1. Unit 12: Oxidation, Reduction, and Electrochemistry

2. Redox
REDuction – OXidation Reactions (AKA Redox): rxns that involve the _____________________________; both reduction and oxidation must happen ____________________!
Reduction = ___________________ by an atom or ion; __________ ___________ goes ________/____________
Oxidation = ___________________ by an atom or ion; __________ ___________ goes ________/_____________
Transfer of electrons
simultaneously
Gain of electrons
Oxidation
Number
Down
Reduces
Loss of electrons
Oxidation
Number up
increases

3. A way to remember → L E O the lion goes G E R
A way to remember → L E O the lion goes G E R *Oxidation and reduction happen because of the __________ for electrons in a chemical reaction. Species prefer to either ________ or _________ electrons in a chemical reaction. AND **Oxidation and reduction are __________ or __________________ reactions and one cannot happen without the other. If one atom _______ electrons, there must be another atom that will _______ electrons.
Lose e- oxidation
Gain e- reduction
desire
lose
gain
mutual
simultaneous
loses
gain

4. Green Chunk Experiment: http://www.sciencedojo.com/?p=184
Example:
___ Al + ___ CuCl2 → ___ ___________ ___ ______
Aluminum is above Cu on Table J so it will replace it! Notice how Al is all by itself (on left of arrow) with a zero charge and then bonded (on right of arrow) where it takes on a charge 2 3 2
AlCl3 3 Cu

5. IDENTIFYING REDOX REACTIONS
One way that we can begin to identify a redox reaction is to inspect the _________________________ from reactant to product side (for every element involved in the reaction). Oxidation numbers are used to track the __________________________ (electron transfer) from reactant to product side of rxn Oxidation Number (State) = ____________, ____________, OR ____________ (_______) values that can be assigned to atoms; identify how many electrons are being lost or gained by an atom/ion when they ____________________
Oxidation numbers
Movement of electrons
positive
negative
neutral
zero
Form bonds

6. *top listed # to the upper right is the most common oxidation number for that element
Trick 1: _________________________ reactions are always REDOX!
Example:
Zn + HCl → ___ _________ ___ _________
*___/___ are by themselves on one side and bonded on the opposite side
Trick 2: DOUBLE REPLACEMENT REACTIONS are NOT REDOX!
NaOH + HCl → ___ _________ ___ _________
*charges stay the same for all elements in the rxn
Single replacement reactions
ZnCl2 H2
Zn H
NaCl
HOH

7. Rules for assigning OXIDATION STATES (numbers):
1) _______________________________ (elements not bonded to another element) have an oxidation number of ________. This includes any formula that has only one chemical symbol in it (single elements & diatomic elements).
Examples: _______ _______ _______ _______
2) In ___________, the sum of the _________ for all elements must ____________________.
Ex: NaCl Ex: Mg3N Ex: HNO3
Na: 1(+1) = Mg: H:
Cl: 1(-1) = N: N:
0! O:
Uncombined elements
zero
Al(s)0 Na(s)0 Cl2(g)0 H2(g)0
compounds
charges
Add up to zero
3(+2) = +6
2(-3) = -6 0!

8. * The ________________________ is the number ___________ the _______________. It is the charge on _____ atom of that element! ** Trick: You can keep polyatomic ions together and use the charge from Table E to determine the oxidation numbers for those elements. *** Remember that we almost always write the __________________ and the ___________________ in a compound formula. EXAMPLE: EXCEPTION to this rule:
Oxidation number
inside
parentheses
one
(+) element first
(-) element last
HCl
NH3

9. 3) ___________________ always have a ___ oxidation number when in a compound (bonded to another species). ___________________ always have a ___ oxidation number when located within a compound. (Assign) Ox #: Ex: LiCl MgCl2 4) __________ is always a ___ in compounds. The other __________ (ex: Cl, Br, I) are also ___ as long as they are the most electronegative element in the compound. Ex: HF CaCl2 NaBr
Group 1 Metals +1
Group 2 Metals +2
Fluorine -1
Halogens -1

10. 5) _____________ is a ___ in compounds unless it is combined with __________ or __________________, in which case it is ___. (Assign) Ox #: Ex: HCl LiH 6) _____________ is ________________ in compounds. Ex: H2O
Hydrogen +1
Group 1
Group 2 Metal -1
Oxygen
Usually -2

11. When combined with ___________ (__), which is more electronegative, ___________________. (Assign) Ox #: Ex: OF2 When in a __________________________. A peroxide is a compound that has a formula of ________. Ex: Na2O2 H2O2
Fluorine F
Oxygen is +2
Peroxide, oxygen is -1
X2O2

12. 7) The sum of the oxidation numbers in polyatomic ions must equal the ___________________________ (_________________). Ex: Cr2O72- a Cr: 2( ) = O: 7( ) = = (charge on ion)
Charge on the ion
See table E +6
+12 -2
-14 -2

13. A reaction is REDOX if…___________________________ _________________________________________________ Reduction (GER) = ________________________ by an atom or ion; _________________________ goes _______/______________ Oxidation (LEO) = ________________________ by an atom or ion; _________________________ goes _______/______________
Oxidation numbers change for two elements within a reaction
Gain of electrons
Oxidation number
down
reduces
Loss of electrons
Oxidation number up
oxidizes

14. Assign oxidation numbers for all elements and complete the tables: Example 1: C + H2O → CO + H2 Example 2: MnO2 + 4HCl → MnCl2 + Cl2 + 2H2O
Charge: Increases/Decreases
e-: Lost/Gained
Oxidized/Reduced C0
H+1
increases
lost
oxidized
decreases
gained
reduced
Charge: Increases/Decreases
e-: Lost/Gained
Oxidized/Reduced
Cl-1
Mn+4
increases
lost
oxidized
decreases
gained
reduced

15. HALF REACTIONS
Half reactions allow us to show the _______________ in a redox rxn. For each redox reaction, we can illustrate two __________. One half-reaction shows ____________ and other shows ____________. Example of a Reduction Half Reaction: Fe3+ + 3e- → Fe *Electrons on left hand side, __________ in the rxn (____). Notice also how the charge for Fe goes down from left to right, ____________ (____). Charge goes down because Fe __________ e-.
Exchange of e-
Half rxns.
oxidation
reduction
gained
GER
reduction
GER
gained

16. Example of an Oxidation Half Reaction:
F e → Fe e-
*Electrons on left hand side, _________ in the rxn (____). Notice also how the charge for Fe goes up from left to right, _____________ (____). Charge goes up because Fe _______ e-.
NOTICE: Always _________________ to the side of rxn that has a _________________ (remember: electrons are ___________!)
FOLLOWING THE LAW OF CONSERVATION:
Half reactions follow the _____________________________. This means that there must be the _______________________ on both sides of the reaction arrow.
There must also be a _____________________________. In half reactions, the ____________________________________ of the equation, although it doesn’t necessarily need to equal zero.
lost
LEO
oxidation
LEO
lost
Add electrons
Higher total charge
negative
Law of conservation of mass
Same number of atoms
Conservation of charge
Net charge must be the same on both sides

17. RULES FOR SETTING UP HALF REACTIONS
1) Assign oxidation numbers to all elements in reaction 2) Draw brackets and identify oxidation & reduction 3) Begin to set up half reactions. Pull out brackets bringing element symbol and assigned charge with you. Set up as a reaction with arrow connecting two sides that have different oxidation numbers assigned. Only trick: diatomics must be pulled out as a pair. This is the only time you ever “bring subscripts with you” in creating half reactions! 4) FOR REACTIONS INVOLVING DIATOMIC ELEMENTS ONLY: Balance mass 1st (make sure there are the same number of elements on each side of each half reaction) 5) Lastly, balance charge in each half reaction by inserting appropriate amount of electrons into each half reaction to attain conservation of charge. Always add electrons to side that has a more positive charge. REMEMBER, electrons are negative in nature! Net charges on each side of rxn should be equal after adding electrons.

18. Assign oxidation numbers to all elements or polyatomic ions
Assign oxidation numbers to all elements or polyatomic ions. Label the brackets for reduction (red) or oxidation (ox). Ex. 1: Mg + ZnCl2 → MgCl2 + Zn OXIDATION Half Reaction: Mg0 → ______ + ______ REDUCTION Half Reaction: Zn+2 + ______ → ______
Mg+2
2e-
2e-
Zn0

19. Ex. 2 (balance masses): Hg + I2 → HgI OXIDATION Half Reaction (make sure to balance the masses ): ______ → ______ + ______ REDUCTION Half Reaction: ______ + ______ → ______
2 Hg0
2 Hg+1
2e-
I20
2 e-
2 I-

20. Ex. 3 (balance charges): Cu + AgNO3 → Cu(NO3)2 + Ag OXIDATION Half Reaction: ______ → ______ + ______ REDUCTION Half Reaction: ______ + ______ → ______ Now, we need to balance the charges: ___ x (Ag+1 + 1e- → Ag0) = ___Ag+1 + ___e- → ___Ag0
Cu0
Cu+2
2 e-
Ag+1
1 e-
Ag0 2 2 2 2

21. Table J and Spontaneous Reactions
General Rule: elements ___________ on Table J are ________ reactive than the elements below them
Spontaneous rxn = rxn occurs w/out adding energy to system
If the “single” element is more active than the “combined” element, the reaction will be spontaneous.
Non-spontaneous rxn = rxn will not occur unless energy is added to system
If the “single” element is less active than the “combined” element, the reaction will NOT be spontaneous.
higher
more

22. Complete the following equations by writing in the products formed or “no rxn” Ex 1: Zn + PbCl2 → Ex 2: Zn + BaO → Ex 3: Ca + CrF2 → Ex 4: Mn + NiS → Ex 5: Fe + MgI2 → Ex 6: Co + PbCl2 →
ZnCl2 + Pb0
No rxn
CaF2 + Cr0
MnS + Ni0
No rxn
CoCl2 + Pb0

23. TWO TYPES of ELECTROCHEMICAL CELLS
Voltaic (similar to a battery)
Electrolytic (similar to alternator in cars)
SIMILARITIES BETWEEN THE TWO:
Both involve ___________ reactions; chemical reactions which involve the flow of ______________
Both involve the flow of __________________, or __________, measured in _________
Both have ______________ (conductive surfaces where oxidation or reduction occurs); called the _________ and the _________
_______________ or _______________ occurs in each half cell
Redox
electrons
Electrical energy
current
volts
2 electrodes
anode
cathode
oxidation
reduction

24. RED CAT AN OX ______________________ ______________________
______________________ ______________________
(__________________) (__________________)
Electrons flow through the _______ from the _________ to the _________.
Reduction ALWAYS occurs
at the cathode
Oxidation ALWAYS occurs at the anode
Ions gain e-
Metal loses e-
wire
anode
cathode

25. Voltaic Cells
Cells that _____________________ convert _____________ energy into ________________ energy or electric _____________.
____________________
CATHODE
The ______________________ of the 2 metals (Table J)
_______________________________________ to it
the _____________ electrode in a ______________________
electrode where _______________ occurs (_____________)
ANODE
_______________________________________ to cathode
the ______________ electrode in a ______________________
spontaneously
chemical
electrical
current
batteries
Less active
Spontaneously attracts electrons
positive
Voltaic cell
reduction
RED CAT
More active
Spontaneously loses electrons
negative
Voltaic cell
oxidation
AN OX

26. Example 1: Wet Cell
______________, are a form of ______________ battery
Consists of LEAD ANODE and LEAD OXIDE CATHODE
Both electrodes immersed in a ________________ solution
Advantage: process is readily ____________ (by alternator)
Disadvantage: very ________, somewhat ______________
Example 2: Dry Cell
_______________________ are the type of batteries in a portable radio, remote control, etc.
CARBON (GRAPHITE) CATHODE surrounded by moist electrolyte paste
Usually ZINC ANODE
*SALT BRIDGE
provides a path for the _________________ between the half-cells
prevents the __________________________
Car batteries
Lead storage
Sulfuric acid
reversible
heavy
dangerous
Dry cell batteries
Flow of ions
Build-up of charge

27. Voltaic Cells (a.k.a Galvanic Cells)→
1. Use Table J to predict the direction that electrons will spontaneously
flow. Draw arrows to indicate the direction on the wire.
2. Based on your answer above, which would be the negative electrode and which would be the positive electrode? ____________________________________________________________
3. Explain your answer to #2. ____________________________________________________ ____________________________________________________________________________ ____________________________________________________________________________
Pb is negative electrode and Ag is positive electrode
Ag is gaining electrons and therefore reduced which is the cathode and +, Pb is losing electrons and therefore oxidized which is the anode and -.

28. 4. At which electrode or in which half-cell does reduction occur? _____
5. At which electrode or in which half-cell does oxidation occur? _____
6. Which electrode is the cathode? _____
7. Which electrode is the anode? _____
*Electrons don’t flow to the cathode, they flow through it to the ions in solution. That’s why the cathode never becomes negative 2 1 2 1

29. Electrolytic Cells nonspontaneous
Cells that use _________________ to force a ___________________ ____________________________ to occur.
This process is for __________________ and ___________________ Example: _________________________ (keeps the car battery replenished with energy)
Electrical energy
nonspontaneous
Chemical reaction
electrolysis
electroplating
Alternator in car

30. Electrolysis Experiment Animation (w/ tutorial):
Standard Hydrogen Electrode (Zinc)
Standard Hydrogen Electrode (Copper)

31. Electrolytic Cells CATHODE
electrode where _____________ are __________
the ________________ electrode (opposite of voltaic cell)
electrode where _______________ occurs (____________)
ANODE
electrode where _____________ are _______________________
NOTICE:
There is ___________________. This is a forced chemical reaction.
You will always see a _______________ hooked up to an electrolytic cell which drives the ____________________
electrons
sent
negative
reduction
RED CAT
electrons
Drawn away from
positive
oxidation
AN OX
No salt bridge
Power source
Forced rxn

32. Flow of e- (spontaneous or forced)
Compare and contrast the two types of electrochemical cells:
GALVANIC/VOLTAIC
ELECTROLYTIC
Flow of e- (spontaneous or forced)
(+) electrode
(-) electrode
*Direction of e- flow
Reduction ½ cell
Oxidation ½ cell
spontaneous
forced
cathode
anode
anode
cathode
Anode → cathode
Anode → cathode
Cathode
Cathode
anode
anode
*Direction of e- flow is either “Anode → Cathode” or “Cathode → Anode”

33. Nonspontaneous Reactions on Electrolytic Cells
Electroplating (see electroplating video)