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Electrochemistry

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Title: Electrochemistry


1
Electrochemistry
  • Voltaic cell
  • Standard reduction potential
  • Electrochemical Series

2
Voltaic cell
3
  • Name Hamza Eid chemistry department
  • Title of Lesson Voltaic cell
  • Date of Lesson 18 26/3/ - 2007 
  • Length of Lesson 4- blocks
  • Description of Class Level 11 Advance Chemistry

4
Overview
  • This lesson allows students to learn how to
  • set up voltaic cells and explore the
  • electrochemistry that is involved. Students
  • will practice writing half reactions, learn to
  • designate the cathode and anode, and make
  • a reduction table.

5
Outcomes
  • Students will be able to
  • Setup, conduct, and explain voltaic cell
    reactions
  • Write equations for half-reactions and balanced
    full redox reactions
  • Identify the anode and cathode
  • Identify the type of reactions that occur at the
    anode and cathode

6
Teacher Does
  • Demo - How to set up a half-cell
  • The half cell consists of the oxidized and
    reduced form of an element or species.
  • In our case a solid metal and a solution of its
    ion. (i.e Zn and Zn2)
  • The half cell will be constructed in a 100 mL
    beaker with 50 mL of solution and a strip of the
    metal.
  • Two half cells are used to make a voltaic cell.
  •  

7
  • The voltaic cell needs a salt bridge connecting
    the two half cells.
  • Our salt bridge will consist of strips of paper
    soaked in a brine (saturated salt) solution.
  •   Two half cells can be connected via a wire.
    This experiment will simply use the wire that
    connects the cells to the voltammeter.

8
  • The voltammeter measurers the potential as
    electrons move through the cell. It will measure
    negative or positive flow depending on which way
    the wires are connected. Be sure to take positive
    measurements only.

9
Student Does
  • Students will be divided into groups of 3-4
  • Ask students, in groups (each group consist of
    3-members) to do the following activity (activity
    1) then each group demonstrates
  • How to set up an electrochemical cell using two
    metal /ion half-cells.
  • How they can identify the anode and the cathode
    in a cell

10
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11
Activity 2- Voltaic Cells Lab
  • Resources, materials and supplies needed
  • For each group (3-4 students)
  • 1 Voltammeter (able to read voltage below 1V)
  • 20 mL potassium chloride Solution
  • 10 - strips of filter paper
  • 6 - 100 mL beakers
  • 50 mL of each of the following 1M solutions
    ZnSO4, FeSO4, NiSO4, CuSO4, Ag2SO4, Al2(SO4)3
  • 1 - 2" long wire of each of the following wires
    Zn, Fe, Ni, Cu, Ag, Al

12
  • Supplementary materials, handouts
  • Lab Sheets
  • Discussion Questions

13
  • Students will be divided into groups of 3-4 and
    given a worksheet that outlines the procedure.
  • For each voltaic cell students will report the
    half reaction equations, the balanced full
    equation, the anode and the cathode, the sites of
    oxidation and reduction, the positive voltage.

14
Activity-3You can get electricity from a lemon.
  • Make two slits in the skin of a lemon and insert
    a piece of aluminum and a piece of copper in the
    other slit.

15
  • Make sure the two metals are not touching each
    other inside the lemon. If you touch your tongue
    to the two strips of metal you will feel a tingle
    of electricity.
  • The current flows because of the chemical
    reaction that takes place between the metals and
    acid in the lemon juice. The lemon juice acts in
    the same way as Volta's salt water or the
    chemical paste in a battery

16
  • Assessments

17
  • Examine the following combination of half -cells.
  • Cd(s)Cd2(aq) half cell combined with Ag
    (aq)Ag(s)
  • Pt(s) IO3-(aq), H(aq) half cell combined with
    Zn2(aq)Zn(s)
  • Pb(s)Pb2(aq) half cell combined with
    Ni2(aq)Ni(s)
  • C(s)ClO4-(aq), H(aq) , Cl- (aq) half cell
    combined with Fe3(aq)Fe(s)
  • C(s)SO42-(aq), H(aq),H2SO3(aq) half cell
    combined with Pt2(aq)Pt(s)

18
For each of the above create a sketch of the cell
similar to the following
19
Vocabulary
  • Battery - a cell that produces an electrical
    charge from a chemical reaction
  • Electrodes - conductors of an electrical charge
  • Current - a continuous flow of electrical charges
  • Voltage - potential difference in a chemical cell
    which produces current
  • Anode - negative electrode in a chemical cell
  • Cathode - positive electrode in a chemical cell

20
  • Standard electrode potentials

21
Outcomes
  • Define standard reduction potential and cell
    potential
  • Construct, and label the parts of a standard
    hydrogen electrode
  • predict the voltage (E ) of an electrochemical
    cell using the table of standard reduction
    half-cells

22
Teacher Does
  • Standard Reduction Potentials The tendency of a
    half reaction to occur as reduction under
    standard conditions
  • standard conditions
  • Temperature 25oC
  • concentrations of all ions 1 M
  • pressure of all at gases 1 atm)

23
  • To measure relative electrode potentials, we must
    establish an arbitrary standard.
  • That standard is the Standard Hydrogen Electrode
    (SHE).
  • The SHE is assigned an arbitrary voltage of
    0.000000 V
  • Hydrogen Half-Cell
  • reversible reaction

24
Hydrogen Electrode
  • The standard hydrogen electrode consists of a
    piece of platinum foil coated with fine particles
    of platinum.
  • It is immersed into a solution of hydrogen ions
    and hydrogen gas is bubbled over it.
  • .

25
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26
Cell Potential
  • the potential difference, in volts, between the
    electrodes of an electrochemical cell
  • positive value indicates a spontaneous reaction

27
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28
The Copper-SHE Cell
  • The cell components are
  • A Cu strip immersed in 1.0 M copper (II) sulfate.
  • The other electrode is a Standard Hydrogen
    Electrode.
  • A wire and a salt bridge to complete the circuit.
  • The initial cell voltage is 0.337 volts.

29
The Copper-SHE Cell
  • In this cell the SHE is the anode
  • The Cu2 ions oxidize H2 to H.
  • The Cu is the cathode.
  • The Cu2 ions are reduced to Cu metal.

30
The Zinc-SHE Cell
  • For this cell the components are
  • A Zn strip immersed in 1.0 M zinc (II) sulfate.
  • A wire and a salt bridge to complete the circuit.
  • The other electrode is the Standard Hydrogen
    Electrode.
  • The initial cell voltage is 0.763 volts.

31
The Zinc-SHE Cell
  • The cathode is the Standard Hydrogen Electrode.
  • In other words Zn reduces H to H2.
  • The anode is Zn metal.
  • Zn metal is oxidized to Zn2 ions.

32
  • In an electrochemical cell. we can think that in
    an electrode the following situation occurring
  • The better the reducing agent the more the
  • equilibrium lies over the right hand side.

33
Student Does
  • Ask students, in groups (each group consist of
    3-members) to do the following activity (activity
    2)
  • Each group demonstrate their observation.
  • Use the following work sheet

34
  • From the activity we conclude that
  • If we had used a voltmeter in the circuit we
    would find that the bigger voltage would be
    developed for Zn/Ag.
  • the second biggest by Zn /Cu
  • and the smallest by Cu/Ag.
  • So we can see that the voltage in a cell is
    governed the tendency of the metal ions to go
    into solution represented by the following
    equilibrium.

35
  • So by measuring the voltage (and the direction of
    flow of the electrons) in a series of cells we
    will be able to arrange oxidising and reducing
    agents in an electrochemical series.

36
  • The activity series of metals

37
Teacher does
  • electrochemical series a series of half
    reactions arranged in the ordering of their
    reducing ability.
  • The metals are arranged in the order of their
    reducing power.

38
  • With the most reactive metals at the top. A
    metal placed in solution can displace a metal ion
    of a metal below it in the reactivity series so
  • Zn(s) CuSO4(aq) ?ZnSO4(aq) Cu(s)
  • Will proceed

39
Teacher does - Activity-4
  • Ask students, in pairs, to design an
    investigation to determine the order of
    reactivity of the metals provided by constructing
    a potential difference chart

40
Activity -5
  • From Video 1
  • Ask how they could improve the design of their
    investigation.

41
Activity-6
  • Provide students with data of standard electrode
    potentials for a range of half-cells.
  • Do a worked example to show how to determine the
    direction of reaction for each half-cell, and how
    to write a balanced equation for the reaction and
    determine the standard cell potential by
    combining the two relevant standard electrode
    potentials.
  • Ask students to work in pairs and challenge each
    other to do the same with a different set of
    half-cells and check their partners answer

42
  • conclusions

43
Uses of Standard Electrode Potentials
  • Electrodes that force the SHE to act as an anode
    are assigned positive standard reduction
    potentials.
  • Electrodes that force the SHE to act as the
    cathode are assigned negative standard reduction
    potentials.
  • Standard electrode (reduction) potentials tell us
    the tendencies of half-reactions to occur as
    written

44
  • For example, the half-reaction for the standard
    potassium electrode is
  • The large negative value tells us that this
    reaction will occur only under extreme conditions

45
  • Compare the potassium half-reaction to fluorines
    half-reaction
  • The large positive value denotes that this
    reaction occurs readily as written.
  • Positive E0 values denote that the reaction tends
    to occur to the right.
  • The larger the value, the greater the tendency to
    occur to the right.
  • It is the opposite for negative values of Eo.

46
  • Uses of Standard Electrode Potentials

47
  • Use standard electrode potentials to predict
    whether an electrochemical reaction at standard
    state conditions will occur spontaneously.
  • Example 21-3 Will silver ions, Ag, oxidize
    metallic zinc to Zn2 ions, or will Zn2 ions
    oxidize metallic Ag to Ag ions?

48
  • Steps for obtaining the equation for
  • the spontaneous reaction.
  • Choose the appropriate half-reactions from a
    table of standard reduction potentials.
  • Write the equation for the half-reaction with the
    more positive E0 value first, along with its E0
    value.

49
  • Add the reduction and oxidation half-reactions
    and their potentials. This produces the equation
    for the reaction for which E0cell is positive,
    which indicates that the forward reaction is
    spontaneous

50
  • Write the equation for the other half-reaction as
    an oxidation with its oxidation potential, i.e.
    reverse the tabulated reduction half-reaction and
    change the sign of the tabulated E0.
  • Balance the electron transfer.

51
  • Example
  • Will silver ions, Ag, oxidize metallic zinc to
    Zn2 ions, or will Zn2 ions oxidize metallic Ag
    to Ag ions?

52
  • Example
  • Will permanganate ions, MnO4-, oxidize
  • iron (II) ions to iron (III) ions, or will iron
  • (III) ions oxidize manganese(II) ions to
  • permanganate ions in acidic solution?
  • Follow the steps outlined in the previous slides.
  • Note that E0 values are not multiplied by any
    stoichiometric relationships in this procedure.

53
  • Example
  • Will permanganate ions, MnO4-, oxidize iron (II)
  • ions to iron (III) ions, or will iron (III) ions
  • oxidize manganese(II) ions to permanganate ions
  • in acidic solution?
  • Thus permanganate ions will oxidize iron (II)
    ions to iron (III) and are reduced to manganese
    (II) ions in acidic solution.

54
  • Example
  • Will nitric acid, HNO3, oxidize arsenous acid,
  • H3AsO3, in acidic solution? The reduction
  • product of HNO3 is NO in this reaction.

55
Assessments
  • Standard reduction potential
  • Test traning

56
resourcesSuggested Website Recourse
  • http//www.chemguide.co.uk/inorganic/redoxmenu.htm
    ltop20
  • http//www.chem.iastate.edu/group/Greenbowe/sectio
    ns/projectfolder/flashfiles/electroChem/voltaicCel
    l20.html
  • http//www.chem.iastate.edu/group/Greenbowe/sectio
    ns/projectfolder/animations/SHZnV7.html

57
  • http//www.chem.iastate.edu/group/Greenbowe/sectio
    ns/projectfolder/animations/SHECu.html
  • http//www.wwnorton.com/chemistry/tutorials/ch1
    7.htm
  • http//www.chem.iastate.edu/group/Greenbowe/secti
    ons/projectfolder/flashfiles/electroChem/voltaicCe
    llEMF.html

58
  • http//www.wwnorton.com/chemistry/tutorials/ch17.h
    tm
  • http//www.chem.iastate.edu/group/Greenbowe/sectio
    ns/projectfolder/flashfiles/electroChem/electrolys
    is10.html
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