AI Article Synopsis
- Cycloaddition using transition metals like rhodium (I) is crucial for creating functionalized molecules in medicinal chemistry.
- The study focuses on two types of compounds: one with an allenyl group and the other with a vinyl group, both linked to a cyclopentane and alkyne.
- Computational models showed that the allenyl compound has a significantly lower reaction energy compared to the vinyl compound, with molecular orbitals influencing the reactivity differences.
Article Abstract
Cycloaddition catalyzed by transition metals such as rhodium (I) is an important way to synthesize functionalized molecules in medicinal chemistry. When the reagent has a saturated ring containing more than five carbons (or heavy atoms), the reaction can progress when the compound has an allenyl group, but not for a vinyl group. Here, we constructed two computational models for allenylcyclopentane-alkyne and vinylcyclopentane-alkyne, and obtained their reaction pathways using density functional theory (DFT). From the reaction pathways, we confirmed that the former model has a much lower reaction energy than the latter. We also found that the molecular orbitals of the transition state structure at the rate-controlling step contribute significantly to the difference in reactivity between the two models.
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| http://dx.doi.org/10.1248/cpb.c20-00144 | DOI Listing |
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