4.1: Naming Cycloalkanes

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Objectives

After completing this section, you should be able to

name a substituted or unsubstituted cycloalkane, given its Kekulé structure, shorthand structure or condensed structure.
draw the Kekulé, shorthand or condensed structure for a substituted or unsubstituted cycloalkane, given its IUPAC name.
draw all possible cycloalkane structures (substituted or unsubstituted) that correspond to a given molecular formula.

Study Notes

Provided that you have mastered the IUPAC system for naming alkanes, you should find that the nomenclature of cycloalkanes does not present any particular difficulties. Concentrate on the examples in which the substituent or substituents is or are an alkyl group, a halogen, or both.

Cycloalkanes are cyclic hydrocarbons, meaning that the carbons of the molecule are arranged in the form of a ring. Cycloalkanes are also saturated, meaning that all of the carbons atoms that make up the ring are single bonded to other atoms (no double or triple bonds). There are also polycyclic alkanes, which are molecules that contain two or more cycloalkanes that are joined, forming multiple rings.

Introduction

Many organic compounds found in nature or created in a laboratory contain rings of carbon atoms with distinguishing chemical properties; these compounds are known as cycloalkanes. Cycloalkanes only contain carbon-hydrogen bonds and carbon-carbon single bonds, but in cycloalkanes, the carbon atoms are joined in a ring. The smallest cycloalkane is cyclopropane.

Cyclopropane has a formula of CH2CH2CH2 and is triangle shaped. Cyclobutane has a formula of CH2CH2CH2CH2 and is square shaped. Cyclopentane has a formula of (CH2)5 and is shaped like a pentagon. Cyclohexane has a formula of (CH2)6 and is shaped like a hexagon.

Figure 4.1.1:

If you count the carbons and hydrogens, you will see that they no longer fit the general formula \(C_nH_{2n+2}\). By joining the carbon atoms in a ring,two hydrogen atoms have been lost. The general formula for a cycloalkane is \(C_nH_{2n}\). Cyclic compounds are not all flat molecules. All of the cycloalkanes, from cyclopentane upwards, exist as "puckered rings". Cyclohexane, for example, has a ring structure that looks like this:

Figure 4.1.2: This is known as the "chair" form of cyclohexane from its shape, which vaguely resembles a chair. Note: The cyclohexane molecule is constantly changing, with the atom on the left, which is currently pointing down, flipping up, and the atom on the right flipping down. During this process, another (slightly less stable) form of cyclohexane is formed known as the "boat" form. In this arrangement, both of these atoms are either pointing up or down at the same time

In addition to being saturated cyclic hydrocarbons, cycloalkanes may have multiple substituents or functional groups that further determine their unique chemical properties. The most common and useful cycloalkanes in organic chemistry are cyclopentane and cyclohexane, although other cycloalkanes varying in the number of carbons can be synthesized. Understanding cycloalkanes and their properties are crucial in that many of the biological processes that occur in most living things have cycloalkane-like structures.


Glucose (6 carbon sugar)	Ribose (5 carbon sugar)	Cholesterol (polycyclic)

Although polycyclic compounds are important, they are highly complex and typically have common names accepted by IUPAC. However, the common names do not generally follow the basic IUPAC nomenclature rules. The general formula of the cycloalkanes is \(C_nH_{2n}\) where \(n\) is the number of carbons. The naming of cycloalkanes follows a simple set of rules that are built upon the same basic steps in naming alkanes. Cyclic hydrocarbons have the prefix "cyclo-".

For simplicity, cycloalkane molecules can be drawn in the form of skeletal structures in which each intersection between two lines is assumed to have a carbon atom with its corresponding number of hydrogens.

Cyclohexane depicted as a hexagon with CH2 at each point of the hexagon. same as same as

Cycloalkane	Molecular Formula	Basic Structure
Cyclopropane	C₃H₆
Cyclobutane	C₄H₈
Cyclopentane	C₅H₁₀
Cyclohexane	C₆H₁₂
Cycloheptane	C₇H₁₄
Cyclooctane	C₈H₁₆
Cyclononane	C₉H₁₈
Cyclodecane	C₁₀H₂₀

IUPAC Rules for Nomenclature

Determine the cycloalkane to use as the parent chain. The parent chain is the one with the highest number of carbon atoms. If there are two cycloalkanes, use the cycloalkane with the higher number of carbons as the parent chain.
If there is an alkyl straight chain that has a greater number of carbons than the cycloalkane, then the alkyl chain must be used as the primary parent chain. Cycloalkane acting as a substituent to an alkyl chain has an ending "-yl" and, therefore, must be named as a cycloalkyl.

Cycloalkane	Cycloalkyl
cyclopropane	cyclopropyl
cyclobutane	cyclobutyl
cyclopentane	cyclopentyl
cyclohexane	cyclohexyl
cycloheptane	cycloheptyl
cyclooctane	cyclooctyl
cyclononane	cyclononanyl
cyclodecane	cyclodecanyl

Example 4.1.1

The longest straight chain contains 10 carbons, compared with cyclopropane, which only contains 3 carbons. Because cyclopropane is a substituent, it would be named a cyclopropyl-substituted alkane.

3) Determine any functional groups or other alkyl groups.

4) Number the carbons of the cycloalkane so that the carbons with functional groups or alkyl groups have the lowest possible number. A carbon with multiple substituents should have a lower number than a carbon with only one substituent or functional group. One way to make sure that the lowest number possible is assigned is to number the carbons so that when the numbers corresponding to the substituents are added, their sum is the lowest possible.

Chemical structure of 1-ethyl-3-methylcyclohexane. (1+3=4) NOT (1+5=6)

5) When naming the cycloalkane, the substituents and functional groups must be placed in alphabetical order.

(ex: 2-bromo-1-chloro-3-methylcyclopentane)

6) Indicate the carbon number with the functional group with the highest priority according to alphabetical order. A dash"-" must be placed between the numbers and the name of the substituent. After the carbon number and the dash, the name of the substituent can follow. When there is only one substituent on the parent chain, indicating the number of the carbon atoms with the substituent is not necessary.

(ex: 1-chlorocyclobutane or cholorocyclobutane is acceptable)

7) If there is more than one of the same functional group on one carbon, write the number of the carbon two, three, or four times, depending on how many of the same functional group is present on that carbon. The numbers must be separated by commas, and the name of the functional group that follows must be separated by a dash. When there are two of the same functional group, the name must have the prefix "di". When there are three of the same functional group, the name must have the prefix "tri". When there are four of the same functional group, the name must have the prefix "tetra". However, these prefixes cannot be used when determining the alphabetical priorities.

There must always be commas between the numbers and the dashes that are between the numbers and the names.

Example 4.1.2

(2-bromo-1,1-dimethylcyclohexane)

Notice that "f" of fluoro alphabetically precedes the "m" of methyl. Although "di" alphabetically precedes "f", it is not used in determining the alphabetical order.

Example 4.1.3

Cyclohexane with two methyl groups on the carbon labeled "1" and a fluorine on the carbon labeled "2".

(2-fluoro-1,1,-dimethylcyclohexane NOT 1,1-dimethyl-2-fluorocyclohexane)

8) If the substituents of the cycloalkane are related by the cis or trans configuration, then indicate the configuration by placing "cis-" or "trans-" in front of the name of the structure.

Blue=Carbon Yellow=Hydrogen Green=Chlorine

Notice that chlorine and the methyl group are both pointed in the same direction on the axis of the molecule; therefore, they are cis.

Cyclopentane with a chlorine on the carbon labeled "1" on a wedge and a methyl group on the carbon labeled "2" also on a wedge. cis-1-chloro-2-methylcyclopentane

9) After all the functional groups and substituents have been mentioned with their corresponding numbers, the name of the cycloalkane can follow.

Reactivity

Cycloalkanes are very similar to the alkanes in reactivity, except for the very small ones, especially cyclopropane. Cyclopropane is significantly more reactive than what is expected because of the bond angles in the ring. Normally, when carbon forms four single bonds, the bond angles are approximately 109.5°. In cyclopropane, the bond angles are 60°.

With the electron pairs this close together, there is a significant amount of repulsion between the bonding pairs joining the carbon atoms, making the bonds easier to break.

Alcohol Substituents on Cycloalkanes

Alcohol (-OH) substituents take the highest priority for carbon atom numbering in IUPAC nomenclature. The carbon atom with the alcohol substituent must be labeled as 1. Molecules containing an alcohol group have an ending "-ol", indicating the presence of an alcohol group. If there are two alcohol groups, the molecule will have a "di-" prefix before "-ol" (diol). If there are three alcohol groups, the molecule will have a "tri-" prefix before "-ol" (triol), etc.

Example 4.1.4

The alcohol substituent is given the lowest number even though the two methyl groups are on the same carbon atom and labeling 1 on that carbon atom would give the lowest possible numbers. Numbering the location of the alcohol substituent is unnecessary because the ending "-ol" indicates the presence of one alcohol group on carbon atom number 1.

Cyclohexane with a hydroxyl group on the carbon labeled "1" and two methyl groups on the carbon labeled "2".

2,2-dimethylcyclohexanol NOT 1,1-dimethyl-cyclohexane-2-ol

Example 4.1.5

Cyclopentane with a hydroxyl group on the carbon labeled "1", a methyl group on the carbon labeled "2", and a bromine on the carbon labeled "3".

3-bromo-2-methylcyclopentanol NOT 1-bromo-2-methyl-cyclopentane-2-ol

Example 4.1.6

Blue=Carbon Yellow=Hydrogen Red=Oxygen

trans-cyclohexane-1,2-diol

Other Substituents on Cycloalkanes

There are many other functional groups like alcohol, which are later covered in an organic chemistry course, and they determine the ending name of a molecule. The naming of these functional groups will be explained in depth later as their chemical properties are explained.

Name	Name ending
alkene	-ene
alkyne	-yne
alcohol	-ol
ether	-ether
nitrile	-nitrile
amine	-amine
aldehyde	-al
ketone	-one
carboxylic acid	-oic acid
ester	-oate
amide	-amide

Although alkynes determine the name ending of a molecule, alkyne as a substituent on a cycloalkane is not possible because alkynes are planar and would require that the carbon that is part of the ring form 5 bonds, giving the carbon atom a negative charge.

Cyclooctane with a carbon triple bonded to the first carbon. The triple bond is crossed out.

However, a cycloalkane with a triple bond-containing substituent is possible if the triple bond is not directly attached to the ring.

Example 4.1.7

Cyclooctane with a CCH group bound to the first carbon with a single bond.

ethynylcyclooctane

Example 4.1.8

Cyclohexane with a propyl group bound to the first carbon with a single bond.

1-propylcyclohexane

Summary

Determine the parent chain: the parent chain contains the most carbon atoms.
Number the substituents of the chain so that the sum of the numbers is the lowest possible.
Name the substituents and place them in alphabetical order.
If stereochemistry of the compound is shown, indicate the orientation as part of the nomenclature.
Cyclic hydrocarbons have the prefix "cyclo-" and have an "-alkane" ending unless there is an alcohol substituent present. When an alcohol substituent is present, the molecule has an "-ol" ending.

Glossary

alcohol: An oxygen and hydrogenOH hydroxyl group that is bonded to a substituted alkyl group.
alkyl: A structure that is formed when a hydrogen atom is removed from an alkane.
cyclic: Chemical compounds arranged in the form of a ring or a closed chain form.
cycloalkanes: Cyclic saturated hydrocarbons with a general formula of CnH(2n). Cycloalkanes are alkanes with carbon atoms attached in the form of a closed ring.
functional groups: An atom or groups of atoms that substitute for a hydrogen atom in an organic compound, giving the compound unique chemical properties and determining its reactivity.
hydrocarbon: A chemical compound containing only carbon and hydrogen atoms.
saturated: All of the atoms that make up a compound are single bonded to the other atoms, with no double or triple bonds.
skeletal structure: A simplified structure in which each intersection between two lines is assumed to have a carbon atom with its corresponding number of hydrogens.

Exercises

Exercise \(\PageIndex{1}\)

Give the IUPAC names for the following cycloalkane structures.

4.1.1.svg

Answer

a) 1,3-Dimethylcyclohexane

b) 2-Cyclopropylbutane

c) 1-Ethyl-3-methylcyclooctane

d) 1-Bromo-3-methylcyclobutane

e) 1,2,4-Triethylcycloheptane

f) 1-Chloro-2,4-dimethylcyclopentane

Exercise \(\PageIndex{2}\)

Draw the structures for the IUPAC names below.

2,3-dicyclopropylpentane
1,2,3-triethylcyclopentane
3-cyclobutyl-2-methylhexane
2-bromo-1-chloro-4-methylcyclohexane
1-bromo-5-propylcyclododecane

Answer

Outside links

More Practice Problems on Nomenclature of Cycloalkanes
Vollhardt, Schore. Organic Chemistry. 5th ed.
Wikipedia: Cycloalkanes
www.cem.msu.edu/~reusch/VirtualText/nomen1.htm
http://www.chemguide.co.uk/organicprops/alkanes/background.html
www.cem.msu.edu/~reusch/VirtualText/nomen1.htm
science.csustan.edu/nhuy/chem3010/handouts/HandoutIVNamecyal.htm
en.wikibooks.org/wiki/Organic_Chemistry/Alkanes_and_cycloalkanes/Cycloalkanes

References

ACD/ChemSketch Freeware, version 11.0, Advanced Chemistry Development, Inc., Toronto, ON, Canada, www.acdlabs.com, 2008.
Bruice, Paula Yurkanis. Oragnic Chemistry. 5th. CA. Prentice Hall, 2006.
Fryhle, C.B. and G. Solomons. Organic Chemistry. 9th ed. Danvers, MA: Wiley, 2008.
McMurry, John. Organic Chemistry. 7th ed. Belmont, California: Thomson Higher Education, 2008.
Sadava, Heller, Orians, Purves, Hillis. Life The Science of Biology. 8th ed. Sunderland, MA: W.H. Freeman, 2008.
Vollhardt, K. Peter C., and Neil E. Schore. Organic Chemistry. 5th ed. New York: W.H. Freeman, 2007.

Contributors and Attributions

Pwint Zin
Jim Clark (ChemGuide)
Dr. Dietmar Kennepohl FCIC (Professor of Chemistry, Athabasca University)
Prof. Steven Farmer (Sonoma State University)
Organic Chemistry With a Biological Emphasis by Tim Soderberg (University of Minnesota, Morris)