Transition Metal Complexes with Appended Benzimidazole Groups for Sensing Dihydrogenphosphate

Howells, Chloe and Stocker, Andrew and Lea, Joshua and Halcovitch, Nathan and Patel, Humaira and Fletcher, Nick (2024) Transition Metal Complexes with Appended Benzimidazole Groups for Sensing Dihydrogenphosphate. Chemistry - A European Journal, 30 (52): e202401385. ISSN 0947-6539

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Abstract

Four new complexes [Ru(bpy) 2(bbib)](PF 6) 2, [Ru(phen) 2(bbib)](PF 6) 2, [Re(CO) 3(bbib)(py)](PF 6) and [Ir(ppy) 2(bbib)](PF 6) [where bbib=4,4′-bis(benzimidazol-2-yl)-2,2′-bipyridine] have been prepared and their photophysical properties determined. Their behaviour has been studied with a variety of anions in acetonitrile, DMSO and 10 % aquated DMSO. Acetate and dihydrogenphosphate demonstrate a redshift in the bbib ligand associated absorptions suggesting that the ligand is strongly interacting with these anions. The 3MLCT emissive state is sensitive to the introduction of small quantities of anion (sub-stoichiometric quantities) and significant quenching is typically observed with acetate, although this is less pronounced in the presence of water. The emissive behaviour with dihydrogenphosphate is variable, showing systematic changes as anion concentration increases with several distinct interactions evident. 1H- and 31P-NMR titrations in a 10 % D 2O−DMSO-D 6 mixture suggest that with dihydrogenphosphate, the imidazole group is able to act as both a proton acceptor and donor. It appears that all four complexes can form a {[complex] 2-H 2PO 4} “dimer”, a one-to-one species (which the X-ray crystallography study suggests is dimeric in the solid-state), and a complex with a combined bis(dihydrogenphosphate) complex anion. The speciation relies on complex equilibria dependent on several factors including the complex charge, the hydrophobicity of the associated ligands, and the solvent.