Journal article
Impact of the 2Fe2P core geometry on the reduction chemistry of phosphido-bridged diiron hexacarbonyl compounds
OTE Selan, MH Cheah, BF Abrahams, RW Gable, SP Best
Australian Journal of Chemistry | Published : 2022
DOI: 10.1071/CH21309
Abstract
The effect of core geometry constraints of hydrogenase H-cluster analogues on reduction chemistry have been explored by a combination of structural, electrochemical and IR spectroelectrochemical (IR-SEC) studies. A series of phosphido-bridged diiron hexacarbonyl complexes, Fe2(µ2-PPh2(CH2)xPPh2)(CO)6, x = 2 (2P) and 4 (4P) and previously reported with x = 3 (3P) and the unlinked bis-diphenylphosphido (DP) analogues were investigated. The X-ray structures of the neutral complexes demonstrate the effect of the linking group on the Fe2P2 core geometry with P-Fe-Fe-P torsion angles of 95 (2P), 101 (3P), 108 (4P) and 109° (DP) and a twisting of the Fe(CO)3 fragments from an eclipsed geometry (2P,..
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Awarded by Australian Research Council
Awarded by Swedish Energy Agency
Awarded by SNIC through the National Supercomputer Centre at Linkoping University (Tetralith)
Funding Acknowledgements
The crystallographic component of the research was supported by a research grant (LE100100109) from the Australian Research Council. MHC gratefully acknowledges funding support from the Swedish Energy Agency through grant no. 50529-1 and computation resources provided by SNIC through the National Supercomputer Centre at Linkoping University (Tetralith) under projects SNIC2021/5-474 and SNIC2021/5-305. No other external funding was directly associated with the research or preparation of manuscript.