Reaction rates of electrons in liquid methanol and ethanol: effects of pressure

Bolton, Gerald L.; Robinson, M. G.; Freeman, Gordon R.

doi:10.1139/v76-167

Cited by 20 publications

(8 citation statements)

References 14 publications

(17 reference statements)

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“…Electron capture by toluene, and probably by allyl alcohol, is stabilized by protonation (26,27): [4] S-, + ROH + i~ + RO-, Reaction [4] involves the rotation of solvent dipoles adjacent to the reaction site as the charge center changes from S-to RO-; the reaction rate should correlate with the dielectric relaxation For personal use only. (14,15).…”

Section: Oooit (K)mentioning

confidence: 99%

Electron behavior in mixed solvents: optical spectra and reactivities in water/alkane diols

Idriss-Ali¹,

Freeman²

1984

Can. J. Chem.

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Investigation of the effect of solvent structure on the optical absorption spectrum and reactivity of solvated electrons has been extended to diol/water mixed solvents, using 1,2-ethanediol (12ED) and 1,4-butanediol (14BD). The large effects that had been found in mono-ol/water mixed solvents did not occur in diol/water. Although addition of 3 mol% of a diol to water increased the optical absorption energies of e−s by 0.06 eV, similar to the shift caused by addition of 3 mol% of a mono-ol, the variation of the spectrum over the rest of the composition range was nearly ideal in diol/water, in contrast to the very non-ideal variation in mono-ol/water. Reaction rate constants kS at 298 K in the diol/water mixed solvents vary approximately as the inverse viscosity,η−1.0, in the diffusion-controlled limit. However, when reactions are two or three orders of magnitude slower than diffusion controlled, kS at 298 K is independent of η. Toluene reacts with e−s at a 10−3-fold smaller rate than does nitrobenzene; the difference is nearly completely due to a ~50 J/mol K lower entropy of activation of the former reaction.

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Section: Oooit (K)mentioning

confidence: 99%

Electron behavior in mixed solvents: optical spectra and reactivities in water/alkane diols

Idriss-Ali¹,

Freeman²

1984

Can. J. Chem.

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“…Possible exceptions are e; + ROH + H + RO; and e; + ROH;, + H + ROH in water and alcohols, where a proton from a solvating -OH or -OH; group might transfer to the site of the electron (3). Proton transfer to the "cavity" of the electron site might avoid the work needed to create a new site for the H atom if the electron were to transfer first, followed by decomposition of the transient ROH-or ROH2.…”

Section: Introductionmentioning

confidence: 99%

Solvent effects on the reactivity of solvated electrons with ions in isobutanol/water mixed solvents

Chen¹,

Avotinsh²,

Freeman³

1994

Can. J. Chem.

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RUZHONG CHEN, YURIS AVOTINSH, and GORDON R. FREEMAN. Can. J. Chem. 72, 1083 (1994.The effective reaction radii a,, where R, is the reactive encounter radius and K is the probability of reaction per encounter, for e; with H: , NH,',,, Ag:, Cu?, and NOT, are all 0.7 f 0.1 nm in isobutanol containing 1G20 mol% water. The value remains at 0.7 f 0.1 nm for H: , Ag:, and Cu? in pure isobutanol, and for the two transition metal ions in pure water solvent.The value for NO;, reduces to 0.35 nm in pure isobutanol and pure water solvents, whereas for H: and NH;, in pure water solvent it is only 0.14 nm and 2.6 x nm, respectively. The low reactivity of NH,',, with e; in water is attributed to the symmetry of the hydrogen-bonded solvation structure of NH; in water, and the higher reactivity of H: (OH;,,) is attributed to the lower symmetry of its hydrogen-bonded solvation structure. The NH,' and OH; ions have no low-lying orbital for an electron to occupy, so either reaction occurs by proton transfer to the electron site or the neutral species must decompose. We suggest that the proton transfer or the decomposition of the neutral species is facilitated by an unsymmetrical solvation structure.Reaction of e; in A1(C104)3 solutions in water is due mainly to H: from hydrolysis of Alp, and partly to partially hydroxylated aluminum(II1) species. Reaction of e; with A12 itself appears to be negligible in water. The reactivity of the solutions of Al(C104)3 in isobutanol-rich solvents is 3-5 times greater than that in water.In pure CI to C4 1-alcanol solvents the value of k2(e; +NO,,) increases linearly with the dielectric relaxation time z, of the solvent. In these solvents the probability of permanent capture per encounter increases approximately as the square of the encounter duration. On attribue la faible rCactivitC du NH,',, avec les e; dans l'eau i la symCtrie de la structure de solvatation comportant des liaisons hydrogknes du NH,',, dans l'eau et on attribue la rCactivitC plus ClevCe des H: (OH;,) B la symCtrie plus faible de sa structure de solvatation comportant une liaison hydrogkne. Les ions NH; et OH; n'ont aucune orbitale de bas niveau pour accommoder un Clectron; la rkaction se produit donc par un transfert de proton vers un site dlClectron ou les espkces neutres doivent se dicomposer. On suggkre que le transfert de proton ou la dCcomposition d'espkces neutres est rendu plus facile par une structure de solvatation qui n'est pas symttrique.La rCaction des e; dans des solutions de A1(C104)3 dans l'eau est principalement due aux H: provenant de l'hydrolyse

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“…We have focused our attention on (i) the prevailing trajectory of IR prehydrated electrons, and (ii) the role of early branchings between reactive (eq 1a) and nonreactive (eq 1b) channels. Due to the low C 37 value of aqueous Cd 2+ , the computed kinetic model investigates a prehydration one-electron reduction of Cd 2+ . This ultrafast redox channel would be triggered by an electron photodetachment from excited aqueous chloride ions with a probability P Reac (eq 3).…”

Section: Resultsmentioning

confidence: 99%

“…In polar solutions, intermolecular electron transfer faster than the picosecond solvation process has been investigated by fluorescence up-conversion − but up to now competitive nonreactive electron dynamics (electron solvation) and ultrafast presolvation radical reactions in water have not be investigated at very short times. Nanosecond and picosecond pulse radiolysis studies have suggested that ultrafast radical reaction (univalent reduction of a solute) would involve hot electrons or short-lived precursors of hydrated electron. − These indirect investigations determine the subnanosecond G value of solvated electrons for different electron scavenger concentrations. The pulse radiolysis experiments treat the data by determining empirical relationships between the rate constant of an electron transfer and the C 37 value, − or stochastic analysis of competitive electron solvation and electron capture .…”

Section: Introductionmentioning

confidence: 99%

“…Nanosecond and picosecond pulse radiolysis studies have suggested that ultrafast radical reaction (univalent reduction of a solute) would involve hot electrons or short-lived precursors of hydrated electron. − These indirect investigations determine the subnanosecond G value of solvated electrons for different electron scavenger concentrations. The pulse radiolysis experiments treat the data by determining empirical relationships between the rate constant of an electron transfer and the C 37 value, − or stochastic analysis of competitive electron solvation and electron capture . The investigations of ultrafast electron transfers at the macroscopic level do not permit one (i) to understand in detail presolvation intermolecular charge transfer, and (ii) to determine the exact nature of early branching between short-lived nonreactive and reactive electronic configurations.…”

Section: Introductionmentioning

confidence: 99%

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Ultrafast Reactivity of IR-Excited Electron in Aqueous Ionic Solutions

1998

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An ultrafast presolvation reaction involving IR-excited hydrated electrons and bivalent metal cations (Cd2+)aq was investigated at the femtosecond time scale. The initial electron photodetachment is triggered by a two-photon UV excitation of aqueous chloride ions (R = [H2O]/[XCl2] = 110). The photodetached electron reaches a IR p-like state (prehydrated electron) with a time constant of 130 fs at 294 K. In the presence of nonreactive divalent alkaline metal cations (X2+ = Mg2+), this transient IR electronic state exhibits a deactivation process toward the ground state of hydrated electron (s state) with a time constant of 300 ± 20 fs. In aqueous CdCl2 solution, an ultrafast IR electron transfer channel (univalent reduction of Cd2+ by IR prehydrated electrons) competes with the p → s transition of trapped electrons (electron solvation process). This presolvation reaction occurs with a characteristic time of 140 ± 20 fs. Within the electron solvation regime, this elementary redox process is totally achieved in less than 1 × 10-12 s and exhibits a probability 10 times higher than the electron hydration channel. The consequence of an early partition between reactive and nonreactive IR electron dynamics on the subpicosecond formation of fully hydrated electron is discussed. The femtosecond IR spectroscopy of excited p-state electron transfer processes in aqueous electrolyte solutions opens a new area of prethermal reactions in environments relevant to mainstream chemistry and biochemistry.

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Reaction rates of electrons in liquid methanol and ethanol: effects of pressure

Cited by 20 publications

References 14 publications

Electron behavior in mixed solvents: optical spectra and reactivities in water/alkane diols

Electron behavior in mixed solvents: optical spectra and reactivities in water/alkane diols

Solvent effects on the reactivity of solvated electrons with ions in isobutanol/water mixed solvents

Ultrafast Reactivity of IR-Excited Electron in Aqueous Ionic Solutions

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