion is the oxidizing agent and becomes reduced.The oxidation number of H decreases from +1 to 0.
Other reactant gains electrons.Oxidizing agent is reduced.
Oxidation number decreases.
Zn(s) + 2H+(aq) → Zn2+(aq) + H2(g)
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HALF-REACTION METHOD FOR BALANCING REDOX REACTIONS
Summary: This method divides the overall redox reaction into oxidation and reduction half-reactions.o Each reaction is balanced for mass (atoms) and charge.o One or both are multiplied by some integer to make the
number of electrons gained and lost equal.o The half-reactions are then recombined to give the
balanced redox equation.
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Half-Reaction Method for Balancing Redox Reactions
Advantages:o The separation of half-reactions reflects actual physical
separations in electrochemical cells.o The half-reactions are easier to balance especially if they
involve acid or base.o It is usually not necessary to assign oxidation numbers to
those species not undergoing change.
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HALF-REACTION METHOD FOR BALANCING REDOX REACTIONS
1. Divide the equation into two half reactions.2. Balance each half reaction
- balance all elements other than H and O- balance the number of oxygen by adding H2O as
needed- balance the number of hydrogen by adding H+
as needed- balance the charges by adding e- as needed
3. Multiply each half-reactions by integers such as the number of electrons lost equals the number of electrons gained.
4. Add the reactions cancelling species that appear on both sides.
5. Check
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Balancing Redox Reactions in Acidic Solution
Mn+2 + BiO3- → Bi+3 + MnO4
-
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Balancing Redox Reactions in Basic Solution
Balance the reaction in acid and then add OH- so as to neutralize the H+ ions.
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SAMPLE PROBLEM:Balance the following equation:
CN- + MnO4- → CNO- + MnO2(s) (basic
solution)
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Figure 21.3 General characteristics of voltaic and electrolytic cells.
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Figure 21.5 A voltaic cell based on the zinc-copper reaction.
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Notation for a Voltaic Cell
Components of anode compartment
(oxidation half-cell)
Components of cathode compartment
(reduction half-cell)
Phase of lower oxidation state
Phase of higher oxidation state
Phase of higher oxidation state
Phase of lower oxidation state
Phase boundary between half-cellsExamples: Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu (s)
Zn(s) Zn2+(aq) + 2e- Cu2+(aq) + 2e- Cu(s)
graphite | I-(aq) | I2(s) || H+(aq), MnO4-(aq) | Mn2+(aq) | graphite
inert electrodes
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Figure 21.6 A voltaic cell using inactive electrodes.
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SAMPLE PROBLEM
The oxidation-reduction reaction,Cr2O7
2-(aq) + 14H+(aq) + 6I-(aq) → 2Cr3+(aq) + 3I2(s) + 7H2O(l)
is spontaneous. Draw a diagram of the cell and indicate the reactions occuring at the electrodes (anode, cathode), the direction of electron migration, the direction of ion migration, the signs of the electrodes. Write the notation for the cell.
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Describing a Voltaic Cell with Diagram and Notation
Draw a diagram, show balanced equations, and write the notation for a voltaic cell that consists of one half-cell with a Cr bar in a Cr(NO3)3 solution, another half-cell with an Ag bar in an AgNO3 solution, and a KNO3 salt bridge. Measurement indicates that the Cr electrode is negative relative to the Ag electrode.
Identify the oxidation and reduction reactions and write each half-reaction. Associate the (-)(Cr) pole with the anode (oxidation) and the (+) pole with the cathode (reduction).
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Sample Problem 21.2
PLAN:
SOLUTION:
Identify the oxidation and reduction reactions and write each half-reaction. Associate the (-)(Cr) pole with the anode (oxidation) and the (+) pole with the cathode (reduction).
Cr(s) | Cr3+(aq) || Ag+(aq) | Ag(s)
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Determining an unknown Eohalf-cell with the standard
reference (hydrogen) electrode.
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Eocell = Eo
cathode - Eoanode.
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Sample Problem 21.3 Calculating an Unknown Eohalf-cell from Eo
cell
A voltaic cell houses the reaction between aqueous bromine and zinc metal:
Br2(aq) + Zn(s) Zn2+(aq) + 2Br -(aq) Eocell = 1.83 V
Calculate Eobromine, given Eo
zinc = -0.76 V.
The reaction is spontaneous as written since the Eocell is (+). Zinc is
being oxidized and is the anode. Therefore, the Eobromine can be found
using Eocell = Eo
cathode - Eoanode.
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Sample Problem 21.3 Calculating an Unknown Eohalf-cell from Eo
cell
PLAN:
SOLUTION:
The reaction is spontaneous as written since the Eocell is (+). Zinc is
being oxidized and is the anode. Therefore, the Eobromine can be found
using Eocell = Eo
cathode - Eoanode.
Anode: Zn(s) Zn2+(aq) + 2e- E = +0.76 V
EoZn as Zn2+(aq) + 2e- Zn(s) is -0.76 V
Eocell = Eo
cathode - Eoanode = 1.83 = Eo
bromine - (-0.76)
Eobromine = 1.83 + (-0.76) = 1.07 V
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•By convention, electrode potentials are written as reductions.
•When pairing two half-cells, you must reverse one reduction half-cell to produce an oxidation half-cell. Reverse the sign of the potential.
•The reduction half-cell potential and the oxidation half-cell potential are added to obtain the Eo
cell.
•When writing a spontaneous redox reaction, the left side (reactants) must contain the stronger oxidizing and reducing agents.
Example: Zn(s) + Cu2+(aq) Zn2+(aq) + Cu(s)stronger
reducing agentweaker
oxidizing agentstronger
oxidizing agentweaker
reducing agent
Writing Spontaneous Redox Reactions
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Sample Problem 21.4Writing Spontaneous Redox Reactions
PROBLEM: (a) Combine the following three half-reactions into three balanced equations (A, B, and C) for spontaneous reactions, and calculate Eo
cell for each. Eo = 0.96 V(1) NO3
-(aq) + 4H+(aq) + 3e- NO(g) + 2H2O(l)Eo = -0.23 V(2) N2(g) + 5H+(aq) + 4e- N2H5
+(aq)Eo = 1.23 V(3) MnO2(s) + 4H+(aq) + 2e- Mn2+(aq) + 2H2O(l)
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Relative Reactivities (Activities) of Metals
1. Metals that can displace H2 from acid.
2. Metals that cannot displace H2 from acid.
3. Metals that can displace H2 from water.
4. Metals that can displace other metals from solution.
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The activity series of the metals.
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Free Energy and Electrical Work
DG a -Ecell
-Ecell =-wmax
charge
charge = nFn = mol e-
F = Faraday constant
F =
1 V = 1
F =
DG = wmax = charge x (-Ecell)
DG = -nFEcell
In the standard state -DGo = -nFEo
cell
DGo = - RT ln K
Eocell = - ( )ln K
96,485 Cmol e-
9.65 x 104 JV•mol e-
JC
RTn F
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The interrelationship of DG0, E0cell, and K.
< 00
> 0
> 00
< 0
> 11
< 1DGo = -RT lnK
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The Effect of Concentration on Cell Potential
DG = DGo + RT ln Q
-nF Ecell = -nF Ecell + RT ln Q
Ecell = Eocell - ln Q
RTnF
•When Q < 1 and thus [reactant] > [product], ln Q < 0, so Ecell > Eocell.
•When Q >1 and thus [reactant] < [product], ln Q > 0, so Ecell < Eocell.
•When Q = 1 and thus [reactant] = [product], ln Q = 0, so Ecell = Eocell.
Ecell = Eocell - log Q0.0592
n
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Figure 21.12 A concentration cell based on the Cu/Cu2+ half-reaction.
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Figure 21.13 The laboratory measurement of pH.
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Alkaline battery.Figure 21.14
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Silver button battery.Figure 21.15
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Lead-acid battery.Figure 21.16
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Nickel-metal hydride battery.Figure 21.17
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Lithium-ion battery.Figure 21.18
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Figure 21.19 Hydrogen fuel cell.
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Figure 21.20 The corrosion of iron.
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Figure 21.21 The effect of metal-metal contact on the corrosion of iron.
Faster corrosion
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Figure 21.22 The use of sacrificial anodes to prevent iron corrosion.
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ELECTROLYTIC CELL
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ELECTROLYSIS OF MOLTEN SALTS
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Predicting the Electrolysis Products of Aqueous Ionic SolutionsWhat products form during electrolysis of aqueous solutions of the following salts: (a) KBr;
Compare the potentials of the reacting ions with those of water, remembering to consider the 0.4 to 0.6 V overvoltage.
The reduction half-reaction with the less negative potential, and the oxidation half-reaction with the less positive potential will occur at their respective electrodes.
Eo = -2.93 V(a) K+(aq) + e- K(s)Eo = -0.42 V2H2O(l) + 2e- H2(g) + 2OH-(aq)
The overvoltage would make the water reduction -0.8 to -1.0 V, but the reduction of K+ is still a higher potential so H2(g) is produced at the cathode.
The overvoltage would give the water half-cell more potential than Br -, so the Br - will be oxidized. Br2(l) forms at the anode.
Eo = 1.07 V2Br -(aq) Br2(l) + 2e-
2H2O(l) O2(g) + 4H+(aq) + 4e- Eo = 0.82 V
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A summary diagram for the stoichiometry of electrolysis.
Faraday’s Law of Electrolysis:
The amount of substances that undergoes oxidation or reduction at each electrode during electrolysis is proportional to the amount of electricity that passes through the cell
1.0 Faraday = 96,500 C1 ampere = 1 C/s
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CORROSION PROTECTION
1. Plating the metal with a thin layer of less easily oxidized2. Connecting a metal to a sacrificial anode (a more active
metal – preferentially oxidized3. Metal oxides to form naturally on the surface4. Galvanizing (coating with zinc)5. Protective coating, such as paint
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Latimer Diagram Frost Diagram
DIAGRAMMATIC REPRESENTATIONSOF REDUCTION POTENTIAL DATA
Pourbaix Diagram
Table of redox potentials are organized by the voltage of the process rather than by the chemical species involved.
Difficult to use if one wants to understand the complex redox chemistry of the elements
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Reminder: Thermodynamic data will predict which reactions ought to occur, but cannot determine whether they happen at an observable rate or not.
Most of the redox reactions of inorganic compounds are rapid reactions, but there are many times when thermodynamics predicts more than one possible product, and where the actual product is selected by the rate of reaction.
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• Written with the most oxidized species on the left and the most reduced species on the right.
• Oxidation number decrease from left to right and the E0 values are written above the line joining the species involved in the couple.
LATIMER DIAGRAMS
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LATIMER DIAGRAMS
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Look at the Latimer diagram of nitrogen in acidic solution
a b c d e
f g h
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FROST DIAGRAM N2
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FROST DIAGRAMS - INTERPRETATIONThe lowest point represent the most thermodynamically stable form of the element
A move downward the plot represent a thermodynamically favorable process
A species at the to right of the diagram is oxidizing. Strengths relative to their position.
The slope of the line drawn between two points divided by the number of electrons transferred is the Eo for the half reaction. A positive slope means the reduction process is positive.
Any state represented on a ‘convex’ point is thermodynamically unstable with respect to disproportionation
Any state represented on a ‘concave’ point is thermodynamicallystable with respect to disproportionation,
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the lowest lying species corresponds to the most stable oxidation state of the element
What do we really get from the Frost diagram?
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The oxidizing agent - couple with more positive slope - more positive E
The reducing agent - couple with less positive slope
If the line has –ive slope- higher lying species – reducing agent
If the line has +ive slope – higher lying species – oxidizing agent
Oxidizing agent? Reducing agent?
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Identify all the species that are unstable with respect to disproportionation
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DISPROPORTIONATION…. ANOTHER EXAMPLE
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Comproportionation reaction
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Comproportionation is spontaneous if the intermediate species lies below the straight line joining the two reactant species.
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NE0
Identify species that are unstable to disproportionation and comproportionation
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Disproportionation
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Comproportionation
In acidic solution…Mn and MnO2
Mn2+
Rate of the reaction hinderedinsolubility?
In basic solution…MnO2 and Mn(OH)2
Mn2O3
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Consider the Latimer Diagrams for Pb and Tin in acid solution.
A) Calculate values of nE for each oxidation state of lead and tin, and construct a comparative Frost diagram for these two elements in acid solution.
B) Which of the six species you have plotted is the strongest oxidizing agent? Justify your answer.
C) Which of the six species you have plotted is the strongest reducing agent? Justify your answer.
D) What product(s) would form if PbO2 was mixed with Sn2+ in acidic solution? Write a balanced equation.
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POURBAIX DIAGRAMS
Graphical representations of thermodynamic and electrochemical equilibria between metal and water, indicating thermodynamically stable phases as a function of electrode potential and pH.
-predicts the spontaneous direction of reactions.-estimates the composition of corrosion products.-predicts environmental changes that will prevent or reduce corrosion attack.
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SAMPLE PROBLEM:
Consider the Pourbaix diagram for manganese.(a)What form(s) will manganese take in lake and stream water,
where the pH = 6-8 and Eo= 0.6-0.7 V?
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