Ultrafast Charge-Transfer-to-Solvent Dynamics of Iodide in Tetrahydrofuran. 2. Photoinduced Electron Transfer to Counterions in Solution

Bragg, Arthur E.; Schwartz, Benjamin J.

doi:10.1021/jp712039u

Cited by 32 publications

(43 citation statements)

References 72 publications

(278 reference statements)

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“…As the CTTS state and the ground state of the solvated electron have a similar, s-like symmetry, each CTTS state likely evolves on a singlepotential energy surface all the way to the aqueous electron. This contrasts to the behaviour of, for example, Na À , whose CTTS state has a reversed, p-like symmetry such that a non-adiabatic transition is required to go from the reactant to the product state 13 . However, our findings show that the characteristic time scale of the dynamics (ultimately, the fluorescence lifetime) changes from excited ionic centre to the next because it strongly depends on the structure of the surrounding solvation cage at the time of photo-excitation.…”

Section: Discussionmentioning

confidence: 84%

“…The valence electrons of ground-state anions are bound by the nucleus, but the excited states are bound by solvent polarization 1 . The CTTS states of halides rapidly decay by ejection of an electron, which is then stabilized by solvation, leaving a neutral halogen atom behind [2][3][4][5][6][7][8][9][10][11][12][13][14] . Atomic anions are ideal for studies of the electron-transfer dynamics to the solvent, because the solute lacks internal (nuclear) degrees of freedom, such that the process of CTTSmediated electron ejection is entirely governed by the structure and motions of the solvation shell.…”

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confidence: 99%

“…Femtosecond X-ray absorption spectroscopy at the I L-edges detected the birth of the neutral halogen, but the time resolution was not sufficient to capture the early dynamics 7 . Of particular relevance here are the studies by Ruhman et al 11,12 and Schwartz et al 13,14,[22][23][24][25] on the CTTS states of sodide (Na À ) in tetrahydrofuran (THF) and ether solvents, which enabled them to probe at high-time resolution both the signal of the ejected electron and the nascent neutral sodium atom. They found that electrons photodetached from the parent ion appear with their equilibrium spectrum after 500 fs with no further spectral evolution, nor a pump wavelength dependence.…”

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confidence: 99%

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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: Discussionmentioning

confidence: 84%

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confidence: 99%

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confidence: 99%

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Real-time observation of the charge transfer to solvent dynamics

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“…Our preliminary simulation studies of this system found that Na 0 clearly exists as a TCP in liquid THF, 18 in agreement with experimental interpretations. [1][2][3][4][13][14][15]19 In this work, we explore the molecular nature of the sodium TCP in significantly more detail. We find that the driving force for TCP formation lies in the creation of a tight solvation shell of ∼4 THF oxygens around the partially exposed Na + end of the TCP.…”

Section: Introductionmentioning

confidence: 99%

Nature of Sodium Atoms/(Na⁺, e⁻) Contact Pairs in Liquid Tetrahydrofuran

2010

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With no internal vibrational or rotational degrees of freedom, atomic solutes serve as the simplest possible probe of a condensed-phase environment's influence on solute electronic structure. Of the various atomic species that can be formed in solution, the quasi-one-electron alkali atoms in ether solvents have been the most widely studied experimentally, primarily due to the convenient location of their absorption spectra at visible wavelengths. The nature of solvated alkali atoms, however, remains controversial: the consensus view is that solvated alkali atoms exist as (Na + , e -) tight-contact pairs (TCPs), species in which the alkali valence electron is significantly displaced from the alkali nucleus and confined primarily by the first solvent shell. Thus, to shed light on the nature of alkali atoms in solution and to further our understanding of condensedphase effects on solutes' electronic structure, we have performed mixed quantum/classical molecular dynamics simulations of sodium atoms in liquid tetrahydrofuran (Na 0 /THF). Our interest in this particular system stems from recent pump-probe experiments in our group, which found that the rate at which this species is solvated depends on how it was created (Science 2008, 321, 1817); in other words, the solvation dynamics of this system do not obey linear response. Our simulations reproduce the experimental spectroscopy of this system and clearly indicate that neutral Na atoms exist as (Na + , e -) TCPs in solution. We find that the driving force for the displacement of sodium's valence electron is the formation of a tight solvation shell around the partially exposed Na + . On average, four THF oxygens coordinate the cation end of the TCP; however, we also observe fluctuations to other solvent coordination numbers. Furthermore, we find that species with different solvent coordination numbers have unique absorption spectra and that interconversion between species with different solvent coordination numbers requires surmounting a free energy barrier of several k B T. Taken together, our results suggest that the Na 0 /THF species with different solvent coordination numbers may be viewed as chemically distinct. Thus, we can explain the kinetics of Na TCP formation as being dictated by changes in the Na + solvent coordination number, and we can understand the dependence on initial conditions seen in the solvation dynamics of this system as resulting from the fact that the important solvent coordinate involves the motion of only a few molecules in the first solvation shell.

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“…[14][15][16][17] For example, in the red-edge excitation of anions such as I − in THF, coupling of the local charge-transfer-to-solvent ͑CTTS͒ excited state to solvent-supported disjoint states with similar energies leads to photoejection of electrons to significant distances ͑ϳ6 nm͒ from the parent anion. 16 Another experimental signature of cavities is that the detached electrons produced after exciting nearly any anion in liquid THF-I − , 17 Na − , 14 K − , 18 or even the solvated electron itself 19 -appear after a ϳ0.5 ps time delay with their equilibrium spectrum. 20 This indicates that excited electrons relax directly into pre-existing solvent traps from the initially prepared solvent-supported excited state.…”

Section: Introductionmentioning

confidence: 99%

Searching for solvent cavities via electron photodetachment: The ultrafast charge-transfer-to-solvent dynamics of sodide in a series of ether solvents

Larsen

Schwartz

2009

The Journal of Chemical Physics

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It was recently predicted by simulations and confirmed by neutron diffraction experiments that the structure of liquid tetrahydrofuran (THF) contains cavities. The cavities can be quite large and have a net positive electrostatic potential, so they can serve as pre-existing traps for excess electrons created via photodetachment from various solutes. In this paper, we use electron photodetachment via charge-transfer-to-solvent (CTTS) excitation of sodide (Na(-)) to probe for the presence of pre-existing cavities in a series of ether solvents: THF, diethyl ether, 1,2-dimethoxyethane (DME), and diglyme (DG). We find that electrons photodetached from sodide appear after a time delay with their equilibrium spectrum in all of these solvents, suggesting that the entire series of ethers contains pre-existing solvent cavities. We then use the variation in electron recombination dynamics with CTTS excitation wavelength to probe the nature of the cavities in the different ethers. We find that the cavities that form the deepest electron traps turn on at about the same energy in all four ether solvents investigated, but that the density of cavities is lower in DG and DME than in THF. We also examine the dynamics of the neutral sodium species that remains following CTTS photodetachment of an electron from sodide. We find that the reaction of the initially created gas-phase-like Na atom to form a (Na(+),e(-)) tight-contact pair occurs at essentially the same rate in all four ether solvents, indicating that only local solvent motions and not bulk solvent rearrangements are what is responsible for driving the partial ejection of the remaining Na valence electron.

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Ultrafast Charge-Transfer-to-Solvent Dynamics of Iodide in Tetrahydrofuran. 2. Photoinduced Electron Transfer to Counterions in Solution

Cited by 32 publications

References 72 publications

Real-time observation of the charge transfer to solvent dynamics

Real-time observation of the charge transfer to solvent dynamics

Nature of Sodium Atoms/(Na⁺, e⁻) Contact Pairs in Liquid Tetrahydrofuran

Searching for solvent cavities via electron photodetachment: The ultrafast charge-transfer-to-solvent dynamics of sodide in a series of ether solvents

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Ultrafast Charge-Transfer-to-Solvent Dynamics of Iodide in Tetrahydrofuran. 2. Photoinduced Electron Transfer to Counterions in Solution

Cited by 32 publications

References 72 publications

Real-time observation of the charge transfer to solvent dynamics

Real-time observation of the charge transfer to solvent dynamics

Nature of Sodium Atoms/(Na+, e−) Contact Pairs in Liquid Tetrahydrofuran

Searching for solvent cavities via electron photodetachment: The ultrafast charge-transfer-to-solvent dynamics of sodide in a series of ether solvents

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Nature of Sodium Atoms/(Na⁺, e⁻) Contact Pairs in Liquid Tetrahydrofuran