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Aromatization

January 01, 1970

Aromatization is a chemical reaction in which an aromatic system is formed from a single nonaromatic precursor. Typically aromatization is achieved by dehydrogenation of existing cyclic compounds, illustrated by the conversion of cyclohexane into benzene. Aromatization includes the formation of heterocyclic systems.[1]

The conversion of methylcyclohexane to toluene is a classic aromatization reaction. This platinum (Pt)-catalyzed process is practiced on scale in the production of gasoline from petroleum.

Industrial practice edit

Although not practiced under the name, aromatization is a cornerstone of oil refining. One of the major reforming reactions is the dehydrogenation of naphthenes into aromatics. The process, which is catalyzed by platinum, is exemplified in the conversion methylcyclohexane (a naphthene) into toluene (an aromatic).[2] Dehydrocyclization converts paraffins (acyclic hydrocarbons) into aromatics.[3] A related aromatization process includes dehydroisomerization of methylcyclopentane to benzene:

 

Biochemical processes edit

 

Aromatases are enzymes that aromatize rings within steroids. The specific conversions are testosterone to estradiol and androstenedione to estrone.[4] Each of these aromatizations involves the oxidation of the C-19 methyl group to allow for the elimination of formic acid concomitant with aromatization. Such conversions are relevant to estrogen tumorogenesis in the development of breast cancer and ovarian cancer in postmenopausal women and gynecomastia in men.[5] Aromatase inhibitors like exemestane (which forms a permanent and deactivating bond with the aromatase enzyme)[6] and anastrozole and letrozole (which compete for the enzyme)[7] have been shown to be more effective than anti-estrogen medications such as tamoxifen likely because they prevent the formation of estradiol.[5]

Aromatization pathways edit

Oxidative dehydrogenation edit

For cyclohexane, cyclohexene, and cyclohexadiene, dehydrogenation is the conceptually simplest pathway for aromatization. The activation barrier decreases with the degree of unsaturation. Thus, cyclohexadienes are especially prone to aromatization. Formally, dehydrogenation is a redox process. Dehydrogenative aromatization is the reverse of arene hydrogenation. As such, hydrogenation catalysts are effective for the reverse reaction. Platinum-catalyzed dehydrogenations of cyclohexanes and related feedstocks are the largest scale applications of this reaction (see above).[1]

2,3-Dichloro-5,6-dicyano-1,4-benzoquinone (DDQ) is often the reagent of choice. DDQ and an acid catalyst has been used to synthesise a steroid with a phenanthrene core by oxidation accompanied by a double methyl migration.[8] In the process, DDQ is itself reduced into an aromatic hydroquinone product.

 

Sulfur and selenium are traditionally used in aromatization, the leaving group being hydrogen sulfide.[9]

Soluble transition metal complexes can induce oxidative aromatization concomitant with complexation. α-Phellandrene (2-methyl-5-iso-propyl-1,3-cyclohexadiene) is oxidised to p-iso-propyltoluene with the reduction of ruthenium trichloride.[10]

Oxidative dehydrogenation of dihydropyridine results in aromatization, giving pyridine.[11]

Dehydration edit

 
240pxSemmler-Wolff synthesis of aniline

Non-aromatic rings can be aromatized in many ways. Dehydration allows the Semmler-Wolff reaction of 2-cyclohexenone oxime to aniline under acidic conditions.[12]

Tautomerization edit

 
1,4-Dioxotetralin and its aromatized tautomer 1,4-naphthalenediol coexist in equal abundance in solution.

The isomerization of cyclohexadienones gives the aromatic tautomer phenol.[13][14] Isomerization of 1,4-naphthalenediol at 200 °C produces a 2:1 mixture with its keto form, 1,4-dioxotetralin.[15]

Hydride and proton abstraction edit

Classically, aromatization reactions involve changing the C:H ratio of a substrate. When applied to cyclopentadiene, proton removal gives the aromatic conjugate base cyclopentadienyl anion, isolable as sodium cyclopentadienide:[16]

2 Na + 2 C5H6 → 2 NaC5H5 + H2

Aromatization can entail removal of hydride. Tropylium, C
7H+
7 arises by the aromatization reaction of cycloheptatriene with hydride acceptors.

C
7H
8 + Br
2C
7H+
7 + Br
 + HBr
 
Ciamician-Dennstedt rearrangement of a pyrrole to a pyridine. The first step involves dearomatization. The second step involves aromatization.

From acyclic precursors edit

The aromatization of acyclic precursors is rarer in organic synthesis, although it is a significant component of the BTX production in refineries.

Among acyclic precursors, alkynes are relatively prone to aromatizations since they are partially dehydrogenated. The Bergman cyclization is converts an enediyne to a dehydrobenzene intermediate diradical, which abstracts hydrogen to aromatize.[17] The enediyne moiety can be included within an existing ring, allowing access to a bicyclic system under mild conditions as a consequence of the ring strain in the reactant. Cyclodeca-3-en-1,5-diyne reacts with 1,3-cyclohexadiene to produce benzene and tetralin at 37 °C, the reaction being highly favorable owing to the formation of two new aromatic rings:

 
Scheme 1. Bergman cyclization

See also edit

References edit

  1. ^ a b Smith, Michael B.; March, Jerry (2007), Advanced Organic Chemistry: Reactions, Mechanisms, and Structure (6th ed.), New York: Wiley-Interscience, ISBN 978-0-471-72091-1
  2. ^ Gary, J.H.; Handwerk, G.E. (1984). Petroleum Refining Technology and Economics (2nd ed.). Marcel Dekker, Inc. ISBN 0-8247-7150-8.
  3. ^ Ono, Y. (1992). "Transformation of Lower Alkanes into Aromatic Hydrocarbons over ZSM-5 Zeolites". Catal. Rev. - Sci. Eng. 34 (3): 179–226. doi:10.1080/01614949208020306.
  4. ^ Lephart, E. D. (1996). "A Review of Brain Aromatase Cytochrome P450". Brain Res. Rev. 22 (1): 1–26. doi:10.1016/0165-0173(96)00002-1. PMID 8871783. S2CID 11987113.
  5. ^ a b Avendaño, C.; Menéndez, J. C. (2008). "Aromatase Inhibitors". Medicinal Chemistry of Anticancer Drugs. Elsevier. pp. 65–73. doi:10.1016/B978-0-444-52824-7.00003-2. ISBN 9780080559629.
  6. ^ Jasek, W., ed. (2007). Austria-Codex (in German) (62nd ed.). Vienna: Österreichischer Apothekerverlag. pp. 656–660. ISBN 9783852001814.
  7. ^ Dinnendahl, V.; Fricke, U., eds. (2007). Arzneistoff-Profile (in German). Vol. 4 (21st ed.). Eschborn, Germany: Govi Pharmazeutischer Verlag. ISBN 9783774198463.
  8. ^ Brown, W.; Turner, A. B. (1971). "Applications of High-Potential Quinones. Part VII. The Synthesis of Steroidal Phenanthrenes by Double Methyl Migration". Journal of the Chemical Society C: Organic. 14: 2566–2572. doi:10.1039/J39710002566. PMID 5167256.
  9. ^ Bergmann, F.; Szmuszkowicz, J.; Fawaz, G. (1947). "The Condensation of 1,1-Diarylethylenes with Maleic Anhydride". Journal of the American Chemical Society. 69 (7): 1773–1777. doi:10.1021/ja01199a055. PMID 20251415.
  10. ^ Bennett, M. A.; Huang, T. N.; Matheson, T. W.; Smith, A. K. (1982). "(η6-Hexamethylbenzene)ruthenium Complexes". Inorganic Syntheses. 21: 74–78. doi:10.1002/9780470132524.ch16. ISBN 9780470132524.
  11. ^ Shimizu, S.; Watanabe, N.; Kataoka, T.; Shoji, T.; Abe, N.; Morishita, S.; Ichimura, H. (2005). "Pyridine and Pyridine Derivatives". Ullmann's Encyclopedia of Industrial Chemistry. Wiley-VCH. doi:10.1002/14356007.a22_399. ISBN 3527306730.
  12. ^ Horning, E. C.; Stromberg, V. L.; Lloyd, H. A. (1952). "Beckmann Rearrangements. An Investigation of Special Cases". Journal of the American Chemical Society. 74 (20): 5153–5155. doi:10.1021/ja01140a048.
  13. ^ Clayden, J.; Greeves, N.; Warren, S.; Wothers, P. (2001). Organic Chemistry (1st ed.). Oxford University Press. p. 531. ISBN 9780198503460.
  14. ^ Capponi, M.; Gut, I. G.; Hellrung, B.; Persy, G.; Wirz, J. (1999). "Ketonization Equilibria of Phenol in Aqueous Solution". Canadian Journal of Chemistry. 77 (5–6): 605–613. doi:10.1139/cjc-77-5-6-605.
  15. ^ Kündig, E. P.; Garcia, A. E.; Lomberget, T.; Bernardinelli, G. (2005). "Rediscovery, Isolation, and Asymmetric Reduction of 1,2,3,4-Tetrahydronaphthalene-1,4-dione and Studies of its [Cr(CO)3] Complex". Angewandte Chemie International Edition. 45 (1): 98–101. doi:10.1002/anie.200502588. PMID 16304647.
  16. ^ Cotton, F. A.; Wilkinson, G. (1999). Advanced Inorganic Chemistry (6th ed.). John Wiley and Sons. ISBN 9780471199571.
  17. ^ Mohamed, R. K.; Peterson, P. W.; Alabugin, I. V. (2013). "Concerted Reactions that Produce Diradicals and Zwitterions: Electronic, Steric, Conformational and Kinetic Control of Cycloaromatization Processes". Chemical Reviews. 113 (9): 7089–7129. doi:10.1021/cr4000682. PMID 23600723.

January 01, 1970
aromatization, chemical, reaction, which, aromatic, system, formed, from, single, nonaromatic, precursor, typically, aromatization, achieved, dehydrogenation, existing, cyclic, compounds, illustrated, conversion, cyclohexane, into, benzene, includes, formation. Aromatization is a chemical reaction in which an aromatic system is formed from a single nonaromatic precursor Typically aromatization is achieved by dehydrogenation of existing cyclic compounds illustrated by the conversion of cyclohexane into benzene Aromatization includes the formation of heterocyclic systems 1 The conversion of methylcyclohexane to toluene is a classic aromatization reaction This platinum Pt catalyzed process is practiced on scale in the production of gasoline from petroleum Contents 1 Industrial practice 2 Biochemical processes 3 Aromatization pathways 3 1 Oxidative dehydrogenation 3 2 Dehydration 3 3 Tautomerization 3 4 Hydride and proton abstraction 3 5 From acyclic precursors 4 See also 5 ReferencesIndustrial practice editAlthough not practiced under the name aromatization is a cornerstone of oil refining One of the major reforming reactions is the dehydrogenation of naphthenes into aromatics The process which is catalyzed by platinum is exemplified in the conversion methylcyclohexane a naphthene into toluene an aromatic 2 Dehydrocyclization converts paraffins acyclic hydrocarbons into aromatics 3 A related aromatization process includes dehydroisomerization of methylcyclopentane to benzene nbsp Biochemical processes edit nbsp Aromatases are enzymes that aromatize rings within steroids The specific conversions are testosterone to estradiol and androstenedione to estrone 4 Each of these aromatizations involves the oxidation of the C 19 methyl group to allow for the elimination of formic acid concomitant with aromatization Such conversions are relevant to estrogen tumorogenesis in the development of breast cancer and ovarian cancer in postmenopausal women and gynecomastia in men 5 Aromatase inhibitors like exemestane which forms a permanent and deactivating bond with the aromatase enzyme 6 and anastrozole and letrozole which compete for the enzyme 7 have been shown to be more effective than anti estrogen medications such as tamoxifen likely because they prevent the formation of estradiol 5 Aromatization pathways editOxidative dehydrogenation edit For cyclohexane cyclohexene and cyclohexadiene dehydrogenation is the conceptually simplest pathway for aromatization The activation barrier decreases with the degree of unsaturation Thus cyclohexadienes are especially prone to aromatization Formally dehydrogenation is a redox process Dehydrogenative aromatization is the reverse of arene hydrogenation As such hydrogenation catalysts are effective for the reverse reaction Platinum catalyzed dehydrogenations of cyclohexanes and related feedstocks are the largest scale applications of this reaction see above 1 2 3 Dichloro 5 6 dicyano 1 4 benzoquinone DDQ is often the reagent of choice DDQ and an acid catalyst has been used to synthesise a steroid with a phenanthrene core by oxidation accompanied by a double methyl migration 8 In the process DDQ is itself reduced into an aromatic hydroquinone product nbsp Sulfur and selenium are traditionally used in aromatization the leaving group being hydrogen sulfide 9 Soluble transition metal complexes can induce oxidative aromatization concomitant with complexation a Phellandrene 2 methyl 5 iso propyl 1 3 cyclohexadiene is oxidised to p iso propyltoluene with the reduction of ruthenium trichloride 10 Oxidative dehydrogenation of dihydropyridine results in aromatization giving pyridine 11 Dehydration edit nbsp 240pxSemmler Wolff synthesis of aniline Non aromatic rings can be aromatized in many ways Dehydration allows the Semmler Wolff reaction of 2 cyclohexenone oxime to aniline under acidic conditions 12 Tautomerization edit nbsp 1 4 Dioxotetralin and its aromatized tautomer 1 4 naphthalenediol coexist in equal abundance in solution The isomerization of cyclohexadienones gives the aromatic tautomer phenol 13 14 Isomerization of 1 4 naphthalenediol at 200 C produces a 2 1 mixture with its keto form 1 4 dioxotetralin 15 Hydride and proton abstraction edit Classically aromatization reactions involve changing the C H ratio of a substrate When applied to cyclopentadiene proton removal gives the aromatic conjugate base cyclopentadienyl anion isolable as sodium cyclopentadienide 16 2 Na 2 C5H6 2 NaC5H5 H2 Aromatization can entail removal of hydride Tropylium C7 H 7 arises by the aromatization reaction of cycloheptatriene with hydride acceptors C7 H8 Br2 C7 H 7 Br HBr nbsp Ciamician Dennstedt rearrangement of a pyrrole to a pyridine The first step involves dearomatization The second step involves aromatization From acyclic precursors edit The aromatization of acyclic precursors is rarer in organic synthesis although it is a significant component of the BTX production in refineries Among acyclic precursors alkynes are relatively prone to aromatizations since they are partially dehydrogenated The Bergman cyclization is converts an enediyne to a dehydrobenzene intermediate diradical which abstracts hydrogen to aromatize 17 The enediyne moiety can be included within an existing ring allowing access to a bicyclic system under mild conditions as a consequence of the ring strain in the reactant Cyclodeca 3 en 1 5 diyne reacts with 1 3 cyclohexadiene to produce benzene and tetralin at 37 C the reaction being highly favorable owing to the formation of two new aromatic rings nbsp Scheme 1 Bergman cyclizationSee also editAromatase Aromatic hydrocarbonReferences edit a b Smith Michael B March Jerry 2007 Advanced Organic Chemistry Reactions Mechanisms and Structure 6th ed New York Wiley Interscience ISBN 978 0 471 72091 1 Gary J H Handwerk G E 1984 Petroleum Refining Technology and Economics 2nd ed Marcel Dekker Inc ISBN 0 8247 7150 8 Ono Y 1992 Transformation of Lower Alkanes into Aromatic Hydrocarbons over ZSM 5 Zeolites Catal Rev Sci Eng 34 3 179 226 doi 10 1080 01614949208020306 Lephart E D 1996 A Review of Brain Aromatase Cytochrome P450 Brain Res Rev 22 1 1 26 doi 10 1016 0165 0173 96 00002 1 PMID 8871783 S2CID 11987113 a b Avendano C Menendez J C 2008 Aromatase Inhibitors Medicinal Chemistry of Anticancer Drugs Elsevier pp 65 73 doi 10 1016 B978 0 444 52824 7 00003 2 ISBN 9780080559629 Jasek W ed 2007 Austria Codex in German 62nd ed Vienna Osterreichischer Apothekerverlag pp 656 660 ISBN 9783852001814 Dinnendahl V Fricke U eds 2007 Arzneistoff Profile in German Vol 4 21st ed Eschborn Germany Govi Pharmazeutischer Verlag ISBN 9783774198463 Brown W Turner A B 1971 Applications of High Potential Quinones Part VII The Synthesis of Steroidal Phenanthrenes by Double Methyl Migration Journal of the Chemical Society C Organic 14 2566 2572 doi 10 1039 J39710002566 PMID 5167256 Bergmann F Szmuszkowicz J Fawaz G 1947 The Condensation of 1 1 Diarylethylenes with Maleic Anhydride Journal of the American Chemical Society 69 7 1773 1777 doi 10 1021 ja01199a055 PMID 20251415 Bennett M A Huang T N Matheson T W Smith A K 1982 h6 Hexamethylbenzene ruthenium Complexes Inorganic Syntheses 21 74 78 doi 10 1002 9780470132524 ch16 ISBN 9780470132524 Shimizu S Watanabe N Kataoka T Shoji T Abe N Morishita S Ichimura H 2005 Pyridine and Pyridine Derivatives Ullmann s Encyclopedia of Industrial Chemistry Wiley VCH doi 10 1002 14356007 a22 399 ISBN 3527306730 Horning E C Stromberg V L Lloyd H A 1952 Beckmann Rearrangements An Investigation of Special Cases Journal of the American Chemical Society 74 20 5153 5155 doi 10 1021 ja01140a048 Clayden J Greeves N Warren S Wothers P 2001 Organic Chemistry 1st ed Oxford University Press p 531 ISBN 9780198503460 Capponi M Gut I G Hellrung B Persy G Wirz J 1999 Ketonization Equilibria of Phenol in Aqueous Solution Canadian Journal of Chemistry 77 5 6 605 613 doi 10 1139 cjc 77 5 6 605 Kundig E P Garcia A E Lomberget T Bernardinelli G 2005 Rediscovery Isolation and Asymmetric Reduction of 1 2 3 4 Tetrahydronaphthalene 1 4 dione and Studies of its Cr CO 3 Complex Angewandte Chemie International Edition 45 1 98 101 doi 10 1002 anie 200502588 PMID 16304647 Cotton F A Wilkinson G 1999 Advanced Inorganic Chemistry 6th ed John Wiley and Sons ISBN 9780471199571 Mohamed R K Peterson P W Alabugin I V 2013 Concerted Reactions that Produce Diradicals and Zwitterions Electronic Steric Conformational and Kinetic Control of Cycloaromatization Processes Chemical Reviews 113 9 7089 7129 doi 10 1021 cr4000682 PMID 23600723 Retrieved from https en wikipedia org w index php title Aromatization amp oldid 1135400914, wikipedia, wiki, book, books, library,

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