Strain-Releasing Ring-Opening Diphosphinations for the Synthesis of Diphosphine Ligands with Cyclic Backbones

JACS Au Pub Date : 2024-07-29 DOI:10.1021/jacsau.4c00347

Chandu G. Krishnan, Hideaki Takano, Hitomi Katsuyama, Wataru Kanna, Hiroki Hayashi, Tsuyoshi Mita

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Abstract

Diphosphine ligands based on cyclobutane, bicyclo[3.1.1]heptane, and bicyclo[4.1.1]octane were synthesized from the corresponding highly strained, small, cyclic organic molecules, i.e., bicyclo[1.1.0]butane, [3.1.1]propellane, and [4.1.1]propellane, employing a ring-opening diphosphination. Under photocatalytic conditions, the three-component reaction of a diarylphosphine oxide, one of the aforementioned strained molecules, and a diarylchlorophosphine results in the smooth formation of the corresponding diphosphines in high yield. The obtained diphosphines can be expected to find applications in functional molecules due to their unique structural characteristics, which likely impart specific properties on their associated metal complexes and coordination polymers (e.g., a zigzag-type structure). The feasibility of the initial radical addition can be estimated using density-functional-theory calculations using the artificial force induced reaction (AFIR) method. This study focuses on the importance of integrating experimental and computational methods for the design and synthesis of new diphosphination reactions that involve strained, small, cyclic organic molecules.

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用于合成具有环状骨架的二膦配体的应变释放开环二膦化反应

利用开环二膦化法，从相应的高应变小环状有机分子（即双环[1.1.0]丁烷、[3.1.1]丙烷和[4.1.1]丙烷）合成了基于环丁烷、双环[3.1.1]庚烷和双环[4.1.1]辛烷的二膦配体。在光催化条件下，二元氧化膦、上述应变分子之一和二芳基氯化膦的三组分反应可顺利生成相应的高产率二膦。由于所获得的二膦具有独特的结构特征，可能会赋予其相关的金属配合物和配位聚合物特定的性质（如人字型结构），因此有望在功能分子中得到应用。通过使用人工力诱导反应（AFIR）方法进行密度-官能团理论计算，可以估算出初始自由基加成的可行性。这项研究的重点是，在设计和合成涉及应变、小型环状有机分子的新型二膦化反应时，必须将实验和计算方法结合起来。

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JACS Au

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