Aqueous solvation dynamics studied by photon echo spectroscopy

Lang, Matthew J.; Jordanides, Xanthipe J.; Song, Xueyu; Fleming, Graham R.

doi:10.1063/1.478488

Cited by 131 publications

(172 citation statements)

References 59 publications

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“…For such a distribution of t 2 times to arise, non-equivalent relaxed CTTS configurations must not interconvert within the decay time, because we observe the same rise of B60 fs at all emission energies below B30,000 cm À 1 . Consistent with this are the characteristic response times of water, which contain a comparatively slower (B1 ps) component 29,30 , associated to collective long-range solvent rearrangements. Thus, it is the distribution of solvent shell configurations around I À that govern the electron-ejection rate.…”

Section: Discussionsupporting

confidence: 50%

Real-time observation of the charge transfer to solvent dynamics

et al. 2013

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Intermolecular electron-transfer reactions have a crucial role in biology, solution chemistry and electrochemistry. The first step of such reactions is the expulsion of the electron to the solvent, whose mechanism is determined by the structure and dynamical response of the latter. Here we visualize the electron transfer to water using ultrafast fluorescence spectroscopy with polychromatic detection from the ultraviolet to the visible region, upon photo-excitation of the so-called charge transfer to solvent states of aqueous iodide. The initial emission is short lived (B60 fs) and it relaxes to a broad distribution of lower-energy charge transfer to solvent states upon rearrangement of the solvent cage. This distribution reflects the inhomogeneous character of the solvent cage around iodide. Electron ejection occurs from the relaxed charge transfer to solvent states with lifetimes of 100-400 fs that increase with decreasing emission energy.

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Section: Discussionsupporting

confidence: 50%

Real-time observation of the charge transfer to solvent dynamics

et al. 2013

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“…Only 1% of the response occurs at intramolecular vibration frequencies, while the remaining 17% arises diffusely through the 100-800 cm K1 region. Interestingly, no response is found in the region of the water translational band near 180 cm K1 that is strongly coupled to the excitation in other chromophores (Lang et al 1999) but contributes only weakly to the intrinsic liquid density of states (Stern & Berne 2001), highlighting the danger in using known spectral responses of dissimilar compounds in modelling the Creutz-Taube ion. The calculated wavelength dependence of the solvation reorganization energy can be used to construct a realistic solvent model for use in non-adiabatic coupling simulations that recognize the tendency for the charge to delocalize in the Creutz-Taube ion.…”

Section: Modelling the Solvent Response To Charge-transfer Excitationmentioning

confidence: 99%

“…However, in reality, this function must decay to zero at infinite frequency, and so it is common to assume either ur(u)Zexp(Ku/u c ) for some critical frequency u c or similar analytical forms (Gilmore & McKenzie 2007); these all result in multi-exponential-like forms for the Stokes function S(t). Results obtained for energy relaxation in liquid water indicate that these simple forms are inappropriate, however, as water displays (Lang et al 1999) a range of responses peaking at frequencies of approximately 2-10 cm K1 (diffusive motions), 60 cm K1 (hydrogen-bonding bend), 180 cm K1 (hindered translation) and 600-800 cm K1 (libration) and displays intramolecular bending and stretching responses. Also, the relative propensities of each of these relaxation phenomena are clearly related to the shape and nature of the chromophore.…”

Section: Modelling the Solvent Response To Charge-transfer Excitationmentioning

confidence: 99%

“…We are, in particular, concerned instead with the reorganization-energy distribution function ur(u)Zj(u)/uZdl s /Zdu, where l s is the solvent reorganization energy (Passino et al 1997), In equation (2.3), the bar indicates thermal averaging over initial configurations of the solvent in equilibrium with the initial state of the chromophore, while excitation is assumed to occur as a result of application of a light pulse at time tZ0. The Stokes function, which by constraint takes on the limiting values Sð0ÞZ 1 and SðNÞZ 0, is typically dominated by multi-exponential decay functions depicting the dissipation of the optical energy into the solvent, although sinusoidal oscillations are also observed in S(t) reflecting long-lived energy transfer into specific intermolecular or solvent modes (Passino et al 1997;Lang et al 1999). The reorganization-energy distribution function ur(u) is finite at zero frequency, indicating that energy is transferred into very long-range motions in the solvent, and the simplest model of the effects of the fluid is the ohmic model, in which ur(u) is assumed to be a constant.…”

Section: Modelling the Solvent Response To Charge-transfer Excitationmentioning

confidence: 99%

“…The dynamics of the interaction of a chromophore with its solvent is an intense field of research using theoretical (Zwanzig 1973;Calderia & Legget 1983;Mukamel 1995;Fleming & Cho 1996;Gilmore & McKenzie 2007), simulation (Maroncelli 1990;Carter & Hynes 1991;Song & Chandler 1998;Stern & Berne 2001) and femtosecond-spectroscopic means (Reid et al 1995;Passino et al 1997;Lang et al 1999;Hettich et al 2002;Kuhn et al 2002). The quantity of most interest is the thermally averaged solvent density of states r(u) weighted by the chromophore-solvent coupling as a function of frequency u.…”

Section: Modelling the Solvent Response To Charge-transfer Excitationmentioning

confidence: 99%

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Towards a comprehensive model for the electronic and vibrational structure of the Creutz–Taube ion

Reimers

Wallace

Hush

2007

Phil. Trans. R. Soc. A.

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Since the synthesis of the Creutz-Taube ion, the nature of its charge localization has been of immense scientific interest, this molecule providing a model system for the understanding of the operation of biological photosynthetic and electron-transfer processes. However, recent work has shown that its nature remains an open question. Many systems of this type, including photosynthetic reaction centres, are of current research interest, and thereby the Creutz-Taube ion provides an important chemical paradigm: the key point of interest is the details of how such molecules behave. We lay the groundwork for the construction of a comprehensive model for its chemical and spectroscopic properties. Advances are described in some of the required areas including: simulation of electronic absorption spectra; quantitative depiction of the large interaction of the ion's electronic description with solvent motions; and the physics of Ru-NH 3 spectator-mode vibrations. We show that details of the solvent electron-phonon coupling are critical in the interpretation of the spectator-mode vibrations, as these strongly mix with solvent motions when 0.75!2J/l!1. In this regime, a double-well potential exists which does not support localized zero-point vibration, and many observed properties of the Creutz-Taube ion are shown to be consistent with the hypothesis that the ion has this character.

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