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Redox Reactions and Electrochemistry
Problem Set
Chapter 5: 21-26, Chapter 21: 15-17, 32, 34, 43, 53, 72, 74
Oxidation/Reduction & Electrochemistry
Oxidation – a reaction in which a substance gainsoxygen atoms
Reduction - a reaction in which a substance losesoxygen atoms
(e.g. the oxidation of a hydrocarbon)
C
H
H
HR C
OH
H
HR C
O
HRC
O
OHRCO O OH2+
O2 O2 O2 O2
(i.e. this is equivalent to the combustion of a hydrocarbon)
Oxidation/Reduction & Electrochemistry• A different type of “redox” (i.e. reduction plus oxidation) reaction does not involve gain or loss of oxygen.• Tarnishing of silver is a redox reaction that produces Ag2S.
• This spontaneous reaction can be reversed with a coupled reaction (add 80 g of baking soda and 80 g of table salt per litre of near boiling water in an aluminum pan to a depth covering the silver object).
3 Ag2S + 2 Al + 6 H2O → 6 Ag + 2 Al(OH)3 + 3 H2S
2
Oxidation/Reduction & Electrochemistry
Cu+2/Zn Cu /Zn+2
Cu+2(aq) + Zn(s) Cu(s) + Zn+2
(aq)
Let’s look at a simple case of this type of redox reaction:
Redox ReactionsCu+2
(aq) + Zn(s) Cu(s) + Zn+2(aq)
The reaction can be represented by two half-reactions in which electrons are either gained or lost and the “oxidation state” of elements changes :
Cu+2(aq) + 2e- Cu(s) oxidation state of Cu +2 0
Zn(s) Zn+2(aq) + 2e- oxidation state of Zn 0 +2
Reduction – a process in which electrons are gained. (The oxidation state of an element decreases and electrons appear on the left side of the half-reaction.)
Oxidation – a process in which electrons are lost. (The oxidation state of an element increases and electrons appear on the right side of the half-reaction.)
Oxidation States - Review
1) Oxidation state of an atom in a free element is 0.
2) Total of the oxidation states of atoms in a molecule or ion is equal to the total charge on the molecule or ion.
3) Group 1A and Group 2A metals have oxidation state of +1 and +2 respectively.
4) F always has an oxidation state of –1. Cl also has oxidation state of –1 unless it is bonded to oxygen or fluorine.
5) H almost always has an oxidation state of +1.
6) O has oxidation state of –2 (unless bonded to itself or F).
7) When bound to metals, group 7A, 6A and 5A elements have oxidation states of -1, -2, -3 respectively.
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Electronegativities-Review
ExampleWhat is the formal oxidation state of P in:
+1 -2
?
: 3 x (+1) + ? + 4 x (-2) = 0 (charge on molecule)
oxidation state of P = +5
H3PO4
: 2 x (+1) + (O.S. of P) + 4 x (-2) = -1 (charge on ion)
oxidation state of P = +5
H2PO4-
: oxidation state of P = +5HPO42-
If the oxidation state of elements do not change in a reaction, it is NOT a redox reaction!
H3PO4(aq) + 3 OH-(aq) 3H2O + PO4
3-(aq) acid/base reaction
Balancing Redox ReactionsHalf-reaction method (not the same as method in textbook). 1) Identify species in which the oxidation state of an
element is changing. Write the skeleton half-reactions including balancing of the redox atoms if necessary.
2) Identify oxidation state on both sides of equation for elements that have a change in oxidation state.
3) Add appropriate number of electrons to either left or right to balance oxidation states of redox atom(s).
4) Balance changes on left and right side of equation by adding H+ (if in acidic solution) or OH- (if in basic solution).
5) Add appropriate number of H2O’s to left or right side of equation to balance atoms in the half-reaction.
4
Balancing Redox Reactions, cont’dAt this point, both half-reactions should be balanced. The next step is to combine the two half-reactions to form an overall equation.
6) Multiply through each half-reactions by appropriate coefficients to match electrons in each half-reaction. (i.e. number of electrons lost by the oxidized species must equal the number gained by the reduced one)
7) Add half-reactions and cancel electrons and other common species on left and right sides of the equation.
8) Check Reaction! It should be balanced in terms of oxidation states, charge and atoms.
IF NOT, YOU HAVE MADE A MISTAKE!
Examples
Determining sulfite in wastewater.
Sulfite is reacted with permanganate to produce sulfate and Mn(II) ion in acidic solution. Balance the redoxreaction.
SO32- + MnO4
- SO42- + Mn2+ skeleton reaction
SO32- SO4
2- identify oxidation states
+4 +6
SO32- SO4
2- + 2e- balance O.S. with electrons
SO32- SO4
2- + 2e- + 2H+ balance charges with H+
H2O + SO32- SO4
2- + 2e- + 2H+ balance atoms with H2O
Cont’d, Mn half-reaction
MnO4- Mn2+ identify oxidation states
+7 +2
MnO4- + 5e- Mn2+ balance O.S. with electrons
8 H+ + MnO4- + 5e- Mn2+ balance charges with H+
8 H+ + MnO4- + 5e- Mn2+ + 4H2O balance atoms with H2O
8 H+ + MnO4- + 5e- Mn2+ + 4H2O
H2O + SO32- SO4
2- + 2e- + 2H+
Balanced Half-Reactions
x 5x 2 to balance e-’s
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Balancing full equation
16 H+ + 2MnO4- + 10e- 2Mn2+ + 8H2O
5H2O + 5SO32- 5SO4
2- + 10e- + 10H+
5SO32- + 2MnO4
- + 6 H+ 5SO42- + 2Mn2+ + 3H2O
6 3
Balanced full reaction:
Check atom balance. OK
Try example 5.7 using this approach, use OH- to balance charge in basic solution. Much easier.
This method forces you to know oxidation states.
Cr2O72-
(aq) Cr+3(aq) skeleton (in acidic solution),
+6 +3
Cr2O72-
(aq) + 2(3e-) 2 Cr+3(aq) balance O.S. with e-’s
Cr2O72-
(aq) 2 Cr+3(aq) balance redox atoms
Cr2O72-
(aq) 2 Cr+3(aq) determine O.S. of redox atoms
Cr2O72-
(aq) + 6e- 2 Cr+3(aq) ” “
14 H+ + Cr2O72-
(aq) + 6e- 2 Cr+3(aq) balance charges with H+
14 H+ + Cr2O72-
(aq) + 6e- 2 Cr+3(aq) + 7H2O balance atoms with H2O
Another ExampleWrite the half reaction for Cr2O7
2- Cr+3
Extra Practise Balancing RedoxReactions (solutions on web site)
#1) Cl2 → ClO- + Cl- in basic solution
#2) I- + IO3- → I2 in acidic solution
#3) H2O2(aq) → O2(g)(in either acidic or basic solution)
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Disproportionation ReactionsA disproportionation reaction occurs when an element in
a substance is both oxidized and reduced.
2 H2O2(aq) 2 H2O(l) + O2(aq)
O OH
H-1 -2 0
Hydrogen peroxide: antiseptic agent, O2 acts as germicide
Example:
Ox/Red Agents, cont’d
Oxidizing Agent – a chemical substance that oxidizes (removes electrons from) other substances in a chemical reaction. In the process of oxidizing something, the oxidant becomes reduced; it’s oxidation state decreases.
Reducing Agent – a chemical substance that reduces (loses electrons to) other substances. In the process of reducing, the reductant becomes oxidized; it’s oxidation state increases.
Oxidizing and Reducing Agents
Removes
electrons
Loses
electrons
Oxidation States of Nitrogen
(best oxidizing agent)
(best reducing agent)
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Oxidizing AgentsO2 – Probably the most common and most important
oxidant known to us. Ubiquitous.
Organic Oxidation Schemes (Example: methane)
CH4
CHO
OH
CH2 OCH3 OH
O C O
-4 -2 0
+2
+4
O2 O2
O2
O2
methane
(alkane)
methanol
(alcohol)
formaldehyde
(aldehyde)
formic acid
(carboxylic acid)
carbon dioxide
(inorganic carbon)
Other oxidizing agentsOxides in their highest oxidation state are frequently strong oxidizing agents.
NO3 HNO3 NO2 NO N2O N2
+6 +5 +4 +2 +1 0
HClO4 ClO3- HClO2 HOCl
+7 +5 +1+3
strong oxidizing agents weaker oxidizing agents
HNO3 and HClO4 are oxidizing acids.
Non-oxidizing acids – HCl, HBr, HI, acids for which the only possible reduction half-reaction is:
2H+(aq) + 2e- H2(g)
Oxidizing Agents, cont’dHNO3 is a much stronger oxidizing agent than H+.
Cu, Ag, Au,Hg
Li, Na, K (1A metals)Mg, Ca (2A metals)Al, ZnFe, Sn, Pb
Metals that will not dissolve
Metals that dissolve in dilute H+ to produce H2
Practice problem – Cu will dissolve in HNO3 producing Cu+2 in solution and the brown gas NO2. Write a balanced equation for this process.
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Electrochemistry(a) Cu(s) / Ag+
(aq)
Cu2+(aq)/ Ag(s)
Spontaneous!
(∆G < 0)
(b) Cu(s) / Zn2+(aq)
No reaction!
Ag+(aq) + e- Ag(s) reduction
Cu(s) Cu2+(aq) + 2 e- oxidation
Not spontaneous!
(∆G > 0)
We can connect half-reactions in separate containers through an electrical circuit. This will produce a current (electron flow) and voltage according to the spontaneity of the reactions.
Electrochemical CellsFlow of electrons (current) can do work.
Atomic view of a Voltaic (galvanic) cell
Anode – oxidation Cathode - reduction
Salt bridge(e.g. KNO3)maintainsneutrality
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Cell Diagrams
• anode (oxidation) is placed at left side of diagram• cathode (reduction) is placed on right side of diagram• boundary line, |, indicates a boundary between different
phase (i.e. solution|solid)• a double boundary line || indicates a boundary (i.e. salt
bridge) between the two half-cell compartments
Zn(s) | Zn2+(aq) || Cu2+
(aq) | Cu(s)anode
(oxidation)cathode(reduction)
half-cell salt bridge half-cell
Voltages and Current
+-anode cathode
Electromotive Force (EMF) - The voltage difference between two solutions provides a measure of the driving force of the electron transfer reaction.
Standard Electrode PotentialsIn electronics and electricity theory, a voltage is a measurement of the potential to do electrical work measured between two points in a circuit. Absolute measurements of potential (voltage) at a single point are meaningless, UNLESS, they are measured against some known reference.
In electricity, that reference is known as “ground”.
In electrochemistry, that reference is the standard hydrogen electrode (SHE).
A Standard Electrode potential, Eo, measures the tendency for the reduction process to occur at an electrode, when all species have unit activity (substances in solution are ~ 1.0 M or, if gases, are at 1 bar {~1 atm} pressure).
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Standard Hydrogen Electrode (SHE)aH2 = 1.0 ~ PH2 = 1.0 bar ~ 1.0 atm
aH3O+ = aH+ = 1.0 ~ [H+] = 1M
|| H+(aq) (1M) | H2(g) (1 atm) | Pt
2H+(aq) + 2e- H2(g) Eo = 0.00 V
frequently written as: EoH+(aq)/H2(g)
Easy to reduce, hard to oxidize (good oxidizing agents)
Hard to reduce, easy to oxidize (good reducing agents)
↑
↓
Standard Electrode (reduction) PotentialsThe potential of an electrochemical cell under standard conditions may be calculated by
Eocell = Eo
cathode – Eoanode
where the Eo’s are standard reduction potentials taken from a table.
The cathode is the electrode at which reduction occurs (electrons on left side of equation, oxidation state decreasing).
The anode is the electrode at which oxidation occurs (electrons on right side of equation, oxidation state increasing).
Also for a spontaneous reaction, Eocell > 0, as we will
see shortly.
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Example 21-2A new battery system currently under study for possible use in electric vehicles is the ZnCl2 battery.
Reaction: Zn(s) + Cl2(g) ZnCl2(aq)
What is the standard potential of the cell, Eo.Zn2+
(aq) + 2e- Zn(s) EoZn2+/Zn = -0.763V
Zn(s) Zn2+(aq) + 2e- Eo
Zn/Zn2+ = - EoZn2+/Zn = -(-0.763V) = +0.763 V
Cl2(g) + 2e- 2Cl-(aq) EoCl2/Cl- = + 1.358 V
Zn(s) + Cl2(g) ZnCl2(aq) Eocell = + 2.121 V
OR
Eocell = Eo
cathode – Eoanode = 1.358 – (- 0.763)V = 2.121 V
oxidation potential
Spontaneous change in a CellPreviously, it was said Ecell > 0 for a spontaneous reaction. Where did this come from?
Electrical work:
Welectrical = Q V Q = charge, V = voltage
If Q in coloumbs, V in volts, W in joulesRelated: P = iV {P = power i = current (charge/time), V = voltage}
If i - coloumbs/sec (Amp), V -volts, P- joules/sec = watts
In an electrochemical cell,
Q = n x F n = moles of electrons
F = charge/mole of electrons = Faraday
F = 96485 C/ mole of electrons
V = Ecell
Spontaneous change, cont’dWelectrical = Q V = nFEcell
This applies to a reversible process (implying that the reaction is carried out slowly enough that the system maintains equilibrium). Previously it was argued that the amount of work we can extract from a chemical process is equal –∆G (pg 796, Petrucci “Are You Wondering” box).
∆G = – Welectrical
∆G = – nFEcell ∆Go = – nFEocell
If Eocell > 0, ∆Go < 0 and the reaction is spontaneous
If Eocell < 0, ∆Go > 0 and reaction is nonspontaneous
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Behavior of Metals
Cu, Ag, Au,Hg
Li, Na, K (1A metals)Mg, Ca (2A metals)Al, ZnFe, Sn, Pb
Metals that will not dissolve
Metals that dissolve in dilute H+ to produce H2
Previously we said that experimental evidence shows the following:
Now we can better understand this:
M(s) Mn+(aq) + n e- oxidation
2 H+(aq) + 2 e- H2(g) reduction Eo = 0.00V
Eocell = Eo
cathode – Eoanode = 0 – Eo
M+/M
If EoM+/M < 0, Eo
cell > 0, the process is spontaneous.
If EoM+/M > 0, a stronger oxidizing agent than H+ is required
(i.e. HNO3, HClO4) .
Nernst EquationPreviously, we talked about standard electrode potentials in which everything was in its standard state.
Very rarely are things in standard state!
∆G = ∆Go + RT ln Q R = gas constantT = temperature (K)Q = reaction quotient
-nFEcell = -nFEocell + RT ln Q
Ecell = Eocell – RT/nF ln Q = Eo
cell – RT/ (2.303 nF) log Q
C= −o ocell cell
0.0592E E logQ, for T = 25n
Nernst Equation
Applications of the Nernst Equation
1) Draw the condensed cell diagram for the voltaic cell pictured at right.
2) Calculate the value of Ecell.
1) Pt|Fe2+(0.1M), Fe3+ (0.2M) || Ag+ (1.0M)|Ag(s)
2) The cell is in nonstandard conditions so we need to apply the Nernst equation - we will need to find Eo
cell , n, and Q.
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cont’dFrom table of Standard Reduction Potentials:
Fe3+ + e- Fe2+ EoFe3+/Fe2+ = 0.771 V
Ag+ + e- Ag EoAg+/Ag = 0.800 V
Overall reaction:
Cathode: Ag+ + e- Ag(s)
Anode: Fe2+ Fe3+ + e-
Ag+(aq) + Fe2+
(aq) Fe3+(aq) + Ag(s)
Eocell = Eo
cathode – Eoanode = Eo
Ag+/Ag – EoFe3+/Fe2+
= 0.800V – 0.771V = 0.029V
Q [Fe ][Fe ][Ag ]
3
2=+
+ +
What is Q ?
What is Eocell ?
after we combine
half-reactions, n = 1
Cont’d
+
+ +
= −
= =
ocell cell
3
2
0.0592E E log Qn
0.0592 [Fe ]= 0.029 V - log 1 [Fe ][Ag ]
(0.20M)0.029 V - 0.0592 log 0.011V(0.10M)(1.0M)
Example A: Calculate Ecell for the following cell
Al|Al3+(0.36M) || Sn4+ (0.086 M), Sn2+ (0.54 M) |PtAl3+ + 3e- Al Eo
Al3+/Al = -1.676 V
Sn4+ + 2e- Sn2+ EoSn4+/Sn2+ = 0.154 V
Cathode: Sn4+ + 2e- Sn2+
Anode: Al Al3+ + 3e-
x 3
x 2
cont’d
3 Sn4+(aq) + 2 Al(s) 3 Sn2+
(aq) + 2 Al3+(aq)
after we combine
half-reactions, n = 6
+ +
+=2 3 3 2
4 3[Sn ] [Al ]Q
[Sn ]
Eocell = Eo
cathode – Eoanode = Eo
Sn4+/Sn2+ – EoAl3+/Al
= 0.154 – (-1.676)V = 1.830V
+ +
+
= −
= =
ocell cell
2 3 3 2
4 3
3 2
3
0.0592E E log Qn
0.0592 [Sn ] [Al ]= 1.830 V - log 6 [Sn ]
0.0592 (0.54M) (0.36M)1.830 V - log 1.815V6 (0.086)
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Change in Ecell with Conditions
Zn(s) + Cu2+(aq) Zn2+
(aq) + Cu (s)
E E0.0592
n logQ = 1.103V0.0592
2 log[Zn ][Cu ] cell cell
o2+
2+= − −
Slope = -59/2 mV per decade change in log{[Zn2+]/[Cu2+]}
If we let cell reaction proceed, reaction shifts to right, [Zn2+] increases, [Cu2+] decreases and Ecelldecreases. When does it stop?
It stops at equilibrium, Ecell = 0.00V0.0 E 0.0592
nlogQcell
oeq= − Keq !!
K 10eq
nE0.0592
cello
=
We can calculate Keqfrom Eo values! For above reaction, Keq = 1.5 x1037
Concentration Cells
Both half-cells are the same chemical system, just different concentrations. The driving force (i.e. the EMF) is provided by the difference in concentrations.
Pt|H2 (g, 1.0 atm)| H+ (x M) || H+ (1 M) |H2(g,1.0 atm)|Pt(s)
Concentration Cell
Cathode: 2 H+ (1M) + 2e- H2(g)
Anode: H2(g) 2 H+ (xM) + 2e-
Eocell = Eo
cathode – Eoanode = 0.00 – 0.00 = 0.00V
( )
+
= − −
=− = − = −
2o anode
cell cell + 2cathode
2
2
[H ]0.0592 0.0592E E logQ =0.00V logn 2 [H ]
0.0592 X 0.0592 log 2logX 0.0592logX2 1 2
Since pH = -log X, Ecell = 0.0592 pH
This concentration cell behaves as a pH meter! Other concentration cells can be used to measure unknown concentrations of other species (i.e. potentiometry).
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Determination of Ksp (see Example 21-10)
Ag(s) | Ag+ (sat. AgI) || Ag+ (0.1M) |Ag(s)
From measured Ecell, determine Ksp.
Solution:
Set up Nernst equation with Ag+ (xM) at anode, 0.1M at cathode.
Solve Nernst equation to get x.
x = [Ag+] = S, [I-] = S
Ksp = S2
ElectrolysisThe use of an externally applied voltage to force an electrochemical reaction, even if it is naturally nonspontaneous.
Zn(s) + Cu2+(aq) Zn2+
(aq) + Cu(s) Eocell = + 1.10 V
Spontaneous!
What about the reverse process?Zn2+
(aq) + Cu(s) Zn(s) + Cu2+(aq) Eo
cell = - 1.10 VNonspontaneous!
But if we apply a potential > 1.10 V across the cell, we overcome the natural negative voltage, thus providing the driving force to make the reaction proceed.
Current is in opposite direction of voltaic, or galvanic, cell.
Galvanic and Electrolytic Cells
Galvanic Cell Electrolytic CellRegardless of the cell type, anode and cathode always defined by the process: oxidation at the anode, reduction at the cathode.
External energy External energy (voltage) source(voltage) sourceelectron flow reversed
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Zn/Cu2+ electrolysis example continued...
The amount of current that flows in the electrolytic cell tells us how much Zn has been produced or how much Cu2+ has dissolved.
Faraday’s Law of Electrolysis:
The number of moles of product formed in an electrolysis cell by an electric current is chemically equivalent to the number of moles of electrons supplied.
or Q = nF = it
charge (coulombs) moles of
electronscurrent (amperes)
time (seconds)
Note: 1 A = 1C/s Faradays constant = 96485 C /mole of e-
Example 21-12Electrodeposition of Cu can be used to determine Cu2+
content of sample.
Cathode: Cu2+ + 2 e- Cu(s)
Anode: 2H2O O2(g) + 4H+(aq) + 4e-
What mass of Cu is deposited in 1 hr if current = 1.62A?
Solution: Find moles of electrons, then find moles of Cu, then find mass of Cu.
Mole of e- = 1.62 A (C/s) x 3600 sec x 1/(96485 C/mole e-)
Mole of Cu = mole e- x 1 mole Cu / 2 mole e-
Mass Cu = moles Cu x 63.456 g Cu/mole Cu
Answer = 1.92 g of Cu deposited in 1 hour
Cont’dExample B: How long will it take to produce 2.62 L of O2(g)at 26.2oC and 738 mmHg at a Pt anode with a constant current of 2.13A?
Solution: Find moles of O2, then find moles of electrons, then find charge, then find time.
Mole of O2: nPVRT
738760 atm 2.62L
0.08206Latmmol K 299.35K1 1= =×
×− −
(recall anode reaction: 2H2O O2(g) + 4H+(aq) + 4e-)
Mole of electrons = moles of O2 x 4 mole electrons/ mole O2
Charge = moles of electrons x F (C/mole of electrons)
Time = Charge (C)/Current (C/s)
Answer = 18829 sec = 5.23 hr = 5 hr & 14min
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Chlor-Alkali ProcessElectrolysis of NaCl solutions
2 Cl-(aq) Cl2(g) + 2 e- anode -EoCl2/Cl- = -1.358 V
2 H2O + 2 e- H2(g) + 2 OH-(aq) cathode Eo
H2O/H2 = -0.828 V
2 H2O + 2 Cl-(aq) Cl2(g) + H2(g) + 2OH-(aq) Eo
cell = -2.19 V
- Cl2 produced at anode
- H2 and NaOH(aq) produced at cathode
- membrane allows Na+ movement
- 11% NaOH and 15% NaCl is concentrated, NaCl crystallized and removed
- final product, 50% NaOH (1% NaClimpurity), Cl2, H2
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