Experimental Evidence of Ultrafast Quenching of the <sup>3</sup>MLCT Luminescence in Ruthenium(II) Tris-bipyridyl Complexes via a <sup>3</sup>dd State

Sun, Qinchao; Mosquera-Vázquez, Sandra; Daku, Latévi Max Lawson; Guénée, Laure; Goodwin, Harold A.; Vauthey, Eric; Hauser, Andreas

doi:10.1021/ja407225t

Cited by 134 publications

(208 citation statements)

References 34 publications

(67 reference statements)

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“…Precise identification of species A and B is not possible, but the initial ultrafast processes are likely to involve internal conversion from the optically excited (ligand-centered) state to the 1 MLCT, intersystem crossing to the 3 MLCT state, and (vibrational and solvent) relaxation of the 3 MLCT state. 77 For the TAA-ph-Ru 2+ dyad very similar transient absorption spectra are obtained ( Figure S1), but the kinetics analysis yields time constants that are different from those obtained for TAAtmb-Ru 2+ . Specifically, 0.9 ps, 1.5 ps, ∼4 ns, and >5 ns are found; the respective SADS of an A → B → C → D → E reaction sequence are shown in Figure S2.…”

Section: The Journal Of Physical Chemistry Amentioning

confidence: 51%

Tetramethoxybenzene is a Good Building Block for Molecular Wires: Insights from Photoinduced Electron Transfer

et al. 2015

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Two donor bridge-acceptor molecules with terminal triarylamine and Ru(bpy)3(2+) (bpy = 2,2'-bipyridine) redox partners were synthesized and investigated by cyclic voltammetry, optical absorption, luminescence, and transient absorption spectroscopy. The two dyads differ only by the central bridging unit, which was tetramethoxybenzene (tmb) in one case and unsubstituted phenylene (ph) in the other case. Photoirradiation of the Ru(bpy)3(2+) complex of the two dyads triggers intramolecular electron transfer from the triarylamine to the (3)MLCT-excited metal complex, and this process occurs with time constants of 1.5 and 6.8 ns for the tmb- and ph-bridged dyads, respectively. Thermal electron transfer in the reverse direction then leads to disappearance of the photoproduct with a time constant of 10 ns in both dyads. The faster rate of photoinduced charge transfer in the tmb-bridged dyad can be understood in the framework of a hole-tunneling model in which the electron-rich tmb bridge imposes a more shallow barrier than the less electron-rich ph spacer. Until now tmb-based molecular wires have received very little attention, and alkoxy substituents have been mostly used for improving the solubility of oligo-p-phenylene vinylene (OPV) and oligo-p-phenylene ethynylene (OPE) wires. Our study illustrates how four alkoxy-substituents on a phenylene backbone can have a significant influence on the charge-transfer properties of a molecular wire, and this is relevant in the greater context of a future molecular electronics technology.

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Section: The Journal Of Physical Chemistry Amentioning

confidence: 51%

Tetramethoxybenzene is a Good Building Block for Molecular Wires: Insights from Photoinduced Electron Transfer

et al. 2015

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“…These observations suggest a basis for selecting Ru photosensitizers with lower energy 3 MLCT than 3 MC excited states: the 77 K MLCT emission maximum of the sensitizer should have a lower energy than the energy for breaking both Ru−ligand bonds along the weakest bonding axis. 21 The point for [Ru(bpy) 3 ] 2+ is based on 3 MC calculations reported by Sun et al, 15 and 77 K emission spectra reported by Thomas et al 21 The code numbers in panel A are from The Supporting Information is available free of charge on the…”

Section: ■ Conclusionmentioning

confidence: 99%

“…23 As these authors note, the only experimental observations that relate to the role of 3 MC states are based on the time difference between 3 MLCT absorption decay and ground state absorption recovery, complemented by density functional theory (DFT) calculations to demonstrate that 3 MLCT and 3 MC excited states are near in energy, that IC can greatly alter 3 MLCT lifetimes, and that the relative energies of these excited states can be stereochemically manipulated for some [Ru(PP) 3 ] 2+ , where PP = bipyridine (bpy) or a methyl-substituted bipyridine. 15 We have approached this problem using DFT modeling 18−21 of the triplet excited states in combination with emission spectroscopic observations. We use a contemporary version of Gaussian 24 that incorporates the Franck−Condon approximation, as developed by Barone and co-workers.…”

Section: ■ Introductionmentioning

confidence: 99%

Metal-to-Ligand Charge-Transfer Emissions of Ruthenium(II) Pentaammine Complexes with Monodentate Aromatic Acceptor Ligands and Distortion Patterns of their Lowest Energy Triplet Excited States

et al. 2015

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This is the first report of the 77 K triplet metal-to-ligand charge-transfer ((3)MLCT) emission spectra of pentaammine-MDA-ruthenium(II) ([Ru(NH3)5(MDA)](2+)) complexes, where MDA is a monodentate aromatic ligand. The emission spectra of these complexes and of the related trans-[Ru(NH3)4(MDA) (MDA')](2+) complexes are closely related, and their emission intensities are very weak. Density functional theory (DFT) calculations indicate that the energies of the lowest (3)MLCT excited states of Ru-MDA complexes are either similar to or lower than those of the lowest energy metal-centered excited states ((3)MC(X(Y))), that the barrier to internal conversion at 77 K is large compared to kBT, and that the (3)MC(X(Y)) excited states are weakly bound. The [Ru(NH3)5py](2+) complex is an exception to the general pattern: emission has been observed for the [Ru(ND3)5(d5-py)](2+) complex, but its lifetime is apparently very short. DFT modeling indicates that the excited state distortions of the different (3)MC excited states are very large and are in both Ru-ligand bonds along a single Cartesian axis for each different (3)MC excited state, nominally resulting in (3)MC(X(Y)), (3)MC((X)Y), and (3)MC(Z) lowest energy metal-centered states. The (3)MC(X(Y)) and (3)MC((X)Y) states appear to be the pseudo-Jahn-Teller distorted components of a (3)MC((XY)) state. The (3)MC(X(Y)) states are distorted up to 0.5 Å in each H3N-Ru-NH3 bond along a single Cartesian axis in the pentaammine and trans-tetraammine complexes, whereas the (3)MC(Z) states are found to be dissociative. DFT modeling of the (3)MLCT excited state of [Ru(NH3)5(py)](2+) indicates that the Ru center has a spin density of 1.24 at the (3)MLCT energy minimum and that the (3)MLCT → (3)MC(Z) crossing is smooth with a very small barrier (<0.5 kcal/mol) along the D3N-Ru-py distortion coordinate, implying strong (3)MLCT/(3)MC excited state configurational mixing. Furthermore, the DFT modeling indicates that the long-lived intermediate observed in earlier flash photolysis studies of [Ru(NH3)5py](2+) is a Ru(II)-(η(2)(C═C)-py) species.

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“…71 The present work underlines one more time that the same energy gap does not warrant similar radiationless rate constants, and that the nature of the states involved, including vibronic and relativistic effects, should be taken into account. [58][59][60] Finally, a detailed understanding of the dynamics of low-lying MC states is needed for elucidating their role in the relaxation cascades of transition metal complexes, 11,13,72 which in applications typically originate from one of high-energy CT states formed by absorption in the visible range.…”

Section: -mentioning

confidence: 99%

Probing the Fate of Lowest-Energy Near-Infrared Metal-Centered Electronic Excited States: CuCl₄^2–and IrBr₆^2–

et al. 2015

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Ultrafast transient absorption spectroscopy is used to investigate the radiationless relaxation dynamics of CuCl4(2-) and IrBr6(2-) complexes directly promoted into their lowest-energy excited metal-centered states upon near-infrared femtosecond excitation at 2000 nm. Both the excited CuCl4(2-) (2)E and IrBr6(2-) (2)Ug'(T2g) states undergo internal conversion to the ground electronic states, yet with significantly different lifetimes (55 fs and 360 ps, respectively) despite the fact that the (2)E and (2)Ug'(T2g) states are separated by the same energy gap (∼5000 cm(-1)) from the respective ground state. This difference likely arises from the predominance of the Jahn-Teller effect in a Cu(2+) ion and the spin-orbit coupling effect in an Ir(4+) ion. The approach documented in this work may be used for elucidating the role of low-energy metal-centered states in relaxation cascades of a number of coordination compounds, allowing for design of efficient light-triggered metal complexes.

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Experimental Evidence of Ultrafast Quenching of the ³MLCT Luminescence in Ruthenium(II) Tris-bipyridyl Complexes via a ³dd State

Cited by 134 publications

References 34 publications

Tetramethoxybenzene is a Good Building Block for Molecular Wires: Insights from Photoinduced Electron Transfer

Tetramethoxybenzene is a Good Building Block for Molecular Wires: Insights from Photoinduced Electron Transfer

Metal-to-Ligand Charge-Transfer Emissions of Ruthenium(II) Pentaammine Complexes with Monodentate Aromatic Acceptor Ligands and Distortion Patterns of their Lowest Energy Triplet Excited States

Probing the Fate of Lowest-Energy Near-Infrared Metal-Centered Electronic Excited States: CuCl₄^2–and IrBr₆^2–

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Experimental Evidence of Ultrafast Quenching of the 3MLCT Luminescence in Ruthenium(II) Tris-bipyridyl Complexes via a 3dd State

Cited by 134 publications

References 34 publications

Tetramethoxybenzene is a Good Building Block for Molecular Wires: Insights from Photoinduced Electron Transfer

Tetramethoxybenzene is a Good Building Block for Molecular Wires: Insights from Photoinduced Electron Transfer

Metal-to-Ligand Charge-Transfer Emissions of Ruthenium(II) Pentaammine Complexes with Monodentate Aromatic Acceptor Ligands and Distortion Patterns of their Lowest Energy Triplet Excited States

Probing the Fate of Lowest-Energy Near-Infrared Metal-Centered Electronic Excited States: CuCl42–and IrBr62–

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Experimental Evidence of Ultrafast Quenching of the ³MLCT Luminescence in Ruthenium(II) Tris-bipyridyl Complexes via a ³dd State

Probing the Fate of Lowest-Energy Near-Infrared Metal-Centered Electronic Excited States: CuCl₄^2–and IrBr₆^2–