Thiophene

Thiophene
Names
Preferred IUPAC name
Thiophene
Other names
Thiofuran
Thiacyclopentadiene
Thiole
Identifiers
3D model (JSmol)
ChEBI
ChemSpider
ECHA InfoCard 100.003.392
RTECS number XM7350000
UNII
Properties
C4H4S
Molar mass 84.14 g/mol
Appearance colorless liquid
Density 1.051 g/mL, liquid
Melting point −38 °C (−36 °F; 235 K)
Boiling point 84 °C (183 °F; 357 K)
-57.38·10−6 cm3/mol
1.5287
Viscosity 0.8712 cP at 0.2 °C
0.6432 cP at 22.4 °C
Hazards
Safety data sheet External MSDS, External MSDS
not listed
NFPA 704
Flammability code 3: Liquids and solids that can be ignited under almost all ambient temperature conditions. Flash point between 23 and 38 °C (73 and 100 °F). E.g., gasoline) Health code 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g., chloroform Reactivity (yellow): no hazard code Special hazards (white): no codeNFPA 704 four-colored diamond
3
2
Flash point −1 °C (30 °F; 272 K)
Related compounds
Related thioethers
Tetrahydrothiophene
Diethyl sulfide
Related compounds
Furan
Pyrrole
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Infobox references

Thiophene, also commonly called thiofuran, is a heterocyclic compound with the formula C4H4S. Consisting of a flat five-membered ring, it is aromatic as indicated by its extensive substitution reactions. Related to thiophene are benzothiophene and dibenzothiophene, containing the thiophene ring fused with one and two benzene rings, respectively. Compounds analogous to thiophene include furan (C4H4O) and pyrrole (C4H4NH), which each vary by the heteroatom in the ring.

Isolation and occurrence

Thiophene was discovered as a contaminant in benzene.[1] It was observed that isatin (an indole) forms a blue dye if it is mixed with sulfuric acid and crude benzene. The formation of the blue indophenin had long been believed to be a reaction of benzene itself. Viktor Meyer was able to isolate thiophene as the actual substance responsible for this reaction.[2]

Thiophene and its derivatives occur in petroleum, sometimes in concentrations up to 1–3%. The thiophenic content of oil and coal is removed via the hydrodesulfurization (HDS) process. In HDS, the liquid or gaseous feed is passed over a form of molybdenum disulfide catalyst under a pressure of H2. Thiophenes undergo hydrogenolysis to form hydrocarbons and hydrogen sulfide. Thus, thiophene itself is converted to butane and H2S. More prevalent and more problematic in petroleum are benzothiophene and dibenzothiophene.

Synthesis and production

Reflecting their high stabilities, thiophenes arise from many reactions involving sulfur sources and hydrocarbons, especially unsaturated ones, e.g. acetylenes and elemental sulfur, which was the first synthesis of thiophene by Meyer the same year that he reported its discovery. Thiophenes are classically prepared by the reaction of 1,4-diketones, diesters, or dicarboxylates with sulfidizing reagents such as P4S10 such as in the Paal-Knorr thiophene synthesis. Specialized thiophenes can be synthesized similarly using Lawesson's reagent as the sulfidizing agent, or via the Gewald reaction, which involves the condensation of two esters in the presence of elemental sulfur. Another method is the Volhard–Erdmann cyclization.

Thiophene is produced on a scale of around 2,000,000 kilograms per year worldwide. Production involves the vapor phase reaction of a sulfur source, typically carbon disulfide, and butanol. These reagents are contacted with an oxide catalyst at 500–550 °C.[3]

Properties

At room temperature, thiophene is a colorless liquid with a mildly pleasant odor reminiscent of benzene, with which thiophene shares some similarities. The high reactivity of thiophene toward sulfonation is the basis for the separation of thiophene from benzene, which are difficult to separate by distillation due to their similar boiling points (4 °C difference at ambient pressure). Like benzene, thiophene forms an azeotrope with ethanol.

The molecule is flat; the bond angle at the sulphur is around 93°, the C–C–S angle is around 109°, and the other two carbons have a bond angle around 114°. The C–C bonds to the carbons adjacent to the sulphur are about 1.34 Å, the C–S bond length is around 1.70 Å, and the other C–C bond is about 1.41 Å (figures from the Cambridge Structural Database).

Reactivity

Thiophene is considered to be aromatic, although theoretical calculations suggest that the degree of aromaticity is less than that of benzene. The "electron pairs" on sulfur are significantly delocalized in the pi electron system. As a consequence of its aromaticity, thiophene does not exhibit the properties seen for conventional thioethers. For example, the sulfur atom resists alkylation and oxidation. However, oxidation of a thiophene ring is thought to play a crucial role in the metabolic activation of various thiophene-containing drugs, such as tienilic acid and the investigational anticancer drug OSI-930. In these cases oxidation can occur both at sulfur, giving a thiophene S-oxide, as well as at the 2,3-double bond, giving the thiophene 2,3-epoxide, followed by subsequent NIH shift rearrangement.[4][5][6][7][8] Oxidation of thiophene by trifluoroperacetic acid also demonstrates both reaction pathways. The major pathway forms the S-oxide as an intermediate, which undergoes subsequent Diels-Alder-type dimerisation and further oxidation, forming a mixture of sulfoxide and sulfone products with a combined yield of 83% (based on NMR evidence):[9][10]

In the minor reaction pathway, a Prilezhaev epoxidation[11] results in the formation of thiophene-2,3-epoxide that rapidly rearranges to the isomer thiophene-2-one.[9] Trapping experiments[12] demonstrate that this pathway is not a side reaction from the S-oxide intermediate, while isotopic labeling with deuterium confirm that a 1,2-hydride shift occurs and thus that a cationic intermediate is involved.[9] Trifluoroperacetic acid is prepared immediately prior to use, and the method chosen determines whether or not water is present;[10][13][14] if the reaction mixture is not anhydrous, this minor reaction pathway is suppressed as water acts as a competing base.[9]

Toward electrophiles

Although the sulfur atom is relatively unreactive, the flanking carbon centers, the 2- and 5-positions, are highly susceptible to attack by electrophiles. Halogens give initially 2-halo derivatives followed by 2,5-dihalothiophenes; perhalogenation is easily accomplished to give C4X4S (X = Cl, Br, I).[15] Thiophene brominates 107 times faster than does benzene.[3]

Chloromethylation and chloroethylation occur readily at the 2,5-positions. Reduction of the chloromethyl product gives 2-methylthiophene. Hydrolysis followed by dehydration of the chloroethyl species gives 2-vinylthiophene.[16][17]

Desulfurization by Raney nickel

Desulfurization of thiophene with Raney nickel affords butane. When coupled with the easy 2,5-difunctionalization of thiophene, desulfurization provides a route to 1,4-disubstituted butanes.

Coordination chemistry

Thiophene exhibits little thioether-like character, but it does serve as a pi-ligand forming piano stool complexes such as Cr(η5-C4H4S)(CO)3.[18]

Thienyl

Upon deprotonation, thiophene converts to the thienyl group, C4H3S. Although the anion per se do not exist, the organolithium derivatives do. Thus reaction of thiophene with butyl lithium gives 2-lithiothiophene, also called 2-thienyllithium. This reagent reacts with electrophiles to give thienyl derivatives, such as the thiol.[19] Oxidation of thienyllithium gives 2,2'-dithienyl, (C4H3)2. Thienyl lithium is employed in the preparation of higher order mixed cuprates.[20]

Uses

Thiophenes are important heterocyclic compounds that are widely used as building blocks in many agrochemicals and pharmaceuticals.[3] The benzene ring of a biologically active compound may often be replaced by a thiophene without loss of activity.[21] This is seen in examples such as the NSAID lornoxicam, the thiophene analog of piroxicam.

Polythiophene

The polymer formed by linking thiophene through its 2,5 positions is called polythiophene. Polythiophene itself has poor processing properties. More useful are polymers derived from thiophenes substituted at the 3- and 3- and 4- positions. Polythiophenes become electrically conductive upon partial oxidation, i.e. they obtain some of the characteristics typically observed in metals.[22]

References

  1. Meyer, Viktor (1883). "Ueber den Begleiter des Benzols im Steinkohlenteer" [On a substance that accompanies benzene in coal tar]. Berichte der Deutschen chemischen Gesellschaft. 16: 1465–1478. doi:10.1002/cber.188301601324.
  2. Ward C., Sumpter (1944). "The Chemistry of Isatin". Chemical Reviews. 34 (3): 393–434. doi:10.1021/cr60109a003.
  3. 1 2 3 Swanston, Jonathan (2006). "Thiophene". Ullmann’s Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a26_793.pub2..
  4. Mansuy, D., Valadon, P., Erdelmeier, I., López García, P., Amar, C., Girault, J. P., and Dansette, P. M. (1991). "Thiophene S-oxides as new reactive metabolites: Formation by cytochrome-P450 dependent oxidation and reaction with nucleophiles". J. Am. Chem. Soc. 113 (20): 7825–7826. doi:10.1021/ja00020a089.
  5. Treiber, A., Dansette, P. M., Amri, H. E., Girault, J.-P., Ginderow, D., Mornon, J.-P., Mansuy, D.; Dansette; El Amri; Girault; Ginderow; Mornon; Mansuy (1997). "Chemical and Biological Oxidation of Thiophene:  Preparation and Complete Characterization of Thiophene S-Oxide Dimers and Evidence for Thiophene S-Oxide as an Intermediate in Thiophene Metabolism in Vivo and in Vitro". J. Am. Chem. Soc. 119 (7): 1565–1571. doi:10.1021/ja962466g.
  6. Rademacher P. M., Woods C. M., Huang Q., Szklarz G. D., Nelson S. D.; Woods; Huang; Szklarz; Nelson (2012). "Differential Oxidation of Two Thiophene-Containing Regioisomers to Reactive Metabolites by Cytochrome P450 2C9". Chem. Res. Toxicol. 25 (4): 895–903. PMC 3339269Freely accessible. PMID 22329513. doi:10.1021/tx200519d.
  7. Mansuy D., Dansette P. M.; Dansette (2011). "Sulfenic acids as reactive intermediates in xenobiotic metabolism". Archives of Biochemistry and Biophysics. 507 (1): 174–185. PMID 20869346. doi:10.1016/j.abb.2010.09.015.
  8. Dansette, PM, Rosi, J, Debernardi, J, Bertho G, Mansuy D; Rosi; Debernardi; Bertho; Mansuy (2012). "Metabolic Activation of Prasugrel: Nature of the Two Competitive Pathways Resulting in the Opening of Its Thiophene Ring". Chem. Res. Toxicol. 25 (5): 1058–1065. doi:10.1021/tx3000279.
  9. 1 2 3 4 Treiber, Alexander (2002). "Mechanism of the Aromatic Hydroxylation of Thiophene by Acid-Catalyzed Peracid Oxidation". J. Org. Chem. 67 (21): 7261–7266. doi:10.1021/jo0202177.
  10. 1 2 Caster, Kenneth C.; Rao, A. Somasekar; Mohan, H. Rama; McGrath, Nicholas A.; Brichacek, Matthew (2012). "Trifluoroperacetic Acid". e-EROS Encyclopedia of Reagents for Organic Synthesis. doi:10.1002/047084289X.rt254.pub2.
  11. Hagen, Timothy J. (2007). "Prilezhaev reaction". In Li, Jie Jack; Corey, E. J. Name Reactions of Functional Group Transformations. John Wiley & Sons. pp. 274–281. ISBN 9780470176504.
  12. Anslyn, Eric V.; Dougherty, Dennis A. (2006). "8.8 Miscellaneous Experiments for Studying Mechanism". Modern Physical Organic Chemistry. University Science Books. pp. 471–482. ISBN 9781891389313.
  13. Hart, Harold; Lange, Richard M.; Collins, Peter M. (1968). "2,3,4,5,6,6-Hexamethyl-2,4-cyclohexadien-1-one". Org. Synth. 48: 87. doi:10.15227/orgsyn.048.0087.; Coll. Vol., 5, p. 598
  14. Hiyama, Tamejiro (2000). "8.2 Trifluoroacetic acid and Trifluoroperacetic acid". Organofluorine Compounds: Chemistry and Applications. Springer Science & Business Media. pp. 255–257. ISBN 9783662041642.
  15. Henry Y. Lew and C. R. Noller (1963). "2-Iodolthiophene". Org. Synth.; Coll. Vol., 4, p. 545
  16. W. S. Emerson and T. M. Patrick, Jr. (1963). "2-Vinylthiophene". Org. Synth.; Coll. Vol., 4, p. 980
  17. K. B. Wiberg and H. F. McShane (1955). "2-Chloromethylthiophene". Org. Synth.; Coll. Vol., 3, p. 1
  18. Rauchfuss, T. B., "The Coordination Chemistry of Thiophenes", Progress in Inorganic Chemistry 1991, volume 39, pp. 259-311. ISBN 978-0-471-54489-0
  19. E. Jones and I. M. Moodie (1988). "2-Thiophenethiol". Org. Synth.; Coll. Vol., 6, p. 979
  20. Bruce H. Lipshutz, Robert Moretti, Robert Crow "Mixed Higher-order Cyanocuprate-induced Epoxide Openings: 1-Benzyloxy-4-penten-2-ol" Org. Synth. 1990, volume 69, pp. 80. doi:10.15227/orgsyn.069.0080
  21. Daniel Lednicer (1999). The Organic Chemistry of Drug Synthesis. 6. New York: Wiley Interscience. p. 187. ISBN 0-471-24510-0.
  22. J. Roncali (1992). "Conjugated poly(thiophenes): synthesis, functionalization, and applications". Chem. Rev. 92 (4): 711–738. doi:10.1021/cr00012a009.
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