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Draw The Condensed Structural Formula Of Hexane

Written By Thursday, 18 November 2021 Add Comment Edit

1.18 Structure and Nomenclature of Aromatic Compounds

Learning Objectives

  1. Recognize aromatic compounds from structural formulas.
  2. Name aromatic compounds given formulas.
  3. Write formulas for aromatic compounds given their names.

Historically, benzene-like substances were called aromatic hydrocarbons because they had distinctive aromas. Today, an aromatic compound is any compound that contains a benzene ring or has certain benzene-like properties (but not necessarily a strong aroma). You can recognize the aromatic compounds in this text by the presence of one or more benzene rings in their structure. Some representative aromatic compounds and their uses are listed in Table 1.9 "Some Representative Aromatic Compounds", where the benzene ring is represented as C6H5.

Table 1.9 Some Representative Aromatic Compounds

Name Structure Typical Uses
aniline C6H5–NH2 starting material for the synthesis of dyes, drugs, resins, varnishes, perfumes; solvent; vulcanizing rubber
benzoic acid C6H5–COOH food preservative; starting material for the synthesis of dyes and other organic compounds; curing of tobacco
bromobenzene C6H5–Br starting material for the synthesis of many other aromatic compounds; solvent; motor oil additive
nitrobenzene C6H5–NO2 starting material for the synthesis of aniline; solvent for cellulose nitrate; in soaps and shoe polish
phenol C6H5–OH disinfectant; starting material for the synthesis of resins, drugs, and other organic compounds
toluene C6H5–CH3 solvent; gasoline octane booster; starting material for the synthesis of benzoic acid, benzaldehyde, and many other organic compounds

Example 5

Which compounds are aromatic?

  1. 6-Carbon aromatic compound with a Chlorine radical.

  2. 6-Carbon cyclic compound with a double bond and a Chlorine radical attached to one Carbon at the right of one of the Carbon involved in the double bond.

  3. 6-Carbon aromatic compound with a propyl radical.

  4. 6-Carbon cyclic compound with a 1-ene-propyl radical.

Solution

  1. The compound has a benzene ring (with a chlorine atom substituted for one of the hydrogen atoms); it is aromatic.
  2. The compound is cyclic, but it does not have a benzene ring; it is not aromatic.
  3. The compound has a benzene ring (with a propyl group substituted for one of the hydrogen atoms); it is aromatic.
  4. The compound is cyclic, but it does not have a benzene ring; it is not aromatic.

Skill-Building Exercise

Which compounds are aromatic?

  1. 6-Carbon aromatic compound with a 2-ene-ethyl radical.

  2. 6-Carbon aromatic compound with two Chlorine radicals attached to Carbons 1 and 4.

  3. 6-Carbon cyclic compound with a two double bond Carbon-Carbon located in Carbons 1 and 4.

In the International Union of Pure and Applied Chemistry (IUPAC) system, aromatic hydrocarbons are named as derivatives of benzene. Figure 1.12 "Some Benzene Derivatives" shows four examples. In these structures, it is immaterial whether the single substituent is written at the top, side, or bottom of the ring: a hexagon is symmetrical, and therefore all positions are equivalent.

Figure 1.12 Some Benzene Derivatives

Aromatic compounds with substituents. The indicated name shows the presence of the substituent.

These compounds are named in the usual way with the group that replaces a hydrogen atom named as a substituent group: Cl as chloro, Br as bromo, I as iodo, NO2 as nitro, and CH3CH2 as ethyl.

Although some compounds are referred to exclusively by IUPAC names, some are more frequently denoted by common names, as is indicated in Table 1.9 "Some Representative Aromatic Compounds".

Aromatic compounds with substituents.

When there is more than one substituent, the corners of the hexagon are no longer equivalent, so we must designate the relative positions. There are three possible disubstituted benzenes, and we can use numbers to distinguish them (Figure 1.13 "The Three Isomeric Dichlorobenzenes"). We start numbering at the carbon atom to which one of the groups is attached and count toward the carbon atom that bears the other substituent group by the shortest path.

Figure 1.13 The Three Isomeric Dichlorobenzenes

Aromatic compounds with substituents. The indicated names show the presence of the substituent. The positions of the radical generate isomerism between these compounds.

In Figure 1.13 "The Three Isomeric Dichlorobenzenes", common names are also used: the prefix ortho (o-) for 1,2-disubstitution, meta (m-) for 1,3-disubstitution, and para (p-) for 1,4-disubstitution.

The substituent names are listed in alphabetical order. The first substituent is given the lowest number. When a common name is used, the carbon atom that bears the group responsible for the name is given the number 1:

Aromatic compounds with substituents. The indicated names show the presence of the substituent.

Example 6

Name each compound using both the common name and the IUPAC name.

  1. 6-Carbon aromatic cyclic compound with two Chlorine radicals on Carbons 1 and 2.

  2. 6-Carbon aromatic cyclic compound with a radical methyl attached to Carbon 1 and radical Bromine attached to Carbon 4.

  3. 6-Carbon aromatic cyclic compound with two NO2 groups attached to Carbons 1 and 3.

Solution

  1. The benzene ring has two chlorine atoms (dichloro) in the first and second positions. The compound is o-dichlorobenzene or 1,2-dichlorobenzene.
  2. The benzene ring has a methyl (CH3) group. The compound is therefore named as a derivative of toluene. The bromine atom is on the fourth carbon atom, counting from the methyl group. The compound is p-bromotoluene or 4-bromotoluene.
  3. The benzene ring has two nitro (NO2) groups in the first and third positions. It is m-dinitrobenzene or 1,3-dinitrobenzene.

Note

The nitro (NO2) group is a common substituent in aromatic compounds. Many nitro compounds are explosive, most notably 2,4,6-trinitrotoluene (TNT).

Formula of the explosive compound Trinitrotoluene (TNT).

Skill-Building Exercise

Name each compound using both the common name and the IUPAC name.

  1. 6-Carbon aromatic cyclic compound with two Bromine radicals on Carbons 1 and 2.

  2. 6-Carbon aromatic cyclic compound with NH2 and Bromine radicals on Carbons 1 and 2.

  3. 6-Carbon aromatic cyclic compound with two Chlorine radicals on Carbons 1 and 5 and a Bromine radical on Carbon 6.

Sometimes an aromatic group is found as a substituent bonded to a nonaromatic entity or to another aromatic ring. The group of atoms remaining when a hydrogen atom is removed from an aromatic compound is called an aryl group. The most common aryl group is derived from benzene (C6H6) by removing one hydrogen atom (C6H5) and is called a phenyl group, from pheno, an old name for benzene.

The aromatic compound can be found as substituent.

Polycyclic Aromatic Hydrocarbons

Some common aromatic hydrocarbons consist of fused benzene rings—rings that share a common side. These compounds are called polycyclic aromatic hydrocarbons (PAHs).

Examples of compounds formed by the fusion of aromatic benzene rings.

The three examples shown here are colorless, crystalline solids generally obtained from coal tar. Naphthalene has a pungent odor and is used in mothballs. Anthracene is used in the manufacture of certain dyes. Steroids, a large group of naturally occurring substances, contain the phenanthrene structure. (For more information about steroids, see Chapter 7 "Lipids", Section 7.4 "Steroids".)

To Your Health: Polycyclic Aromatic Hydrocarbons and Cancer

The intense heating required for distilling coal tar results in the formation of PAHs. For many years, it has been known that workers in coal-tar refineries are susceptible to a type of skin cancer known as tar cancer. Investigations have shown that a number of PAHs are carcinogens. One of the most active carcinogenic compounds, benzopyrene, occurs in coal tar and has also been isolated from cigarette smoke, automobile exhaust gases, and charcoal-broiled steaks. It is estimated that more than 1,000 t of benzopyrene are emitted into the air over the United States each year. Only a few milligrams of benzopyrene per kilogram of body weight are required to induce cancer in experimental animals.

Biologically Important Compounds with Benzene Rings

Substances containing the benzene ring are common in both animals and plants, although they are more abundant in the latter. Plants can synthesize the benzene ring from carbon dioxide, water, and inorganic materials. Animals cannot synthesize it, but they are dependent on certain aromatic compounds for survival and therefore must obtain them from food. Phenylalanine, tyrosine, and tryptophan (essential amino acids) and vitamins K, B2 (riboflavin), and B9 (folic acid) all contain the benzene ring. (For more information about vitamins, see Chapter 9 "Proteins, and Enzymes", Section 9.6 "Enzyme Cofactors and Vitamins".) Many important drugs, a few of which are shown in Table 1.10 "Some Drugs That Contain a Benzene Ring", also feature a benzene ring.

Note

So far we have studied only aromatic compounds with carbon-containing rings. However, many cyclic compounds have an element other than carbon atoms in the ring. These compounds, called heterocyclic compounds, are discussed in Chapter 5 "Amines and Amides", Section 5.3 "Amines as Bases". Some of these are heterocyclic aromatic compounds.

Table 1.10 Some Drugs That Contain a Benzene Ring

Name Structure
aspirin

Condensed formula of organic aromatic compounds with common use: Aspirin.

acetaminophen

Condensed formula of organic aromatic compounds with common use: Acetaminophen.

ibuprofen

Condensed formula of organic aromatic compounds with common use: ibuprofen.

amphetamine

Condensed formula of organic aromatic compounds with common use: amphetamine.

sulfanilamide

Condensed formula of organic aromatic compounds with common use: sulfanilamide.

Concept Review Exercises

  1. Briefly identify the important characteristics of an aromatic compound.

  2. What is meant by the prefixes meta, ortho, or para? Give the name and draw the structure for a compound that illustrates each.

  3. What is a phenyl group? Give the structure for 3-phenyloctane.

Answers

  1. An aromatic compound is any compound that contains a benzene ring or has certain benzene-like properties.

  2. meta = 1,3 disubstitution; (answers will vary)

    Aromatic 6-carbon cyclic compound with two groups NO2 in Carbons 1 and 3.

    ortho = 1,2 disubstitution

    Aromatic 6-carbon cyclic compound with two radicals Bromine in Carbons 1 and 2

    para = 1,4 disubstitution or 1-bromo-4-chlorobenzene

    Aromatic 6-carbon cyclic compound with one radical Bromine in Carbon 1 and one radical Chlorine in Carbons 4.

  3. phenyl group: C6H5 or

    6-carbon aromatic cyclic compound with a radical Methyl.

    3-phenyloctane:

    Twelve-carbon saturated hydrocarbon compound with a two-Carbon saturated radical on Carbon 3.

Key Takeaway

  • Aromatic compounds contain a benzene ring or have certain benzene-like properties; for our purposes, you can recognize aromatic compounds by the presence of one or more benzene rings in their structure.

Exercises

  1. Is each compound aromatic?

    a.Aromatic 6-carbon cyclic compound with one group NO2 in Carbon 1.

    b.Aromatic 6-carbon cyclic compound with one radical Bromine in Carbon 1.

  2. Is each compound aromatic?

    a.6-carbon cyclic compound with double bonds Carbon-Carbon at Carbons 1 and 3.

    b.Two 6-carbon cyclic ring compound.

  3. Draw the structure for each compound.

    a. toluene

    b. m-diethylbenzene

    c. 3,5-dinitrotoluene

  4. Draw the structure for each compound.

    a. p-dichlorobenzene

    b. naphthalene

    c. 1,2,4-trimethylbenzene

  5. Name each compound with its IUPAC name.

    a.Aromatic 6-carbon cyclic compound with one 2-Carbon saturated hydrocarbon radical attached to Carbon 1.

    b.Aromatic 6-carbon cyclic compound with one isopropyl radical attached to Carbon 1.

    c.Aromatic 6-carbon cyclic compound with one radical Methyl attached to Carbon 1 and one radical Bromine attached to Carbon 2.

    d.Aromatic 6-carbon cyclic compound with two Chlorine radicals attached to Carbons 1 and 3 and one radical Methyl attached to Carbon 5.

  6. Name each compound with its IUPAC name.

    a.Aromatic 6-carbon cyclic compound with one radical propyl attached to Carbon 1.

    b.Aromatic 6-carbon cyclic compound with two radicals Chlorine, one attached to Carbon 1 and the other one attached to Carbon 4 and, one radical methyl attached to Carbon 3.

    c.Aromatic 6-carbon cyclic compound with three radicals Bromine attached to Carbons 1, 3 and 5.

    d.A toluene compound with a group NO2 attached to Carbon 3.

Answers

1.

a. yes

b. no

3.

a.The formula of toluene compound.

b.Aromatic 6-carbon cyclic compound with two radicals ethyl, one attached to Carbon 1 and the other one attached to Carbon 3.

c.A toluene compound with two groups NO2 attached to Carbons 3 and 5.

5.

a. ethylbenzene

b. isopropylbenzene

c. o-bromotoluene

d. 3,5-dichlorotoluene

Draw The Condensed Structural Formula Of Hexane

Source: https://guides.hostos.cuny.edu/che120

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