EPR and DFT Studies of the Structure of Phosphinyl Radicals Complexed by a Pentacarbonyl Transition Metal

Ndiaye, B.; Bhat, Shrinivasa; Jouaiti, Abdelaziz; Berclaz, Théo; Bérnardinelli, Gerald; Geoffroy, Michel

doi:10.1021/jp061960w

Cited by 33 publications

(29 citation statements)

References 38 publications

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“…It is worthwhile mentioning that irradiation of crystals of Mo(CO) 5 PPh 3 leads to the detection of the main species expected from common mechanisms in radiation chemistry: (1) formation of the radical cation, which is not stable above 100 K, (2) formation of the radical anion, which results from the capture of a thermalized electron by a surrounding neutral molecule; this anion could be detected even after annealing at 300 K [36], (3) formation at room temperature of a radical species due to the homolytic scission of an organic bond; in this case (CO) 5 Mo-PPh 2 [17]. …”

Section: Discussionmentioning

confidence: 99%

“…[16]. As previously explained, the crystal was glued on a small brass cube with Y//c* and a*//ÀX (the crystallographic axes correspond to the reduced cell) [17]; then it was immersed in liquid nitrogen and exposed at 77 K for 2 h to the radiation of a X-rays tube (PW Phillips tube, tungsten anticathode, 30 kV, 30 mA). Any increase in the temperature of the sample was carefully avoided, the crystal was transferred to a finger dewar, and positioned in the EPR cavity of a Bruker 300 spectrometer (X-band).…”

Section: Methodsmentioning

confidence: 99%

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Single-crystal EPR study and DFT structure of the [Mo(CO)5PPh3]+· radical cation

Sidorenkova

Berclaz

Ndiaye

et al. 2009

Journal of Physics and Chemistry of Solids

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a b s t r a c tA radical species characterized by a large g-anisotropy and a clearly resolved hyperfine structure with 95/97 Mo and 31 P nuclei is formed, at 77 K, by radiolysis of a single crystal of Mo(CO) 5 PPh 3 . The corresponding EPR signals disappear irreversibly with increasing temperature and the angular dependence of the various coupling constants imply a spin delocalization of $60% and $4% on the molybdenum and the phosphorus atoms, respectively and are, a priori, consistent with the trapping of a one-electron deficient centre. The ability of DFT to predict the EPR tensors for a 17-electron Mo (I) species is verified by calculating the g-tensor and the various 14 N and 13 C coupling tensors previously reported by Hayes for [Mo(CN) 5 NO] 3À . Calculations at the B3LYP/ZORA/SOMF level of theory show that, in contrast to Mo(CO) 5 PH 3 , one-electron oxidation of Mo(CO) 5 PPh 3 causes an appreciable change in the geometry of the complex. The g-tensor and the 95/97 Mo and 31 P isotropic and anisotropic coupling constants calculated for [Mo(CO) 5 PPh 3 ] + Á confirm the trapping of this species in the irradiated crystal of Mo(CO) 5 PPh 3 ; they also show that the conformational modifications induced by the electron release are probably hindered by the nearby complexes.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Single-crystal EPR study and DFT structure of the [Mo(CO)5PPh3]+· radical cation

Sidorenkova

Berclaz

Ndiaye

et al. 2009

Journal of Physics and Chemistry of Solids

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“…It is generally admitted that these intermediates can be divided into two main classes [3,4]: (i) organic radicals coordinated to a transition metal complex [5], (ii) paramagnetic complexes with a considerable localisation of the unpaired electron on the metal. We have recently shown that (CO) 5 M-Å PR 2 , a species of the former class, can be formed from M(CO) 5 PR 3 (with M = Cr, Mo, W) [6]. Here, we show that, by changing the experimental conditions, the same precursor can lead to a metal-centred radical anion [M(CO) 4 PR 3 ] ÅÀ .…”

Section: Introductionmentioning

confidence: 61%

“…[6], at room temperature, single crystals of W(CO) 5 PPh 3 , Mo(CO) 5 PPh 3 and Cr(CO) 5 PPh 3 previously irradiated at 300 K, showed only the signals due to the trapping of the phosphinyl radical linked to the pentacarbonylmetal: (CO) 5 M-Å PPh 2 . However, these spectra drastically changed when the crystals, previously irradiated at 300 K, were studied at 77 K. Probably due to saturation, the lines assigned to (CO) 5 M-Å PPh 2 considerably decreased in intensity, while new signals clearly appeared on the spectra; moreover, the above described signals A and B, generated by irradiation at 77 K, were not detected.…”

Section: Epr Spectramentioning

confidence: 96%

[M(CO)4PPh3]− radicals (M=Cr, Mo, W): DFT and single crystal EPR investigations

Berclaz

Ndiaye

Bhat

et al. 2007

Chemical Physics Letters

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“…6). [12] Stimulated by the recent developments in molecular electronics, the EPR group simultaneously intensified its efforts in three directions: i) The design of molecular systems capable of accepting or losing a single electron and delocalizing the resultant unpaired spin over a large part of the molecule. Most of these new compounds were based on phosphorus compounds with a low coordination number ( Fig.…”

Section: Magnetic Resonance Spectroscopymentioning

confidence: 99%