Oxazines

This article will address the topic of Oxazines from a comprehensive and detailed perspective, with the aim of offering a complete and updated view of this matter. Throughout the text, different aspects related to Oxazines will be analyzed, from its origin to its impact on current society. Relevant data, statistics and expert opinions will be presented to offer the reader a deep and enriching understanding of Oxazines. Likewise, possible solutions or proposals will be examined to address the challenges posed by Oxazines. Don't miss this article that promises to be enlightening and enriching!

The 8 isomers of oxazine[1]

Oxazines are heterocyclic organic compounds containing one oxygen and one nitrogen atom in a cyclohexa-1,4-diene ring (a doubly unsaturated six-membered ring). Isomers exist depending on the relative position of the heteroatoms and relative position of the double bonds.

By extension, the derivatives are also referred to as oxazines; examples include ifosfamide and morpholine (tetrahydro-1,4-oxazine). A commercially available dihydro-1,3-oxazine is a reagent in the Meyers synthesis of aldehydes. Fluorescent dyes such as Nile red and Nile blue are based on the aromatic compound benzophenoxazine. Cinnabarine and cinnabaric acid are two naturally occurring dioxazines, being derived from biodegradation of tryptophan.[2]

Dioxazines

Dioxazines are pentacyclic compounds consisting of two oxazine subunits. A commercially important example is the pigment pigment violet 23.[3]

Synthetic route to dioxazine dyes.[4]

Benzoxazines

Benzoxazine resin synthetic pathway, structure and cure mechanism

Benzoxazines are bicyclic compounds formed by the ring fusion of a benzene ring with an oxazine. Polybenzoxazines are a class of polymers formed by the reaction of phenols, formaldehyde, and primary amines which on heating to ~200 °C (~400 °F) polymerise to produce polybenzoxazine networks.[5] The resulting high molecular weight thermoset polymer matrix composites are used where enhanced mechanical performance, flame and fire resistance compared to epoxy and phenolic resins is required.[6]

Physical properties

Oxazine dyes exhibit solvatochromism.[7]

Images

References

  1. ^ Eicher T, Hauptmann S, Speicher A (March 2013). The Chemistry of Heterocycles: Structures, Reactions, Synthesis, and Applications (3rd ed.). Wiley Inc. p. 442. ISBN 978-3-527-66987-5. OCLC 836864122.
  2. ^ Stone TW, Stoy N, Darlington LG (February 2013). "An expanding range of targets for kynurenine metabolites of tryptophan" (PDF). Trends in Pharmacological Sciences. 34 (2): 136–43. doi:10.1016/j.tips.2012.09.006. PMID 23123095.
  3. ^ Chamberlain T (2002). "Dioxazine violet pigments". In Smith HM (ed.). High Performance Pigments. John Wiley & Sons. pp. 185–194. doi:10.1002/3527600493.ch12. ISBN 978-3-527-30204-8.
  4. ^ Tappe H, Helmling W, Mischke P, Rebsamen K, Reiher U, Russ W, Schläfer L, Vermehren P (2000). "Reactive Dyes". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a22_651. ISBN 3527306730.
  5. ^ Tsotra P, Setiabudi F, Weidmann U (2008). "Benzoxazine chemistry: a new material to meet fire retardant challenges of aerospace interiors applications" (PDF). Engineering. S2CID 18422389.
  6. ^ Tietze R, Chaudhari M (2011). "Advanced benzoxazine chemistries provide improved performance in a broad range of applications". In Ishida H, Agag T (eds.). Handbook of Benzoxazine Resins. Elsevier B.V. pp. 595–604. doi:10.1016/B978-0-444-53790-4.00079-5. ISBN 978-0-444-53790-4.
  7. ^ Fleming S, Mills A, Tuttle T (2011-04-15). "Predicting the UV-vis spectra of oxazine dyes". Beilstein Journal of Organic Chemistry. 7: 432–441. doi:10.3762/bjoc.7.56. PMC 3107493. PMID 21647257.