Electronic spectra of RMn(CO)3(α-diimine) (RH, CH3): a CASSCF/CCI comparative study of the lowest singlet excited states

Daniel, Chantal; Matsubara, T.; Stor, G.J.

doi:10.1016/0010-8545(94)80025-1

Cited by 5 publications

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“…Quite recently, the spectroscopy, photophysics, and photochemistry of a series of complexes M(L)(CO) 3 (α-diimine) (M = Mn, Re), in which L represents a metal fragment or an alkyl group bound to the metal by a high-lying σ orbital, have been studied in detail. − From these studies, it was concluded that mainly d π (M) → π*(α-diimine) (metal-to-ligand-charge-transfer: MLCT) transitions contribute to the absorption spectra, but that decay to the ground state and homolytic cleavage of the metal−L bond take place from a close low-lying σ M - L → π*(α-diimine) (sigma-bond-to-ligand-charge-transfer: 3 σπ* or 3 SBLCT) excited state. To rationalize the experimental data, a few theoretical investigations, based either on DFT calculations , or on accurate CASSCF/MR-CCI calculations, , have been performed. Recently, the potential energy curves corresponding to the 1 A‘ electronic ground state and to the low-lying 3 A‘ excited states have been computed for the model complex Mn(H)(CO) 3 (H-DAB) as a function of q a = [Mn−H] and q b = [Mn−CO ax ] under the C s symmetry constraint .…”

Section: Introductionmentioning

confidence: 99%

Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)₃(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)

Guillaumont¹,

Wilms²,

Daniel³

et al. 1998

Inorg. Chem.

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The lowest energy electronic transitions of the model complexes M(R)(CO)3(H-DAB) (M = Mn, R = H, CH3,C2H5; M = Re, R = H, α-diimine = H-DAB = 1,4-diaza-1,3-butadiene) are investigated with the use of CASSCF/MR-CCI calculations. On the basis of the excitation energies calculated for the low-lying nd → π*DAB (metal-to-ligand-charge-transfer), σM - R → π*DAB (sigma-bond-to-ligand-charge-transfer), and nd → nd (metal-centered) excited states, it is shown how the three-center interaction between the R group, the metal center, and the π* acceptor DAB ligand controls the nature and the energies of the lowest electronic transitions of these molecules. In the manganese hydride complex, the low-lying excited states are nearly pure, corresponding either to MLCT states in the visible energy domain between 15 090 and 26 000 cm-1 or to SBLCT states calculated at 34 390 and 37 950 cm-1 for the triplet and for the singlet components, respectively. The calculated oscillator strengths indicate a large contribution of the second MLCT state, corresponding to the 3d xz → π*DAB excitation, to the intense visible band observed in this class of complexes. The transitions to the singlet and triplet MC excited states are calculated at 35 900 and 26 380 cm-1, respectively, and will contribute to the UV absorption together with those to the SBLCT states. On going from the hydride to the methyl complex, the main change is a drastic lowering of the transition energies, which may exceed 0.5 eV for the SBLCT states. This effect is largely due to the weakening of the metal−R bond, the basicity of CH3 -, and the more polarized character of the metal−methyl bond. On going from the methyl to the ethyl complex, the SBLCT transitions are still lowered in energy, due to the weakening of the metal−R bond, but the excitation energies to the MLCT states are not significantly affected. This is a consequence of the more covalent character of the metal−ethyl bond as compared to the metal−methyl bond. The substitution of hydrogen by an alkyl group is accompanied not only by a red shift of the low-lying MLCT states from 15 090−26 000 to 13 690−20 410 cm-1 but also by an increase in the density of states in the visible energy domain. The second effect that will affect the photophysics and the photochemistry within the molecular series implies an important mixing between the MLCT and SBLCT excited states. A comparison between the lowest part of the spectrum of Mn(H)(CO)3(H-DAB) and Re(H)(CO)3(H-DAB) points to a large influence of the metal center, mainly due to the relativistic destabilization of the d shells and the stabilizing interaction between the π*DAB and the 6p z of the metal center. The consequences are a stabilization of the excited states calculated between 12 600−27 650 cm-1 (triplet components) and 15 250−31 340 cm-1 (singlet components) and a significant mixing between the MLCT and SBLCT states.

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Section: Introductionmentioning

confidence: 99%

Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)₃(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)

Guillaumont¹,

Wilms²,

Daniel³

et al. 1998

Inorg. Chem.

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Quantum chemistry and Dick Stufkens photochemistry

Daniel

2002

Coordination Chemistry Reviews

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Spectroscopic and electrochemical properties of [Mn(phen)(CO)3(imidazole)](SO3CF3) complexes

Carlos

Neto

et al. 2000

Inorganica Chimica Acta

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Electronic spectra of RMn(CO)3(α-diimine) (RH, CH3): a CASSCF/CCI comparative study of the lowest singlet excited states

Abstract: Electronic spectra of RMn(CO)sub3(alpha-diimine) (R=H,CHsub3): a CASSCF/CCI comparative study of the lowest singlet excited states Daniel, C.; Matsubara, T.; Stor, G.J.

Cited by 5 publications

References 36 publications

Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)₃(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)

Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)₃(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)

Quantum chemistry and Dick Stufkens photochemistry

Spectroscopic and electrochemical properties of [Mn(phen)(CO)3(imidazole)](SO3CF3) complexes

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Electronic spectra of RMn(CO)3(α-diimine) (RH, CH3): a CASSCF/CCI comparative study of the lowest singlet excited states

Abstract: Electronic spectra of RMn(CO)sub3(alpha-diimine) (R=H,CHsub3): a CASSCF/CCI comparative study of the lowest singlet excited states Daniel, C.; Matsubara, T.; Stor, G.J.

Cited by 5 publications

References 36 publications

Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)3(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)

Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)3(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)

Quantum chemistry and Dick Stufkens photochemistry

Spectroscopic and electrochemical properties of [Mn(phen)(CO)3(imidazole)](SO3CF3) complexes

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Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)₃(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)

Variation in Charge-Transfer Photochemistry Clarified by a CASSCF/MR-CCI Comparative Study of the Low-Lying Excited States of M(R)(CO)₃(H-DAB) (M = Mn, R = H, Methyl, Ethyl; M = Re, R = H; DAB = 1,4-Diaza-1,3-butadiene)