What question did this study set out to answer?

This research aims to explore the molecular design of cage phosphine oxides featuring P=O and Si interactions.

March 6, 2026

Theoretical Design of Cage Structures with Unusual Linear P=O→Si Interactions

Key Points

This research aims to explore the molecular design of cage phosphine oxides featuring P=O and Si interactions.
Used density functional theory methods (B3PW91 and ωB97X-D) for molecular design.
Selected specific substituents at silicon and phosphorus to stabilize endo forms.
Assessed the competition between four silicon atoms for bonding to phosphoryl oxygen.
Identified stabilizing endo forms containing significant P=O···Si interactions.
Determined the nature of the P=O bond in phosphine oxides based on silicon coordination.
Showed that silicon atoms effectively compete for bonding with phosphoryl oxygen.

Abstract

Molecular design of cage phosphine oxides (6-phospha-1,3,9,12-tetrasila-bicyclo4.4.4tetradecan-6-oxides) with four Si-containing acceptor fragments and one P=O donor fragment was performed using density functional theory methods (B3PW91 and ωB97X-D). Substituents at the silicon and phosphorus atoms were selected to favor the existence of the structures in the endo form containing a P=O···Si interaction. The competition of four silicon atoms for bonding to the phosphoryl oxygen atom was used to assess the coordinating ability of the phosphoryl group and to determine the nature of the P=O bond in phosphine oxides.

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Theoretical Design of Cage Structures with Unusual Linear P=O→Si Interactions

Key Points

Abstract

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