A Combined Experimental and Computational Exploration of Heteroleptic cis-Pd2L2L’2 Coordination Cages through Geometric Complementarity

Andrew Tarzia, Wentao Shan, Victor Posligua, Cameron Cox, Louise Male, Benjamin D. Egleston, Rebecca L Greenaway, Kim Jelfs, Jamie Lewis*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

Heteroleptic (mixed-ligand) coordination cages are of interest as host systems with more structurally and functionally complex cavities than homoleptic architectures. The design of heteroleptic cages, however, is far from trivial. In this work, we experimentally probed the self-assembly of Pd(II) ions with binary ligand combinations in a combinatorial fashion to search for new cis-Pd2L2L’2 heteroleptic cages. A hierarchy of computational analyses was then applied to these systems with the aim of elucidating key factors for rationalising self-assembly outcomes. Simple and inexpensive geometric analyses were shown to be effective in identifying complementary ligand pairs. Preliminary results demonstrated the viability of relatively rapid semi-empirical calculations for predicting the topology of thermodynamically favoured assemblies with rigid ligands, whilst more flexible systems proved challenging. Stemming from this, key challenges were identified for future work developing effective computational forecasting tools for self-assembled metallo-supramolecular systems.
Original languageEnglish
Article numbere202403336
JournalChemistry: A European Journal
Early online date27 Oct 2024
DOIs
Publication statusE-pub ahead of print - 27 Oct 2024

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