electrochemistry. oxidation- reduction iron ores are minerals with a high iron content. one of them...
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ELECTROCHEMISTRY
OXIDATION- REDUCTION
Iron ores are minerals with a high iron content. One of them hematite, Fe2O3 is chemically very similar to iron rust. The reaction which iron metal is produced from hematite in a blast furnace is described as:
Fe2O3(s) + 3CO(g) 2 Fe(l) + 3 CO2(g)
We can think of the CO(g) as taking O atoms away from Fe2O3 to produce CO2(g) and the free element iron. A commonly used term to describe a reaction in which a substance loses O atoms, is « reduction» and gains O atoms is «oxidation». An oxidation and reduction must always occur together, and the reaction in which they do is called an oxidation-reduction reaction.
Oxidation State (O.S) Changes
Fe2O3(s) + 3CO(g) 2 Fe(l) + 3 CO2(g)
The O.S of oxygen is -2 everywhere it appears. That of iron(shwon in red) changes. It decreases from + 3 in Fe2O3 to 0 in the free element, Fe. The O.S of carbon also changes. It increases from +2 in CO to +4 in CO2 . In terms of oxidation state changes, in an oxidation process the O.S of some element increases and in reduction the O.S of an element decreases.
+3 -2 +2 -2 0 +4-2
Identifying Oxidation- Reduction Reactions
Indicate whether each of the following is an oxidation-reduction reaction
a) MnO2(k) + 4 H+(aq) + 2 Cl-(aq) Mn2+
(aq) + 2 H2O(s) + Cl2(g)
b) H2PO4
-
(aq) + OH-
(aq) HPO42-
(aq) + H2O(s)
Solution:
a)The O.S of Mn in MnO2 decreases from +4 to +2 in Mn2+. MnO2 is reduced to Mn2+. The O.S of O remains --2 throughout the reaction, and that of H at +1. The O.S of Cl increases from -1 in Cl- to 0 in Cl2. Cl- is oxidized to Cl2 .The reaction is an oxidation-reduction reaction.
b) The O.S of H is +1 on both sides of the equation. The O.S of O remains -2 throughout the reaction. The O.S of phosphorus is +5 in both H2PO4
- and HPO42-. There are no
changes in O.S . This is not an oxidation-reduction reaction. It is infact an acid-base reaction.
The reaction illustrated below is an oxidation-reduction reaction
Zn(s) + Cu2+(aq) Zn2+(aq) + Cu(s)
We can show this by evaluating changes in the O.S states. But we may think of the reaction as involving two half-reactions occuring at the same time. The overall or net reaction is the sum of these two reactions:
Oxidation: Zn(k) Zn2+(aq) + 2e-
Reduction: Cu2+(aq) + 2e- Cu(k)
Net: Zn(k) + Cu2+(aq) Zn2+
(aq) + Cu(k)
In the half-equation the O.S of Zn increases from 0 to +2, corresponding to a loss of two electrons by each Zinc atom. In the second half-equation the O.S of Copper decreases from +2 to 0 corresponding to the gain of 2e- by each Cu2+
(aq) . To summarize;
Oxidation and Reduction Half reactions
Oxidation, is a process in which the O.S of some element increases, and in which electrons appear on the right in a half-equation
Reduction, is a process in which the O.S of some element decreases, and in which the electrons appear on the left in a half equation.
Oxidation and reduction half-reactions must always occur together, and the total number of electrons associated with the oxidation must equal to the total number associated with the reduction.
Oxidation and Reduction Half reactions
BALANCING OXIDATION- REDUCTION EQUATIONS
The same principles of equation balancing apply to oxidation-reduction (redox equations are balance for numbers of atoms and balance for electric charge.Several methods are possible but we emphasize the one described below:
The-Half reaction(Ion-Electron Method)
In this method of balancing a redox equation we:
write and balance seperate half-equations for oxidation and reduction.
adjust coefficients in the two-half equations so that the same number of electrons appears in each half equation
add together the two half-equations to obtain the balanced net equation.
• Example: Write the balanced equation for the reaction:
• SO32-
(aq) + MnO4-(aq) SO4
2-(aq) + Mn2+
(aq)
• Step 1.Write the «skeleton» half-equations based on the species undergoing oxidation and reduction. The O.S of sulfur increases from +4 in SO3
2- to +6 in SO42-. The O.S. Of Mn decreases from +7 in MnO4
- to +2 in Mn2+. The skeleton half-equations are:
SO32-
(aq) SO42-
(aq)
MnO4-(aq) Mn2+
(aq)
Step 2. Balance each half-equation atomically in this order
• Atoms other than H and O
• O atoms by adding H2O with the appropriate coefficient
• H atoms by adding H+ with the appropriate coefficient
• The other atoms( S and Mn) are already balanced in the skeleton half-equations. To balance O atoms we add one H2O molecule to the left of the first half-equation and four to the right of the second.
Balancing the Equation for a Redox Reaction in Acidic Solution
Balancing the Equation for a Redox Reaction Balancing the Equation for a Redox Reaction in Acidic Solutionin Acidic Solution
SO32-
(aq) + H2O(l) SO42-
(aq)
MnO4-(aq) Mn2+
(aq) + 4 H2O(l)
To balance H atoms we add two H+ to the right of the first half-equation and eight to the left of the second
SO32-
(aq) + H2O(l) SO42-
(aq) + 2H+(aq)
MnO4-(aq) + 8 H+
(aq) Mn2+(aq) + 4 H2O(l)
Step 3. Balance each half-equation electrically. Add the number of electrons necessary to get the same electric charge on both sides of each half equation.The half-equation in which the electrons appear on the right side is the oxidation half reaction. The other half equation with electrons on the left is the reduction half-equation.
Oxidation: SO32-
(aq) + H2O(l) SO42-
(aq) + 2H+(aq) + 2e-
(net charge on each side, -2)
Reduction: MnO4-(aq) + 8 H+
(aq) + 5e- Mn2+(aq) + 4 H2O(l)
(net charge on each side, +2)
Balancing the Equation for a Redox Reaction in Balancing the Equation for a Redox Reaction in Acidic SolutionAcidic Solution
Step 4. Obtain the net redox reaction by combining the half-equations. Multiply through the oxidation half-equation by 5 and through the reduction half-equation by 2. This results in 10 e- on each side of the net equation:
5 SO32-
(aq) + 5 H2O(l) 5 SO42-
(aq) + 10 H+(aq) + 10e-
2MnO4-(aq) + 16 H+
(aq) + 10e- 2 Mn2+(aq) + 8 H2O(l)
5 SO32-
(aq) + 2 MnO4-(aq) + 5 H2O(l) + 16 H+
(aq)
5 SO42-
(aq) + 2 Mn2+(aq) + 8 H2O(l) + 10 H+
(aq)
Step 5. Simplify. The net equation should not contain the same species on both sides. Subtract 5 H2O from each side of the equation in step 4. This leaves 3 H2O on the right. Also subtract 10 H+ from each side, leaving 6 on the left.
5 SO32-
(aq) + 2 MnO4-(aq) + 6 H+
(aq) 5 SO42-
(aq) + 2 Mn2+(aq) + 3 H2O(s)
Step 6. Verify. Check the final net equation to ensure that is balanced both atomically and electrically.e.g the net charge on each side of the equation is:
(5x2-) +(2 x 1-) + (6 x 1+) = (5 x 2-) + (2 x 2+) = -6.
Balancing the Equation for a Redox Balancing the Equation for a Redox Reaction in Basic SolutionReaction in Basic Solution
Balance the equation for the reaction in which chromate ion oxidizes sulfide ion in basic solution to produce free sulfur and chromium(III) hydroxide:CrO4
2- (aq) + S2-(aq) + OH- Cr(OH)3(s) + S(s) +H2O•Solution: Initially, we treat the half-reactions as if they occur in acidic solution, and then we adjust them for a basis solution: •STEP 1. write the two skeleton half-equations and balance them for Cr and S atoms• CrO4
2- (aq) Cr(OH)3(s)•S2-(aq) S(s)•STEP 2. Balance each half-equation for H and O atoms. Note that the second half-equation has no H or O atoms•CrO4
2- (aq) + 5 H+(aq) Cr(OH)3(s) + H2O•S2-(aq) S(s)
Balancing the Equation for a Redox Balancing the Equation for a Redox Reaction in Basic SolutionReaction in Basic Solution
STEP 3. Balance the half-equations for electric charge by adding the appropriate numbers of electronsReduction: CrO4
2- (aq) + 5 H+(aq) + 3 e- Cr(OH)3(s) + H2OOxidation: S2-(aq) S(s) + 2 e-
STEP 4. Change from an acidic to a basic medium by adding OH- ions and eliminating H+.The oxidation half equation is unaffected because it has no H+ ions. Add 5 OH- ions to each side of the reductionhalf equation; combine H+ and OH- into H2O; eliminate H2O from the right side of the half-equation. CrO4
2- (aq) + 5 H+(aq) + 5 OH- (aq) + 3 e- Cr(OH)3(s) + H2O + 5 OH- (aq) CrO4
2- (aq) + 5 H2O + 3 e- Cr(OH)3(s) + H2O + 5 OH- (aq) CrO4
2- (aq) + 4 H2O + 3 e- Cr(OH)3(s) + 5 OH- (aq)
Balancing the Equation for a Redox Balancing the Equation for a Redox Reaction in Basic SolutionReaction in Basic Solution
STEP 5. Combine the half-equations to obtain the net redox equation. (multiply the reduction half-equation by 2 and the oxidation half reaction by 3)
2 CrO42- (aq) + 8 H2O + 6 e- 2 Cr(OH)3(s) + 10 OH-
(aq)3 S2-(aq) 3 S(s) + 6 e-
2 CrO42- (aq) + 8 H2O + 3 S2-(aq) 2 Cr(OH)3(s) + 10
OH- (aq) + 3 S(s)
OXIDIZING AND REDUCING AGENTSOXIDIZING AND REDUCING AGENTSIn a redox reaction, the substance that makes it possible for some other substances to be oxidized is called oxidizing agent or oxidant. In doing so, the oxidizing agent is itself reduced. Similarly, the substance that causes some other substances to be reduced is called the reducing agent or reductant. In the reaction the reducing agent itself is oxidized.•An oxidizing agent(oxidant): •contains an element whose O.S. decreases in a redox reaction•«gains» electrons(electrons are found on the left side of the half-equation•A reducing agent(reductant):•contains an element whose O.S. increases in a redox reaction•«loses» electrons(electrons are found on the right side of the half-equation
OXIDIZING AND REDUCING AGENTSOXIDIZING AND REDUCING AGENTS
Example: Hydrogen peroxide, H2O2 is a versatile chemical. Its uses include bleaching wood pulp and fabrics and substituting for chlorine in water purification. One reason for its versatility is that it can be either an oxidizing or reducing agent. For the following reactions, identify whether hydrogenperoxide is an oxidizing or reducing agent.a) H2O2 + 2 Fe2+(aq) + 2 H+(aq) 2 H2O + 2 Fe3+
b) 5 H2O2(aq) + 2 MnO4- (aq) + 6 H+ 8 H2O +2 Mn2+
(aq) + 5 O2(g)Solution: a) Fe2+ is oxidized to Fe3+ and H2O2 makes it possible; H2O2 is an oxidizing agent. b) MnO4
- is reduced to Mn2+ and H2O2 makes this possible; H2O2
is a reducing agent
ELECTRODE POTENTIALS AND THEIR MEASUREMENT
Two kinds of interactions are possible between metal atoms on the electrode and metal ions in solution1.A metal ion Mn+ may collide with the electrode, gain n electrons and be converted to a metal atom M, the ion is reduced2.A metal atom M on the electrode may lose n electrons and enter the solution as the ion Mn+. The metal atom is oxidized.
ELECTRODE POTENTIALS AND THEIR MEASUREMENT
Electrode potential is a property proportional to the density of negative electric charge. To measure a difference in potential, we need to connect two half-cells in a special way. The flow of electric current is in the form of migration of ions from the greater negative charge to the other electrode.(here from Cu to Ag)
The net reaction that occurs as electric current flows through the electrochemical cell is:
ELECTRODE POTENTIALS AND THEIR MEASUREMENT
• The reading on the voltmeter is (0,463 V) significant. It is the potential difference between two half cells. Because this potential difference is the « driving force» for electrons, it is often called the electromotive force(emf) of the cell or the cell potential .
• Why does copper not displace Zn2+ from solution?• If we set up an electrochemical cell Zn(s) / Zn2+ half cell and Cu2+/Cu(s) half
cell, we find that electrons flow from the Zn to the Cu. The spontaneous net reaction in the electrochemical cell is
• Zn(s) + Cu2+(aq) Zn2+(aq) + Cu(s)• This is a spontaneous reaction and the reverse of this reaction does not occur
spontaneously.
Anode:Oxidation
Cathode:Reduction
Net
CELL DIAGRAMS CELL DIAGRAMS
CELL DIAGRAMSCELL DIAGRAMS
• A cell diagram shows the components of an electrochemical cell in a symbolic way. We will use the following conventions in writing cell diagrams:
• The anode, the electrode at which the oxidation occurs, is placed at the left side of the diagram
• The cathode, the electrode at which reduction occurs, is placed at the right side of the diagram.
• A boundary between different phases(e.g, an electrode and a solution) is represented by a single vertical line(/)(/)
• The boundary between half-cell components, usually a salt bridge, is represented by a double vertical line (//)
• The electrochemical cells which produce electricity as a result of chemical reactions are called voltaicvoltaic or galvanic cellsgalvanic cells
CELL DIAGRAMSCELL DIAGRAMS
Representing a Redox reaction Through a Cell Diagram-Aluminium metal displaces zinc(II) ion from aqueous solutiona)Write oxidation and reduction half equations and a net equation for this redox reactionb)Write a cell diagram for a voltaic cell in which this reaction occurs.Solution: a) The term « displaces» means the Aluminium goes into solution as Al3+ and Zn2+ comes out of the solution as zinc metal.
b) Al(s) is oxidized to Al3+ in the anode half-cell(left) and Zn2+ (aq) is reduced to Zn(s) in the cathode half-cell(right)
STANDARD ELECTRODE POTENTIALSTo do a calculation of cell voltages, we choose a particular half-cell to which we assign a potential of zero. We then compare other half cells to this reference. The commonly accepted reference is the standard hydrogen electrode
STANDARD ELECTRODE POTENTIALS
• Standard electrode potential, E˚, measures the tendency for a reduction process to occur at an electrode.
• To determine the value of E˚ for an electrode, we compare it with a standard hydrogen electrode(SHE). In the voltaic cell indicated below the measured potential difference is 0,337 V, with electrons flowing from H2 to the Cu electrode.
STANDARD ELECTRODE POTENTIALS
A standard cell potential, Ecell˚, is the potential difference or voltage of a cell formed from two standard electrodes. The net reaction that occurs in the voltaic cell is
The cell reaction indicates that Cu2+ (1M) is more easily reduced than is H+(1M). The standard electrode potential representing the reduction of Cu2+ (aq) to Cu(s) is assigned a positive value.
STANDARD ELECTRODE POTENTIALSWhen a standard hydrogen electrode is combined with a standard zinc electrode, electrons flow in the opposite direction, that is from the zinc to the hydrogen electrode.
In summary, the potential of the standard hydrogen electrode is set at 0.Any electrode at which a reduction half-reaction shows a greater tendency to occur than does the reduction of H+(1M) to H2(g) has a positive value for its reduction potential,E˚.
Any electrode at which a reduction half-reaction shows a lesser tendency to occur than does the reaction of H+(1M) to H2(g) has a negative value for its standard reduction potantial, E˚.The value of E˚ does not depend on the amount of substances involved. E˚ values are unaffected by multiplying half-equations by constant coefficients.
STANDARD ELECTRODE POTENTIALS
SOME STANDARD ELECTRODE(REDUCTION) POTENTIALS AT 25˚C
SOME STANDARD ELECTRODE(REDUCTION) POTENTIALS AT 25˚C
SOME STANDARD ELECTRODE(REDUCTION) POTENTIALS
AT 25˚C
A new battery system currently under study for possible use in electric vehicles is the zinc-chlorine battery. The net reaction producing electricity in this cell is
=ECd2+/Cd
Determining a Free Energy Change from A Cell Potential. Determine ΔG˚ for the reaction
n mol e- = electric current(ampere) x time(s) / 96485 C
For the reaction Cu2+(aq) + 2 e- Cu(s)
The mass of Cu accumulated on the electrode= n/2 x MA(atomic mass of Cu)
Our main criterion for spontaneous change is that ΔG<0 . However, according to the equation if ΔG< 0, then ΔG< 0 Ecell>0.If Ecell>0 , a reaction occurs spontaneously in the forward direction
If Ecell<0, the reaction occurs spontaneously in the reverse direction.
If Ecell=0, a reaction is at equilibrium.
If a cell reaction is reversed, Ecell changes sign
Making Qualitative Predictions with Electrode Potential Data
Solution
Because the E˚value for the reduction of S2O82-(aq)
is larger than that for the reduction of Cr2O72-(aq) ,
S2O82-(aq) should be the better oxidizing agent.
Example:
RELATIONSHIP BETWEEN Ecell˚ and Keq
R=8,314 Jmol-1K-1
at 25˚C
Example: What is the value of the equilibrium constant Keq for the reaction between copper metal and iron(III) ions in aqueous solution at 25˚C?
APPLICATION FIELDS OF Ecell˚ IN COMBINATION WITH Keq AND ΔG
ECELL AS A FUNCTION OF CONCENTRATION
NERNST EQUATION
Example : What is the value of Ecell for the voltaic cell pictured below?
Ecell= 0,011 V
Example: Will the cell reaction proceed spontaneously as written for the following cell?
Solution:
CONCENTRATION CELLS
aq
CONCENTRATION CELLS
Any voltaic cell in which the net cell reaction involves only a change in the concentration of some species( here H+) is called a concentration cell.A concentration cell consists of two half-cells with identical electrodes but different ion concentrations. Because the electrodes are identical, the standard half-cell potentials are numerically equal and opposite in sign. This makes Ecell=0. However, because the ion concentrations differ, there is a potential difference between the two half-cells. Spontaneous change in a concentration cell always occurs in the direction that produces a more dilute solution
CONCENTRATION CELLS
Constructing and using a hydrogen electrode is difficult. A better approach is to replace the SHE by a different reference electrode and the other hydrogen electrode by a glass electrode. A glass electrode is a thin glass membrane enclosing HCl(aq) and a silver wire coated with AgCl(s)The potential of the glass electrode depends on the hydrogen ion concentration of the solution being tested. The difference in potential between the glass electrode and the reference electrode is converted to a pH reading by the meter
BATTERIES:PRODUCING ELECTRICITY THROUGH CHEMICAL REACTIONS
A device that stores chemical energy for later release as electricity is called a batteryPrimary batteries: The cell reaction is not reversible. When the reactants have been mostly converted to products, no more electricity is produced and the battery is dead.Secondary batteries: The cell reaction can be reversed by passing electricity through the battery(charging). This means that a battery can be used several times by charging.Flow batteries: Materials(Reactants, products, electrolytes) pass through the battery, which is the conversion of chemical energy into electrical energy
LECLANCHE(DRY) CELLIn this cell oxidation occurs at a zinc anode and reduction at an inert carbon cathode. The electrolyte is a moist paste of MnO2, ZnCl2, NH4Cl and carbon black.
Oxidation: Zn(s) Zn2+(aq) +2 e-
Reduction: 2 MnO2(s) +H2O + 2e- Mn2O3(s) + 2 OH-(aq) An acid-base reaction occurs between NH4
+(aq) + OH-(aq) NH3(g) + H2O(l).The Leclanche cell is a primary cell. It is cheap to make, but it has some drawbacks. When current is rapidly drawn from the cell, products build up on the electrodes(e.g NH3) and this causes the voltage to drop. Also because the electrolyte medium is acidic, zinc metal slowly dissolves. In order to overcome this problem, an alkaline form of this battery can be produced . The advantage of the alkaline battery are that zinc does not dissolve in a base and the battery does a better job in maintaining the voltage.
LEAD-ACID STORAGE BATTERY
The most common secondary battery is the automobile storage battery (see below) . The electrodes are lead-antimony alloy. The anodes are impregnated with lead metal and the cathodes with red-brown leaddioxide. The electrolyte is dilute sulfuric acid. When the cell is allowed to discharge, following reactions occur:Oxidation: Pb(s) + SO4
2-(aq) PbSO4(s) + 2 e-
Reduction: PbO2(s) + 4 H+(aq) + SO42-(aq)+ 2 e- PbSO4(s) + 2
H2ONet: Pb(s) + PbO2(s)+ 4 H+(aq)+SO4
2-(aq) 2 PbSO4(s)+2 H2O
To recharge it,electrons are forced in the opposite direction by connecting the battery to an external electric source. The reverse of reactions occurs when the battery is recharged
BUTTON CELL BATTERIES
The cell-diagram of a silver-zinc cell isZn(s)/,ZnO(s)/ KOH(satd)/Ag2O(s),Ag(s)Oxidation: Zn(s) + 2 OH-(aq) ZnO(s) +H2O+ 2 e-
Reduction: Ag2O(s)+H2O+ 2 e- 2 Ag(s)+ 2 OH-(aq)Net: Zn(s) + Ag2O(s) ZnO(s) + 2 Ag(s)
Because no solution species is involved in the net reaction, the quantity of the electrode is very small, and the electrodes can be maintained very close together.
The storage capacity of a silver-zinc cell is about six times as great as a lead-acid cell of the same size.These batteries are used in watches, electronic calculators, hearing aids and cameras
FUEL CELLS
The essential process in a fuel cell is fuel+oxygen oxidation products. Applied to methan, a fuel cell can be obtained as the picture to the next.One of the simplest and most successful fuel cells involves the reaction between H2(g) and O2(g) to produce water.Oxidation: 2 H2(g) + 4 OH-
(aq) 4 H2O + 4 e-
Reduction: O2(g)+ 2 H2O+4 e-
4 OH-(aq)Net: 2 H2(g) + O2(g) 2 H2O (l)
FUEL CELLSAs long as fuel and O2 are available, the cell will produce electricity. It does not have the limited capacity of a primary battery, but neither does have the storage capacity of a secondary battery. Fuel cells have had their most notable successes as energy sources in space vehicles.A fuel cell reaction is often rated in terms of the efficiency value, ε= ΔG/ΔH. For the methane fuel cell ε= - 818/-890 = 0,92
Construction of a PEMFC(Proton Exchange Membrane Fuel Cell
AIR BATTERIES
Another kind of flow battery, because it uses oxygen from air, is known as air battery. The substance that is oxidized is typically a metal.One heavily studied battery system is the aluminium-air battery. In this battery oxidation occurs at an aluminium anode and reduction at a carbon-air cathode. The electrolyte circulated through the battery is NaOH(aq).The half reactions and the net reaction are:Oxidation: 4 { Al(s) + 4 OH-(aq) [Al(OH)4]-(aq) + 3 e-}Reduction: 3{O2(g) + 2 H2O + 4 e- 4 OH-(aq)Net: 4 Al(s) + 3 O2(g)+ 6 H2O + 4 OH-(aq) 4 [Al(OH)4]-(aq)Al-air batteries have one of the highest energy densities of the all bateries, but they are not widely used because of previous problems with cost,shelf life, start up time, by-product removal which have restricted their use to mainly military applications
CORROSION: UNWANTED VOLTAIC CELLS
Rust, the most familiar example of corrosion
Corrosion is the wearing away of metals due to a chemical reaction. If an iron nail is embedded in a gel of agar(acid-base indicator Phenolphtalein and the potassiumferricyanide) in water, it is observed that at the head and tip of the nail a deep blue precipitate forms. This shows us that oxidation occurs.Oxidation : 2 Fe(s) 2 Fe2+(aq) +4 e-
Reduction: O2+ 2 H2O+4 e- 4 OH- (aq)Some metals such as Aluminium form corrosion products that adhere tightly to the underlying metal and protect it from further corrosion. Iron oxide flakes off and constantly exposes fresh surface. The difference in corrosion behaviour explains why cans made of iron deteriorate rapidly in the environment, whereas aluminium cans have an almost unlimited lifetime. The simplest method of protecting a metal from corrosion is to cover it with a paint.
CORROSION PROTECTION
Another method of protecting an iron surface is to plate it with a thin layer of a second metal. iron can be plated with copper by electroplating or with tin by dipping the iron into the molten metal. In either case the underlying metal is protected only as long as the coating medium remains intact.When iron is coated with zinc(galvanized iron) the situation is different. Zinc is more active than iron . If a break occurs in the zink plating, the iron is still protected.Zinc is oxidized instead of iron.(see below)
CORROSION PROTECTION
a sacrifical anode protection in the hull of a ship
Cathodic protection is a technique is to control the corrosion of a metal surface by making the surface the cathode of an electrochemical cell. This is a useful protection method used with large iron and steel objects in contact with water,moist soils-ships,storage tanks, pipelines, etc.This involves connecting a chunk of magnesium, aluminium, zinc or some active metal to the object either directly through a wire. Oxidation occurs at the active metal. The iron behaves like a cathode and supports a reduction half-reaction. As long as some active metal remains, the iron is protected. The tive metal is called sacrificial anode.
ELECTROLYSIS:NONSPONTANEOUS CHEMICAL CHANGE
When the cell functions spontaneously, electrons flow from the zinc to the copper and the net chemical change in the voltaic cell is Zn(s) + Cu2+ Zn2+(aq) + Cu(s) Ecell= + 1,100 VNow suppose we connect the same cell to an external energy source of voltage greater than 1,100 V. That is the connection is made so that the electrons are forced into the zinc electrode(cathode) and removed from the copper electode(the anode)
Oxidation Cu(s) Cu2+(aq) - ECu2+
/Cu˚= - 0,337 VReduction Zn2+(aq) + 2 e- Zn(s) EZn
2+/Zn = - 0,763 V
Net Cu(s) + Zn2+(aq) Cu2+(aq)+ Zn(s) Ecell= - 1,100 V We conclude that when the cell reaction in a voltaic cell is reversed by reversing the direction of the electron flow , the voltaic cell is changed to an electrolytic cell.
QUANTITATIVE ASPECTS OF ELECTROLYSIS
Generally, we do not measure electric charge directly, we measure electric current. One ampere(A) of electric current represents the passage of 1 coulomb of charge per second (s).
1 mol e-= 96485 Cnumber of mol e- = current(C/s) x time(s) x 1 mol e-
96485 C