Oxidation-Reduction Chemistry (“Redox” Chemistry)

 

I.                     What is “redox” chemistry?

a.      A redox reaction takes place when electrons are transferred from one atom or ion to another atom or ion.

b.      “Redox” is an abbreviation for “oxidation-reduction” chemistry. I guess it’s abbreviated as “redox’ because it’s faster than saying “oxidation-reduction” and easier than saying “ox-red”. J

c.      Redox chemistry is not new to you. We have seen redox reactions all year long. For instance, all single replacement reactions are redox reactions. However, we will be talking about these reactions in a new way in this chapter.

d.      Here is an example of a redox reaction that you have done in the laboratory this year:

ac003

+

Solid zinc metal, which has a silvery appearance

 

Copper (II) nitrate solution. Remember that copper solutions have a blue appearance.

Solid copper metal is produced. It is brownish orange, just like a penny. It is forming on the outside of the zinc metal at the bottom of the test tube. As the amount of solid copper that is formed increases, the amount of copper metal ions that are dissolved in the solution decreases. Eventually, the solution will become less blue, because the blue color of the solution is due to the presence of dissolved copper. The solid zinc metal, on the other hand, disappears as it dissolves.

Here is the chemical equation:

Zn (s)

+

Cu(NO3)2 (aq) 

Cu (s) + Zn(NO3)2 (aq)

Here is the net ionic equation:

Zn
Before

(reactant)

+

Cu2+               

Before (reactant)

Cu     +    Zn2+
Afterward

(products)

Zinc loses electrons, and its charge goes up from “0” (before) to “+2” (afterward)

 

The copper (II) ion gains electrons and its charge goes down from “+2” (before) to “0” (afterward)

↑     ↑
(Look at their
charges afterward!)

 

II.                   Who cares about redox chemistry?

a.      Redox chemistry occurs when electrons travel from one place to another in a chemical reaction. Why does this occur? Well, that’s like figuring out why some things fall down to the ground while other things don’t. Imagine a large object in the sky, like a parachutist dropped from an airplane. The person will fall down to the ground because that is a spontaneous process. On the other hand, a jet airplane weighing several tons can leave the ground and go into the sky when its engines are turned on because that is a spontaneous process.

b.      Water falls down a waterfall spontaneously, and the motion of the water can be used to turn a turbine, which is a device that turns the motion of the water into electricity. Similarly, electrons move from one chemical to another in a redox reaction; we can make the electrons do work for us as they move from one place to another.  A hydroelectric dam works by forcing the falling water to move through a turbine; a battery in your iPod works by forcing the electrons in a chemical reaction to move through wires as one chemical loses electrons to another chemical that “wants” the electrons more. (How do we know which way the electrons will flow – which chemical will lose electrons and which one will want to gain the electrons? We will answer this question later in the section on electrochemistry.)

c.      Therefore, one of the reasons that we care about redox chemistry is that understanding redox chemistry is the key to understanding electrochemistry, which is the conversion of chemical energy into electrical energy. Electrical energy is the energy due to the flow of electrons from one place to another. If you can understand that moving water (over a hydroelectric dam) can produce useful power for us, then you should realize that electrochemistry is just making use of moving electrons instead of moving water. In fact, the speed at which the electrons flow through a wire is described as current, just like a river that has lots of water moving through it is said to have a very high current.

III.                  Assigning oxidation numbers

a.      In order to identify a reaction as being a redox reaction, you have to see if anything is oxidized or reduced. The easiest way to do this is to look at the changes in the oxidation numbers of the elements in the reactions.

                                                              i.      The change in the oxidation number lets us know which substance is losing electrons, and which substance is gaining the electrons.

                                                            ii.      The oxidation number is basically the same thing as the “charge” of the element. (In case you care, it’s not quite the same thing. Oxidation numbers can have non-whole number values. Oxidation numbers can be assigned to the elements in a molecular compound, which by definition has no ions and therefore has no charges. But hey – don’t worry about this until AP Chemistry! J )

b.      Your textbook has a list of rules about how to assign oxidation numbers. Here is a quick summary:

                                                              i.      Any element that is not in a compound (i.e., it is “all by itself”) has an oxidation number of 0. Examples:

Element

Oxidation number

Cl2

0

O2

(the oxygen that you need to live)

0

O3

(this is ozone)

0

Al

0

Ca

0

Fe

0

 

                                                            ii.      Any monatomic ion has an oxidation number that is equal to its charge. Examples:

Ion

Oxidation number

Cl-1

-1

O2-

-2

Al3+

+3

Ca2+

+2

Fe2+

+2

Fe3+

+3

 

                                                          iii.      Oxygen is usually -2

                                                           iv.      Fluorine is -1

                                                             v.      H is usually +1

                                                           vi.      All oxidation numbers in a compound have to add up to 0 Examples:

Compound

Oxidation numbers

HCl

H = +1, Cl = -1

H2O

H = +1, O = -2

Al2O3

Al =+3, O =-2

CaF2

Ca =+2, F = -1

FeO

Fe =+2, O = -2

Fe2O3

Fe =+3, O = -2

CH4

C = -4, H = +1

CO2

C = +4, O = -2

 

                                                         vii.      All oxidation numbers in a polyatomic ion have to add up to the charge on the polyatomic ion. Examples:

Polyatomic Ion

Oxidation numbers

CO32-

C = +2, O = -2

SO42-

S = +6, O = -2

SO32-

S =+4, O =-2

O22-

O = -1

Hg22+

Hg = +1

ClO4-1

O = -2, Cl = +7

 

 

IV.               Identifying redox reactions

a.      The easiest way to identify redox reactions is to see how the oxidation numbers change as the reactants turn into products.

b.      Oxidation occurs when an element’s oxidation number goes up.

c.      Reduction occurs when an element’s oxidation number goes down.

d.      Example: Is the reaction below a redox reaction? If so, identify the substances that are oxidized and reduced.

e.      Example: Is the reaction below a redox reaction? If so, identify the substances that are oxidized and reduced.

f.        Example: Is the reaction below a redox reaction? If so, identify the substances that are oxidized and reduced.

g.      Example: Is the reaction below a redox reaction? If so, identify the substances that are oxidized and reduced.

h.      Example: Is the reaction below a redox reaction? If so, identify the substances that are oxidized and reduced.

i.        Notice that synthesis, decomposition, single replacement, and combustion must always be redox! Just look that the lone (uncombined) elements: they always have an oxidation number of 0 when they are alone, but are always something other than zero when they are in a compound. Thus their oxidation numbers change and the reaction must be redox.

j.         A helpful chart:

Oxidation

Reduction

An increase in oxidation number

A decrease in oxidation number

A loss of electrons

A gain of electrons

A gain of oxygen, usually

A loss of oxygen, usually

A loss of hydrogen, usually

A gain of hydrogen, usually

Figure 1. This is Leo the lion, and he goes "ger!" when he gets angry.

LEO goes GER!”

 

Lose Electrons Oxidation

 

Gain Electrons Reduction

 

V.                 Identifying the oxidizing agent and the reducing agent

a.      The substance that gets oxidized is the reducing agent.

b.      The substance that gets reduced is the oxidizing agent.

c.      In the example problems in the last section, identify the oxidizing agent and reducing agent.

Example IV.d) Zn is the reducing agent, S is the oxidizing agent

Example IV.e) Zn2+ is the oxidizing agent, S2- is the reducing agent

Example IV.f) Zn is the reducing agent, Cu2+  is the oxidizing agent

Example IV.g) C is the reducing agent, O is the oxidizing agent

Example IV.h) There is no redox reaction, so there are no oxidizing or reducing agents.

 

VI.               Oxidation and reduction always occur at the same time.

a.      If one substance loses electrons, then another substance must always gain electrons.

b.      Therefore, oxidation can never happen without reduction, and vice-versa.

VII.              * Balancing reactions using the half-reaction method