AI Article Synopsis
- TRIP-Py is a novel heteroditopic ligand with a phosphatriptycene scaffold that has both phosphorus and pyridyl coordinating sites, allowing selective binding to various metal cations based on their hardness.
- The ligand displays selectivity for harder metals like Zn with its N donor and softer metals like Au with its P donor, leading to the formation of distinct metal complexes and coordination polymers.
- TRIP-Py not only aids in the synthesis of mixed-metal complexes but also improves crystallization processes and serves as an NMR probe due to its structural rigidity and donor properties.
Article Abstract
Phosphasilatriptycene, a phenylene spacer and a pyridyl moiety represent the building blocks of TRIP-Py, the first heteroditopic ligand featuring a phoshatriptycene scaffold. The P and N donor sites located at opposite ends of the prolate TRIP-Py molecule selectively coordinate metal cations matching their Pearson character. The harder pyridyl donor binds to Zn, the softer phosphorus donor to Pt, Hg and Au. The remarkably short Au-P bond in the latter underlines the good π acceptor character of the phoshatriptycene moiety. When both the chloride salts of hard Zn and soft Au cations are available for coordination, TRIP-Py acts as selective ditopic linker in the discrete trinuclear mixed-metal complex [ZnCl(TRIP-PyAuCl)]. For Cd, a cation with intermediate Pearson character, selectivity withers, and a monometallic coordination polymer is obtained. Its significantly elongated Cd-P coordinative bonds underline, however, the preference of Cd for the harder N donor. When Zn and Hg halides are combined, their preference for the matching donor sites in TRIP-Py and for tetrahedral coordination afford 1D and 2D heterobimetallic polymers with and without solvent-accessible voids. TRIP-Py enables the use of two important analytical tools: its rigidity facilitates crystallization and allowed to investigate 14 crystalline solids, and its P donor provides a powerful NMR probe for coordination.
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| http://dx.doi.org/10.1039/d2dt00728b | DOI Listing |
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