71338-71-1Relevant articles and documents
Compound with mutton smell fragrance as well as preparation method and application thereof
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Paragraph 0074-0086; 0088-0091; 0093-0096, (2021/04/14)
The invention relates to the field of spices, and in particularrelates to a compound with mutton smell fragrance as well as a preparation method and application thereof. The invention discloses the compound with mutton smell fragrance. The compound has a structure shown as a formula (I). Research finds that the prepared compound with the mutton smell fragrance has the remarkable mutton smell fragrance, the fragrance intensity is high, and the fragrance lasting time is long. Compared with a traditional acidic mutton smell aroma substance, the compound with the mutton smell fragrance prepared by the invention belongs to ester compounds, so that the compound can stably exist when being applied to essence containing alkaline substances. The invention further provides a preparation method and application of the compound with the mutton smell fragrance. The raw materials for preparing the compound with the mutton smell fragrance are wide and easy to obtain, the technological operation is simple and convenient, and the compound is suitable for batch production.
Dienolates of Cycloalkenones and α,β-Unsaturated Esters Form Diels–Alder Adducts by a Michael/Michael-Tandem Reaction Rather Than in One Step
Loesche, Ann-Christine,Brückner, Reinhard
supporting information, p. 562 - 573 (2018/12/11)
α,β-Unsaturated esters and lithium 1,3-dien-2-olates are known to furnish bicyclic lithium enolates by anionic Diels–Alder reactions. However, in principle, the respective products might form not only in a single step but also in two consecutive – or “tandem” – Michael additions, the first of which occurs intermolecularly, the second intramolecularly. Three cyclic lithium dienolates and four esters with a stereogenic Cα=Cβ bond reacted to give Diels–Alder adducts (10 times) or failed to react (2 times). Seven of the reactive combinations furnished adducts wherein the configuration of the former ester moiety had in part inverted. This precludes concerted pathways as their origins. This was a surprise since donors at C-2 of the 1,3-diene accelerate normal electron-demand Diels–Alder reactions in the order alkyl ⊕O? being a far better donor still, it is not obvious why the mechanism is non-concerted rather than concerted (and still more asynchronous).
Electrochemical anion pool synthesis of amides with concurrent benzyl ester synthesis
Mevan Dissanayake,Melville, Alex D.,Vannucci, Aaron K.
supporting information, p. 3165 - 3171 (2019/06/18)
An electrosynthesis method for amide bond formation has been developed in an attempt to increase the atom economy for this class of reactions. This "anion pool" method electrochemically generates strong nucleophiles from amine substrates. The amine nucleophiles then react with acid anhydrides to generate amides, and the by-product from this reaction undergoes further chemical transformations to generate pharmaceutically relevant benzoic esters. These one-pot reactions are operationally simple, are performed at room temperature, and avoid rare transition metals and added bases. The amide synthesis is amenable to primary and secondary amines and a variety of anhydrides with yields up to 90% obtained. Atom economy and process mass index (PMI) values calculated for this procedure indicate that this process can be considered greener compared to traditional amide synthesis routes used by industry. Furthermore, this electrochemical approach showed unique selectivity when substrates that contained two inequivalent amine moieties were examined.
