Formation and Structure of Rh(0) Complexes of Phosphinine-Containing Macrocycles:  EPR and DFT Investigations

Electrochemical and chemical reductions of Rh(I) complexes of L P4 (a macrocycle containing four phosphinine rings) and of L P2S2 (a macrocycle containing two phosphinine rings and two thiophene rings) lead, in liquid solution, to EPR spectra exhibiting large hyperfine couplings with 31P nuclei. An...

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Published in:The journal of physical chemistry. A, Molecules, spectroscopy, kinetics, environment, & general theory Molecules, spectroscopy, kinetics, environment, & general theory, 2002-03, Vol.106 (12), p.3017-3022
Main Authors: Cataldo, Laurent, Choua, Sylvie, Berclaz, Théo, Geoffroy, Michel, Mézailles, Nicolas, Avarvari, Narcis, Mathey, François, Le Floch, Pascal
Format: Article
Language:English
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Summary:Electrochemical and chemical reductions of Rh(I) complexes of L P4 (a macrocycle containing four phosphinine rings) and of L P2S2 (a macrocycle containing two phosphinine rings and two thiophene rings) lead, in liquid solution, to EPR spectra exhibiting large hyperfine couplings with 31P nuclei. An additional coupling (27 MHz) with 103Rh is detected, in the liquid state, for the spectrum obtained with [L P2S2 Rh (0) ]; moreover, resolved 31P hyperfine structure is observed in the frozen solution spectrum of this latter complex. DFT calculations performed on Rh(I) complexes of model macrocycles L‘ P4 and L‘ P2S2 indicate that, in these systems, the metal coordination is planar and that one-electron reduction induces a small tetrahedral distortion. The calculated couplings, especially the dipolar tensors predicted for [L‘ P2S2 Rh (0) ], are consistent with the experimental results. Although the unpaired electron is mostly delocalized on the ligands, the replacement of two phosphinines by two thiophenes tends to increase the rhodium spin density (ρRh =0.35 for [L‘ P2S2 Rh (0) ]). It is shown that coordination to Rh as well as one-electron reduction of the resulting complex provoke appreciable changes in the geometry of the macrocycle.
ISSN:1089-5639
1520-5215
DOI:10.1021/jp014339z