5 Steps to a 5 AP Chemistry

272  Step 4. Review the Knowledge You Need to Score High

All carbon atoms that are not part of the nine-atom main chain are branches. Branches

have -yl endings. It may help you to circle the carbon atoms belonging in the branches. In

the above example, there are three branches. Two consist of only one carbon and are called

methyl groups. The remaining branch has two carbons, so it is an ethyl group. The branches

are arranged alphabetically. If there is more than one of a particular type, use a prefix (di-, tri,

tetra-, etc.). The two methyl groups are designated dimethyl. The position of each branch is

indicated with a number already determined for the main chain. Each branch must get its own

number, even if it is identical to one already used.

In the above example this gives: 5-ethyl-2,2-dimethylnonane

a. ethyl before methyl (alphabetical—prefixes are ignored)

b. two methyl groups =dimethyl

c. three branches =three numbers

Numbers are separated from other numbers by commas, and numbers are separated

from letters by a hyphen.

Another type of isomerism is optical isomerism. These molecules are capable of rotat-

ing light to either the left or right and are said to be optically active. The presence of an

asymmetric or chiral carbon (a carbon atom with four different groups attached to it) will

make a compound optically active.

Common Functional Groups

If chemistry students had to learn the properties of each of the millions of organic

compounds, they would face an impossible task. Luckily, chemists find that having

certain arrangements of atoms in an organic molecule causes those molecules to react in a

similar fashion. For example, methyl alcohol, CH 3 -OH, and ethyl alcohol, CH 3 -CH 2 -OH,

undergo the same types of reactions. The −OH group is the reactive part of these

types of molecule. These reactive groups are called functional groups. Instead of learning

the properties of individual molecules, one can simply learn the properties of functional

groups.

In our study of the simple hydrocarbons, there are only two functional groups. One is a

carbon-to-carbon double bond. Hydrocarbons that contain a carbon-to-carbon double

bond are called alkenes. Naming alkenes is very similar to naming alkanes. The major difference

is that the carbon base has an -eneending instead of the -aneending. The carbon backbone of

the base hydrocarbon is numbered so the position of the double bond has the lowest location

number.

The other hydrocarbon functional group is a carbon-to-carbon triple bond.

Hydrocarbons that contain a triple bond are called alkynes. Alkynes use the -yneending on

the base hydrocarbon. The presence of a double or triple bond make these hydrocarbons

unsaturated.

The introduction of other atoms (N, O, Cl, etc.) to organic compounds gives rise to

many other functional groups. The major functional groups are shown in Table 18.2.

Macromolecules

As we mentioned in the introduction to this chapter, carbon has the ability to bond to

itself in long and complex chains. These large molecules, called macromolecules, may have