Naphthalene

Naphthalene is an organic compound with formula C
10
H
8
. It is the simplest polycyclic aromatic hydrocarbon, and is a white crystalline solid with a characteristic odor that is detectable at concentrations as low as 0.08 ppm by mass.[13] As an aromatic hydrocarbon, naphthalene's structure consists of a fused pair of benzene rings. It is best known as the main ingredient of traditional mothballs.

Naphthalene
Skeletal formula and numbering system of naphthalene
Ball-and-stick model of naphthalene
Names
Preferred IUPAC name
Naphthalene[1]
Systematic IUPAC name
Bicyclo[4.4.0]deca-1,3,5,7,9-pentaene
Other names
white tar, camphor tar, tar camphor, naphthalin, naphthaline, antimite, albocarbon, hexalene, mothballs, moth flakes
Identifiers
3D model (JSmol)
1421310
ChEBI
ChEMBL
ChemSpider
ECHA InfoCard 100.001.863
EC Number
  • 214-552-7
3347
KEGG
RTECS number
  • QJ0525000
UNII
Properties
C10H8
Molar mass 128.174 g·mol−1
Appearance White solid crystals/ flakes
Odor Strong odor of coal tar
Density 1.145 g/cm3 (15.5 °C)[2]
1.0253 g/cm3 (20 °C)[3]
0.9625 g/cm3 (100 °C)[2]
Melting point 78.2 °C (172.8 °F; 351.3 K)
80.26 °C (176.47 °F; 353.41 K)
at 760 mmHg[3]
Boiling point 217.97 °C (424.35 °F; 491.12 K)
at 760 mmHg[2][3]
19 mg/L (10 °C)
31.6 mg/L (25 °C)
43.9 mg/L (34.5 °C)
80.9 mg/L (50 °C)[3]
238.1 mg/L (73.4 °C)[4]
Solubility Soluble in alcohols, liquid ammonia, carboxylic acids, C6H6, SO2,[4] CCl4, CS2, toluene, aniline[5]
Solubility in ethanol 5 g/100 g (0 °C)
11.3 g/100 g (25 °C)
19.5 g/100 g (40 °C)
179 g/100 g (70 °C)[5]
Solubility in acetic acid 6.8 g/100 g (6.75 °C)
13.1 g/100 g (21.5 °C)
31.1 g/100 g (42.5 °C)
111 g/100 g (60 °C)[5]
Solubility in chloroform 19.5 g/100 g (0 °C)
35.5 g/100 g (25 °C)
49.5 g/100 g (40 °C)
87.2 g/100 g (70 °C)[5]
Solubility in hexane 5.5 g/100 g (0 °C)
17.5 g/100 g (25 °C)
30.8 g/100 g (40 °C)
78.8 g/100 g (70 °C)[5]
Solubility in butyric acid 13.6 g/100 g (6.75 °C)
22.1 g/100 g (21.5 °C)
131.6 g/100 g (60 °C)[5]
log P 3.34[3]
Vapor pressure 8.64 Pa (20 °C)
23.6 Pa (30 °C)
0.93 kPa (80 °C)[4]
2.5 kPa (100 °C)[6]
0.42438 L·atm/mol[3]
-91.9·10−6 cm3/mol
Thermal conductivity 98 kPa:
0.1219 W/m·K (372.22 K)
0.1174 W/m·K (400.22 K)
0.1152 W/m·K (418.37 K)
0.1052 W/m·K (479.72 K)[7]
1.5898[3]
Viscosity 0.964 cP (80 °C)
0.761 cP (100 °C)
0.217 cP (150 °C)[8]
Structure
Monoclinic[9]
P21/b[9]
C5
2h
[9]
a = 8.235 Å, b = 6.003 Å, c = 8.658 Å[9]
α = 90°, β = 122.92°, γ = 90°
Thermochemistry
165.72 J/mol·K[3]
167.39 J/mol·K[3][6]
Std enthalpy of
formation fH298)
78.53 kJ/mol[3]
201.585 kJ/mol[3]
Std enthalpy of
combustion cH298)
-5156.3 kJ/mol[3]
Hazards
Main hazards Flammable, sensitizer, possible carcinogen. Dust can form explosive mixtures with air
GHS pictograms [10]
GHS Signal word Danger
GHS hazard statements
H228, H302, H351, H410[10]
P210, P273, P281, P501[10]
NFPA 704 (fire diamond)
Flammability code 2: Must be moderately heated or exposed to relatively high ambient temperature before ignition can occur. Flash point between 38 and 93 °C (100 and 200 °F). E.g. diesel fuelHealth code 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g. chloroformReactivity code 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
2
2
0
Flash point 80 °C (176 °F; 353 K)[10]
525 °C (977 °F; 798 K)[10]
Explosive limits 5.9%[10]
10 ppm[3] (TWA), 15 ppm[3] (STEL)
Lethal dose or concentration (LD, LC):
1800 mg/kg (rat, oral)
490 mg/kg (rat, oral)
1200 mg/kg (guinea pig, oral)
533 mg/kg (mouse, oral)[11]
NIOSH (US health exposure limits):
PEL (Permissible)
TWA 10 ppm (50 mg/m3)[12]
REL (Recommended)
TWA 10 ppm (50 mg/m3) ST 15 ppm (75 mg/m3)[12]
IDLH (Immediate danger)
250 ppm[12]
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)
Infobox references

History

In the early 1820s, two separate reports described a white solid with a pungent odor derived from the distillation of coal tar. In 1821, John Kidd cited these two disclosures and then described many of this substance's properties and the means of its production. He 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).[14] Naphthalene's chemical formula was determined by Michael Faraday in 1826. The structure of two fused benzene rings was proposed by Emil Erlenmeyer in 1866,[15] and confirmed by Carl Gräbe three years later.[16]

Physical properties

A naphthalene molecule can be viewed as the fusion of a pair of benzene rings. (In organic chemistry, rings are fused if they share two or more atoms.) As such, naphthalene is classified as a benzenoid polycyclic aromatic hydrocarbon (PAH).

The eight carbons that are not shared by the two rings carry one hydrogen atom each. For purpose of the standard IUPAC nomenclature of derived compounds, those eight atoms are numbered 1 through 8 in sequence around the perimeter of the molecule, starting with a carbon adjacent to a shared one. The shared carbons are labeled 4a (between 4 and 5) and 8a (between 8 and 1).

Molecular geometry

The molecule is planar, like benzene. 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 1.37 Å (137 pm) in length, whereas the other carbon–carbon bonds are about 1.42 Å (142 pm) long. This difference, established by X-ray diffraction,[17] is consistent with the valence bond model in naphthalene and in particular, with the theorem of cross-conjugation. This theorem would describe naphthalene as an aromatic benzene unit bonded to a diene but not extensively conjugated to it (at least in the ground state), which is consistent with two of its three resonance structures.

Because of this resonance, the molecule has bilateral symmetry across the plane of the shared carbon pair, as well as across the plane that bisects bonds C2-C3 and C6-C7, and across the plane of the carbon atoms. Thus there are two sets of equivalent hydrogen atoms: the alpha positions, numbered 1, 4, 5, and 8, and the beta positions, 2, 3, 6, and 7. Two isomers are then possible for mono-substituted naphthalenes, corresponding to substitution at an alpha or beta position. Bicyclo[6.2.0]decapentaene is a structural isomer with a fused 4–8 ring system[18] and azulene is another, with a fused 5-7 ring system.

Bicyclo[6.2.0]decapentaene

The point group symmetry of naphthalene is D2h.

Electrical conductivity

Pure crystalline naphthalene is a moderate insulator at room temperature, with resistivity of about 1012 Ω m. The resistivity drops more than a thousandfold on melting, to about 4 × 108 Ω m. Both in the liquid and in the solid, the resistivity depends on temperature as ρ = ρ0 exp(E/(k T)), where ρ0 (Ω m) and E (eV) are constant parameters, k is Boltzmann's constant (8.617×10−5 eV/K), and T is absolute temperature (K). The parameter E is 0.73 in the solid. However, the solid shows semiconducting character below 100 K.[19][20]

Chemical properties

Reactions with electrophiles

In electrophilic aromatic substitution reactions, naphthalene reacts more readily than benzene. For example, chlorination and bromination of naphthalene proceeds without a catalyst to give 1-chloronaphthalene and 1-bromonaphthalene, respectively. Likewise, whereas both benzene and naphthalene can be alkylated using Friedel–Crafts reactions, naphthalene can also be easily alkylated by reaction with alkenes or alcohols, using sulfuric or phosphoric acid catalysts.

In terms of regiochemistry, electrophiles attack at 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 gives the "alpha" product naphthalene-1-sulfonic acid as the kinetic product but naphthalene-2-sulfonic acid as the thermodynamic product. The 1-isomer forms predominantly at 25 °C, and the 2-isomer at 160 °C. Sulfonation to give the 1- and 2-sulfonic acid occurs readily:

H
2
SO
4
+ C
10
H
8
C
10
H
7
−SO
3
H
+ H
2
O

Further sulfonation give di-, tri-, and tetrasulfonic acids.

Lithiation

Analogous to the synthesis of phenyllithium is the conversion of 1-bromonaphthalene to 1-lithionaphthalene, a lithium-halogen exchange:

C10H7Br + BuLi → C10H7Li + BuBr

The resulting lithionaphthalene undergoes a second lithiation, in contrast to the behavior of phenyllithium. These 1,8-dilithio derivatives are precursors to a host of peri-naphthalene derivatives.[21]

Reduction and oxidation

With alkali metals, naphthalene forms the dark blue-green radical anion salts such as sodium naphthalenide, Na+C10H
8
. The naphthalenide salts are strong reducing agents.

Naphthalene can be hydrogenated under high pressure in the presence of metal catalysts to give 1,2,3,4-tetrahydronaphthalene(C
10
H
12
), also known as tetralin. Further hydrogenation yields decahydronaphthalene or decalin (C
10
H
18
).

Oxidation with O
2
in the presence of vanadium pentoxide as catalyst gives phthalic anhydride:

C10H8 + 4.5 O2 → C6H4(CO)2O + 2 CO2 + 2 H2O

This reaction is the basis of the main use of naphthalene. Oxidation can also be effected using conventional stoichiometric chromate or permanganate reagents.

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. Although 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 twelve 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, undergoes fractional distillation to isolate naphthalene. The crude naphthalene resulting from this process is about 95% naphthalene by weight. The chief impurities are the sulfur-containing aromatic compound benzothiophene (< 2%), indane (0.2%), indene (< 2%), and methylnaphthalene (< 2%). Petroleum-derived naphthalene is usually purer than that derived from coal tar. Where required, crude naphthalene can be further purified by recrystallization from any of a variety of solvents, resulting in 99% naphthalene by weight, referred to as 80 °C (melting point). Approximately 1.3M tons are produced annually.[22]

In North America, the coal tar producers are Koppers Inc., Ruetgers Canada Inc. and Recochem Inc., and the primary petroleum producer is Monument Chemical Inc. In Western Europe the well-known producers are Koppers, Ruetgers, and Deza. In Eastern Europe, naphthalene is produced by a variety of integrated metallurgy complexes (Severstal, Evraz, Mechel, MMK) in Russia, dedicated naphthalene and phenol makers INKOR, Yenakievsky Metallurgy plant in Ukraine and ArcelorMittal Temirtau in Kazakhstan.

Other sources and occurrences

Aside from coal tar, trace amounts of naphthalene are produced by magnolias and some species of deer, as well as the Formosan subterranean termite, possibly produced by the termite as a repellant against "ants, poisonous fungi and nematode worms."[23] Some strains of the endophytic fungus Muscodor albus produce naphthalene among a range of volatile organic compounds, while Muscodor vitigenus produces naphthalene almost exclusively.[24]

Naphthalene in the interstellar medium

Naphthalene has been tentatively detected in the interstellar medium in the direction of the star Cernis 52 in the constellation Perseus.[25][26] More than 20% of the carbon in the universe may be associated with polyaromatic hydrocarbons, including naphthalene.[27]

Protonated cations of naphthalene (C
10
H+
9
) are the source of part of the spectrum of the Unidentified Infrared Emissions (UIRs). Protonated naphthalene differs from neutral naphthalene (e.g. that used in mothballs) in that it has an additional hydrogen atom. The UIRs from "naphthalene cation" (C
10
H+
9
) have been observed by astronomers. This research has been publicized as "mothballs in space."[28]

Uses

Naphthalene is used mainly as a precursor to other chemicals. The single largest use of naphthalene is the industrial production of phthalic anhydride, although more phthalic anhydride is made from o-xylene. Many azo dyes are produced from naphthalene, and so is the insecticide 1-naphthyl-N-methylcarbamate (carbaryl). Other useful agrichemicals include naphthoxyacetic acids.

Hydrogenation of naphthalene gives tetralin, which is used as a hydrogen-donor solvent.[22]

Naphthalenesulfonic acids and sulfonates

Many naphthalenesulfonic acids and sulfonates are useful. Alkyl naphthalene sulfonate are surfactants, The aminonaphthalenesulfonic acids, naphthalenes substituted with amines and 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 sulfonic acids are also used in the synthesis of 1-naphthol and 2-naphthol, precursors for various dyestuffs, pigments, rubber processing chemicals and other chemicals and pharmaceuticals.[22]

Naphthalene sulfonic acids are used in the manufacture of naphthalene sulfonate polymer plasticizers (dispersants), which are used to produce concrete and plasterboard (wallboard or drywall). They are also used as dispersants in synthetic and natural rubbers, and as tanning agents (syntans) in leather industries, agricultural formulations (dispersants for pesticides), dyes and as a dispersant in lead–acid battery plates.

Naphthalene sulfonate polymers are produced by treating naphthalenesulfonic acid with formaldehyde, followed by neutralization with sodium hydroxide or calcium hydroxide. These products are commercially sold as superplasticizers for the production of high strength concrete.

Laboratory uses

Molten naphthalene provides an excellent solubilizing medium for poorly soluble aromatic compounds. In many cases it is more efficient than other high-boiling solvents, such as dichlorobenzene, benzonitrile, nitrobenzene and durene. The reaction of C60 with anthracene is conveniently conducted in refluxing naphthalene to give the 1:1 Diels–Alder adduct.[29] The aromatization of hydroporphyrins has been achieved using a solution of DDQ in naphthalene.[30]

Wetting agent and surfactant

Alkyl naphthalene sulfonates (ANS) are used in many industrial applications as nondetergent wetting agents that effectively disperse colloidal systems in aqueous media. The major commercial applications are in the agricultural chemical industry, which uses ANS for wettable powder and wettable granular (dry-flowable) formulations, and the textile and fabric industry, which utilizes the wetting and defoaming properties of ANS for bleaching and dyeing operations.

As a fumigant

Naphthalene has been used as a household fumigant. It was once the primary ingredient in mothballs, although its use has largely been replaced in favor of alternatives such as 1,4-dichlorobenzene. 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 attack textiles. Other fumigant uses of naphthalene include use in soil as a fumigant pesticide, in attic spaces to repel animals and insects, and in museum storage-drawers and cupboards to protect the contents from attack by insect pests.

Naphthalene is a repellent to opossums.[31][32]

Other uses

It is used in pyrotechnic special effects such as the generation of black smoke and simulated explosions.[33] It is used to create artificial pores in the manufacture of high-porosity grinding wheels. In the past, naphthalene was administered orally to kill parasitic worms in livestock. Naphthalene and its alkyl homologs are the major constituents of creosote. Naphthalene is used in engineering to study heat transfer using mass sublimation.

Health effects

Exposure to large amounts of naphthalene may damage or destroy red blood cells, most commonly in people with the inherited condition known as glucose-6-phosphate dehydrogenase (G6PD) deficiency,[34] which over 400 million people suffer from. Humans, in particular children, have developed the condition known as hemolytic anemia, after ingesting mothballs or deodorant blocks containing naphthalene. Symptoms include fatigue, lack of appetite, restlessness, and pale skin. Exposure to large amounts of naphthalene may cause confusion, nausea, vomiting, diarrhea, blood in the urine, and jaundice (yellow coloration of the skin due to dysfunction of the liver).[35]

The US National Toxicology Program (NTP) held an experiment where male and female rats and mice were exposed to naphthalene vapors on weekdays for two years.[36] Both male and female rats exhibited evidence of carcinogenesis with increased incidences of adenoma and neuroblastoma of the nose. Female mice exhibited some evidence of carcinogenesis based on increased incidences of alveolar and bronchiolar adenomas of the lung, while male mice exhibited no evidence of carcinogenesis.

The International Agency for Research on Cancer (IARC)[37] classifies naphthalene as possibly carcinogenic to humans and animals (Group 2B). The IARC 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. Under California's Proposition 65, naphthalene is listed as "known to the State to cause cancer".[38] A probable mechanism for the carcinogenic effects of mothballs and some types of air fresheners containing naphthalene has been identified.[39][40]

Regulation

US government agencies have set occupational exposure limits to naphthalene exposure. The Occupational Safety and Health Administration has set a permissible exposure limit at 10 ppm (50 mg/m3) over an eight-hour time-weighted average. The National Institute for Occupational Safety and Health has set a recommended exposure limit at 10 ppm (50 mg/m3) over an eight-hour time-weighted average, as well as a short-term exposure limit at 15 ppm (75 mg/m3).[41]. Napthelene's minimum odor threshold is 0.084 ppm for humans.[42]

Mothballs and other products containing naphthalene have been banned within the EU since 2008.[43][44]

In China, the use of naphthalene in mothballs is forbidden.[45] Danger to human health and the common use of natural camphor are cited as reasons for the ban.

Naphthalene derivatives

The partial list of naphthalene derivatives includes the following compounds:

NameChemical formulaMolar mass [g/mol]Melting point [°C]Boiling point [°C]Density [g/cm3]Refractive index
1-Naphthoic acidC11H8O2172.18157300
1-Naphthoyl chlorideC11H7ClO190.6316–19190 (35 Torr)1.2651.6552
1-NaphtholC10H8O144,1794–962781.224
1-NaphthaldehydeC11H8O156,181–2160 (15 Torr)
1-NitronaphthaleneC10H7NO2173.1753–573401.22
1-FluoronaphthaleneC10H7F146.16−192151.3231.593
1-ChloronaphthaleneC10H7Cl162.62−62591.1941.632
2-ChloronaphthaleneC10H7Cl162.6259.52561.1381.643
1-BromonaphthaleneC10H7Br207.07−22791.4891.670
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See also

References

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  12. NIOSH Pocket Guide to Chemical Hazards. "#0439". National Institute for Occupational Safety and Health (NIOSH).
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  14. John Kidd (1821). "Observations on Naphthalene, a peculiar substance resembling a concrete essential oil, which is produced during the decomposition of coal tar, by exposure to a red heat". Philosophical Transactions. 111: 209–221. doi:10.1098/rstl.1821.0017.
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  16. C. Graebe (1869) "Ueber die Constitution des Naphthalins" (On the structure of naphthalene), Annalen der Chemie und Pharmacie, 149 : 20–28.
  17. Cruickshank, D. W. J.; Sparks, R. A. (18 October 1960). "Experimental and Theoretical Determinations of Bond Lengths in Naphthalene, Anthracene and Other Hydrocarbons". Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences. 258 (1293): 270–285. Bibcode:1960RSPSA.258..270C. doi:10.1098/rspa.1960.0187.
  18. Dieter Cremer; Thomas Schmidt; Charles W. Bock (1985). "Theoretical determination of molecular structure and conformation. 14. Is bicyclo[6.2.0]decapentaene aromatic or antiaromatic?". J. Org. Chem. 50 (15): 2684–2688. doi:10.1021/jo00215a018.
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  21. van Soolingen J., de Lang R. J., den Besten R., Klusener P. A. A., Veldman N., Spek A. L., Brandsma L. (1995). "A simple procedure for the preparation of 1,8-bis(diphenylphosphino)naphthalene". Synthetic Communications. 25: 1741–1744. doi:10.1080/00397919508015858.CS1 maint: multiple names: authors list (link)
  22. Gerd Collin, Hartmut Höke, Helmut Greim (2003). "Naphthalene and Hydronaphthalenes". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH.CS1 maint: uses authors parameter (link).
  23. "Termite 'mothball' keep insects at bay". Sci/Tech. BBC News. April 8, 1998.
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  25. "Interstellar Space Molecules That Help Form Basic Life Structures Identified". Science Daily. September 2008.
  26. Iglesias-Groth, S.; et al. (2008-09-20), "Evidence for the Naphthalene Cation in a Region of the Interstellar Medium with Anomalous Microwave Emission", The Astrophysical Journal Letters, 685 (1): L55–L58, arXiv:0809.0778, Bibcode:2008ApJ...685L..55I, doi:10.1086/592349 - This spectral assignment has not been independently confirmed, and is described by the authors as "tentative" (page L58).
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  30. M.A. Filatov; A.V. Cheprakov (2011). "The synthesis of new tetrabenzo- and tetranaphthoporphyrins via the addition reactions of 4,7-dihydroisoindole". Tetrahedron. 67 (19): 3559–3566. doi:10.1016/j.tet.2011.01.052.
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  33. Lu, Pei; Li, Caiting; Zeng, Guangming; Xie, Xuwen; Cai, Zhihong; Zhou, Yangxin; Zhao, Yapei; Zhan, Qi; Zeng, Zheng (2012-01-15). "Research on soot of black smoke from ceramic furnace flue gas: Characterization of soot". Journal of Hazardous Materials. 199–200: 272–281. doi:10.1016/j.jhazmat.2011.11.004. ISSN 0304-3894. PMID 22138172.
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