| 'Naphthalene' |
|---|
 Chemical structure of naphthalene
 Ball-and-stick model of naphthalene  Space-filling model of naphthalene |
| General | |
|---|---|
| Chemical name | Naphthalene |
| Other names | Tar Camphor, White Tar,
Moth Flakes |
| Chemical formula | C10H8 |
| SMILES | c1cccc2c1cccc2 |
| InChI | InChI=1/C10H8/c1-2-6-10-8-
4-3-7-9(10)5-1/h1-8H |
| Molar mass | 128.17052 g/mol |
| Appearance | White solid crystals/flakes,
strong odor of coal tar |
| CAS number | 91-20-3 |
| Properties |
|---|
| Density | 1.14 g/cm³ |
| Solubility in water | approximately 30mg/L |
| Melting point | 80.2 °C |
| Boiling point | 218 °C |
| Hazards |
|---|
| MSDS | External MSDS |
| Main hazards | Flammable, sensitizer, possible
carcinogen. Dust can form
explosive mixtures with air |
| NFPA 704 | |
| Flash point | 79 - 87 °C |
| Autoignition temperature | 525 °C |
| R/S statement | R: 22, 40, 50/53
S: 2, 36/37, 46, 60, 61 |
| RTECS number | QJ0525000 |
Except where noted otherwise, data are given for
materials in their standard state (at 25°C, 100 kPa)
|
'Naphthalene' (not to be confused with
naphtha) (also known as 'naphthalin', 'naphthaline', 'moth ball', 'tar camphor', 'white tar', or 'albocarbon'), is a crystalline,
aromatic, white, solid
hydrocarbon, best known as the primary ingredient of
mothballs. Naphthalene is volatile, forming a flammable
vapor. Its
molecules consist of two fused
benzene rings. It is manufactured from
coal tar, and converted to
phthalic anhydride for the manufacture of
plastics,
dyes and
solvents. It is also used as an
antiseptic and
insecticide, especially in mothballs.
''p''-Dichlorobenzene is now often used instead of naphthalene as a mothball substitute. Naphthalene easily
sublimates at room temperature.
History
In 1819-1820, at least two chemists reported a white solid with a pungent odor derived from the distillation of coal tar. In 1821,
John Kidd described many of this substance's properties and the means of its production, and proposed the name ''naphthaline'', as it had been derived from a kind of naphtha (a broad term encompassing any volatile, flammable liquid hydrocarbon mixture, including coal tar).
[1]
Naphthalene's melting point is 79 to 83 degrees Celsius and has a density of 1.14 g/cm³. Along with being highly flammable, naphthalene is harmful to self (
Xn) and to nature (
N).
Naphthaline's chemical formula, C
10H
8, was determined by
Michael Faraday in 1826. The structure of two fused benzene rings was proposed by
Emil Erlenmeyer in 1866, and confirmed by
Carl Graebe three years later.
Structure and reactivity
A naphthalene molecule is composed of two fused benzene rings. (In
organic chemistry, rings are ''fused'' if they share two or more atoms.) Accordingly, naphthalene is classified as a benzenoid
polyaromatic hydrocarbon (PAH). Naphthalene has three resonance structures, which are shown in the drawing below. Naphthalene has two sets of equivalent hydrogens. The ''alpha'' positions are positions 1, 4, 5, and 8 on the drawing below. The ''beta'' positions are positions 2, 3, 6, and 7.
Unlike
benzene, the carbon-carbon bonds in naphthalene are ''not'' of the same length. The bonds C1–C2, C3–C4, C5–C6 and C7–C8 are about 1.36 Å (136 pm) in length, whereas all the other carbon-carbon bonds are about 1.42 Å (142 pm) in length. This has been verified by
x-ray diffraction and can be expected from the
resonance structures, where the bonds C1–C2, C3–C4, C5–C6 and C7–C8 are double in ''two'' of the three structures, whereas all the others are double in only ''one''.
Resonace structures of naphthalene
Like benzene,naphthalene can undergo
electrophilic aromatic substitution. For many electrophilic aromatic substitution reactions, naphthalene is more reactive than benzene, and reacts under milder conditions than does benzene. For example, while both benzene and naphthalene react with
chlorine in the presence of a
ferric chloride or
aluminium chloride catalyst, naphthalene and chlorine can react to form 1-chloronaphthalene even without a catalyst. Similarly, while both benzene and naphthalene can be alkylated using
Friedel-Crafts reactions, naphthalene can also be alkylated by reaction with
alkenes or
alcohols, with
sulfuric or
phosphoric acid as the catalyst.
Mono-substitution of naphthalene has two possible
isomeric products, corresponding to substitution at an alpha or beta position, respectively. Usually, the major product has the electrophile in the alpha position. The selectivity for alpha over beta substitution can be rationalized in terms of the resonance structures of the intermediate: for the alpha substitution intermediate, seven resonance structures can be drawn, of which four preserve an aromatic ring. For beta substitution, the intermediate has only six resonance structures, and only two of these are aromatic. Sulfonation, however, gives a mixture of the "alpha" product 1-naphthalenesulfonic acid and the "beta" product 2-naphthalenesulfonic acid, with the ratio dependent on reaction conditions.
Naphthalene can be hydrogenated under high pressure or with a suitable catalyst to give 1,2,3,4-tetrahydronaphthalene, a solvent sold under the trade name
Tetralin. Further hydrogenation yields
decahydronaphthalene or Decalin (C
10H
18, also known as bicyclo[4.4.0]decane).
Oxidation of naphthalene with
chromate or
permanganate, or catalytic oxidation with O
2 and a
vanadium catalyst, gives
phthalic acid.
Production
Most naphthalene is derived from
coal tar. From the 1960s until the 1990s, significant amounts of naphthalene were also produced from heavy petroleum fractions during
petroleum refining, but today petroleum-derived naphthalene represents only a minor component of naphthalene production.
Naphthalene is the most abundant single component of coal tar. While the composition of coal tar varies with the coal from which it is produced, typical coal tar is about 10% naphthalene by weight. In industrial practice,
distillation of coal tar yields an oil containing about 50% naphthalene, along with a variety of other
aromatic compounds. This oil, after being washed with aqueous
sodium hydroxide to remove
acidic components, chiefly various
phenols, and with
sulfuric acid to remove
basic components, is
fractionally distilled to isolate naphthalene. The crude naphthalene resulting from this process is about 95% naphthalene by weight. The chief impurity is the sulfur-containing aromatic compound
benzothiophene. Petroleum-derived naphthalene is usually purer than that derived from coal tar. Where purer naphthalene is required, crude naphthalene can be further purified by
recrystallizing it from any of a variety of solvents.
Incidence in nature
Trace amounts of naphthalene are produced by
magnolias and specific types of
deer. Naphthalene has also been found in the
Formosan subterranean termite, possibly as a repellant against "ants, poisonous fungi and nematode worms."
[1]
Uses
Naphthalene's most familiar use is as a household
fumigant, such as in
mothballs. In a sealed container containing naphthalene pellets, naphthalene vapors build up to levels toxic to both the adult and larval forms of many
moths that are destructive to textiles. Other fumigant uses of naphthalene include use in soil as a fumigant pesticide, and in
attic spaces to repel animals.
In the past, naphthalene was administered orally to kill parasitic worms in livestock.
Larger volumes of naphthalene are used as a chemical intermediate to produce other chemicals. The single largest use of naphthalene is the industrial production of
phthalic anhydride, although more phthalic anhydride is made from
o-xylene than from naphthalene. Other naphthalene-derived chemicals include alkyl naphthalene sulfonate
surfactants, and the
insecticide carbaryl. Naphthalenes substituted with combinations of strongly electron-donating
functional groups, such as
alcohols and
amines, and strongly electron-withdrawing groups, especially
sulfonic acids, are intermediates in the preparation of many synthetic
dyes. The hydrogenated naphthalenes
tetrahydronaphthalene (Tetralin) and
decahydronaphthalene (Decalin) are used as low-volatility
solvents.
Naphthalene vapour can also slow the onset of
rust, such as the use of moth balls in a tool box.
Health effects
In
humans, exposure to large amounts of naphthalene may damage or destroy
red blood cells. This could cause the body to have too few red blood cells until it replaces the destroyed cells. Humans, particularly children, have developed this condition after ingesting mothballs or deodorant blocks containing naphthalene. Some of the symptoms of this condition are fatigue, lack of appetite, restlessness, and pale
skin. Exposure to large amounts of naphthalene may also cause
nausea, vomiting,
diarrhea,
blood in the
urine, and
jaundice (yellow coloration of the skin).
When the U.S. National Toxicology Program exposed male and female rats and mice to naphthalene vapors on weekdays for two years
[2], male and female rats exhibited: evidence of carcinogenic activity, based on increased incidences of adenoma and neuroblastoma of the nose, female mice exhibited some evidence of carcinogenic activity, based on increased incidences of alveolar and bronchiolar adenomas of the lung, and male mice exhibited no evidence of carcinogenic activity.
The International Agency for Research on Cancer (IARC)
[3] classifies naphthalene as possibly carcinogenic to humans [Group 2B]. It also points out that acute exposure causes cataracts in humans, rats, rabbits, and mice and, that
hemolytic anemia, described above, can occur in children and infants after oral or inhalation exposure or after maternal exposure during pregnancy.
Over 400 million people have an inherited condition called
glucose-6-phosphate dehydrogenase deficiency. For these people, exposure to naphthalene is harmful and may cause
hemolytic anemia, which causes their
erythrocytes to break down.
See also
★
Decahydronaphthalene (the fully saturated analog of naphthalene)
★
Naphthol
★ Classic Naphthalene synthesis: the
Wagner-Jauregg reaction
References
1. Obersvations on Naphthaline, a peculiar substance resembling a concrete essential oil, which is apparently produced during the decomposition of coal tar, by exposure to a red heat, John Kidd, , , Philosophical Transactions, 1821
2. NTP Technical Reports 410 and 500
3. IARC Monographs on the Evaluation of Carcinogenic Risks to Humans
External links
★
Naphthalene (PIM 363) - mostly on toxicity of naphthalene
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