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      Computational exploration of the 1,3‐dipolar cycloaddition reaction of 7‐isopropylidenebenzonorbornadiene with nitrile oxide and cyclic nitrone derivatives

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      https://www.riss.kr/link?id=O106357393

      • 저자
      • 발행기관
      • 학술지명
      • 권호사항
      • 발행연도

        2021년

      • 작성언어

        -

      • Print ISSN

        0894-3230

      • Online ISSN

        1099-1395

      • 등재정보

        SCI;SCIE;SCOPUS

      • 자료형태

        학술저널

      • 수록면

        n/a-n/a   [※수록면이 p5 이하이면, Review, Columns, Editor's Note, Abstract 등일 경우가 있습니다.]

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        • 전북대학교 중앙도서관  
        • 성균관대학교 중앙학술정보관  
        • 부산대학교 중앙도서관  
        • 전남대학교 중앙도서관  
        • 제주대학교 중앙도서관  
        • 중앙대학교 서울캠퍼스 중앙도서관  
        • 인천대학교 학산도서관  
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        • 계명대학교 동산도서관  
        • 충남대학교 중앙도서관  
        • 한양대학교 백남학술정보관  
        • 이화여자대학교 중앙도서관  
        • 고려대학교 도서관  
      • ⓒ COPYRIGHT THE BRITISH LIBRARY BOARD: ALL RIGHT RESERVED

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      다국어 초록 (Multilingual Abstract)

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      The synthesis of isoxazolidine and isoxazole derivatives, versatile building blocks for the construction of a wide range of complex heterocyclic architectures in synthetic organic and medicinal chemistry, is efficiently achieved via the 1,3‐dipolar cycloaddition reaction (1,3‐DC). Herein, we report an extensive theoretical study on the peri‐, regio‐, stereo, and enantio‐selectivities of 1,3‐DC of 7‐isopropylidenebenzonorbornadiene with nitrile oxide and cyclic nitrone derivatives using density functional theory calculations. Acetophenone‐substituted nitrile oxide periselectively adds across the endocyclic olefinic bond of the dipolarophile to furnish the exo‐cycloadduct as the major product, a reaction that has a rate constant of 1.88 × 109 s−1. The endo approach of this periselective path is the closest competing pathway with a rate constant of 4.59 × 107 s−1. Different substituents on the nitrile oxide do not affect the peri‐ and stereo‐selectivity of the reaction. Diethyl ether solvation has no substantial effect on the energetic patterns observed in the gas phase computation. Also, we report a novel 1,3‐DC between cyclic nitrone derivatives and 7‐isopropylidenebenzonorbornadiene as an efficient way to generate isoxazolidine derivatives. Even though the reactions of the cyclic nitrone derivatives have slightly higher activation barriers than the acyclic nitrile oxide derivatives, the former is more enantioselective than the latter. Whereas electron‐donating groups (EDGs) on the cyclic nitrone favor the formation of the exo‐cycloadduct, electron‐withdrawing groups (EWGs) favor the formation of the endo‐cycloadduct. Both 1,3‐dipoles add across the dipolarophile via a concerted asynchronous mechanism.
      Both nitrile oxide and cyclic nitrone derivatives periselectively add across the endocyclic olefinic bond of 7‐isopropylidenebenzonorbornadiene to generate either the endo‐cycloadduct or the exo‐cycloadduct. The electronic nature of the substituents on the nitrile oxide does not affect the formation of the exo‐cycloadduct. In contrast to nitrile oxide, either the endo‐cycloadduct or the exo‐cycloadduct may be formed depending on the electronic nature of the substituents on the cyclic nitrone.
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      The synthesis of isoxazolidine and isoxazole derivatives, versatile building blocks for the construction of a wide range of complex heterocyclic architectures in synthetic organic and medicinal chemistry, is efficiently achieved via the 1,3‐dipolar ...

      The synthesis of isoxazolidine and isoxazole derivatives, versatile building blocks for the construction of a wide range of complex heterocyclic architectures in synthetic organic and medicinal chemistry, is efficiently achieved via the 1,3‐dipolar cycloaddition reaction (1,3‐DC). Herein, we report an extensive theoretical study on the peri‐, regio‐, stereo, and enantio‐selectivities of 1,3‐DC of 7‐isopropylidenebenzonorbornadiene with nitrile oxide and cyclic nitrone derivatives using density functional theory calculations. Acetophenone‐substituted nitrile oxide periselectively adds across the endocyclic olefinic bond of the dipolarophile to furnish the exo‐cycloadduct as the major product, a reaction that has a rate constant of 1.88 × 109 s−1. The endo approach of this periselective path is the closest competing pathway with a rate constant of 4.59 × 107 s−1. Different substituents on the nitrile oxide do not affect the peri‐ and stereo‐selectivity of the reaction. Diethyl ether solvation has no substantial effect on the energetic patterns observed in the gas phase computation. Also, we report a novel 1,3‐DC between cyclic nitrone derivatives and 7‐isopropylidenebenzonorbornadiene as an efficient way to generate isoxazolidine derivatives. Even though the reactions of the cyclic nitrone derivatives have slightly higher activation barriers than the acyclic nitrile oxide derivatives, the former is more enantioselective than the latter. Whereas electron‐donating groups (EDGs) on the cyclic nitrone favor the formation of the exo‐cycloadduct, electron‐withdrawing groups (EWGs) favor the formation of the endo‐cycloadduct. Both 1,3‐dipoles add across the dipolarophile via a concerted asynchronous mechanism.
      Both nitrile oxide and cyclic nitrone derivatives periselectively add across the endocyclic olefinic bond of 7‐isopropylidenebenzonorbornadiene to generate either the endo‐cycloadduct or the exo‐cycloadduct. The electronic nature of the substituents on the nitrile oxide does not affect the formation of the exo‐cycloadduct. In contrast to nitrile oxide, either the endo‐cycloadduct or the exo‐cycloadduct may be formed depending on the electronic nature of the substituents on the cyclic nitrone.

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