Solvent reorganization energies measured by an electron transfer reaction in supercritical ethane

Takahashi, Kenji; Sawamura, Sadashi; Jonah, Charles D.

doi:10.1016/s0896-8446(98)00047-3

Cited by 4 publications

(3 citation statements)

References 33 publications

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“…Pressure in the cell was adjusted using a HPLC (JASCO, model PU-980) pump and monitored with a Cole-Parmer digital pressure meter (model 7350-38). The experimental arrangements were similar to those described previously. , …”

Section: Methodsmentioning

confidence: 99%

“…The local solvent density of supercritical fluid may be significantly greater than the bulk density of fluid. Unusual microscopic solvation of solutes (sometimes referred to as the clustering of solvent molecules around the solute molecule) in these systems affects the kinetics of energy and charge-transfer reactions. − Fast techniques of flash photolysis , and pulse radiolysis , have been employed to examine both radical and electron-transfer reactions to determine the effects of solvation and solvent reorganization energies.…”

Section: Introductionmentioning

confidence: 99%

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Charged Species in the Radiolysis of Supercritical CO₂

et al. 1999

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The pulse radiolysis technique has been employed in studying charge-transfer reactions of anionic C2O4 -, and cationic C2O4 + species in supercritical carbon dioxide (scCO2) over a range of reduced densities ρr = 0.36−1.5 and at a reduced temperature of T r = 1.03. The absorption spectrum measured in the visible region with a maximum around 700 nm is assigned to the dimer cation C2O4 +. The pressure dependence of charge-transfer reactions was examined using dimethylaniline (DMA), benzoquinone (BQ), and oxygen as charge acceptors. The reaction rates of DMA with cations, and BQ with anions are at or near the diffusion-controlled limit. The rates decrease an order of magnitude with increase of pressure. The reaction of C2O4 + with oxygen is much slower with an almost constant rate over the pressure range examined. The measured rate constants of electron-transfer reactions are analyzed in terms of the diffusion constants of reactants in scCO2, and the dependence of measured and theoretical values on the bulk density is discussed.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Charged Species in the Radiolysis of Supercritical CO₂

et al. 1999

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“…Two possible explanations are discussed among which is a solvent reorganization energy of approximately 0.35 eV dependent on pressure, a ¢gure higher than expected due to density £uctuations. 177 Inorganic and small organic solutes…”

Section: Positronium and Muonium Chemistrymentioning

confidence: 99%

7 Radiation chemistry

Belloni

Delcourt

Houée-Levin⊥

et al. 2000

Annu. Rep. Prog. Chem., Sect. C

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We try in this review to survey advances in all the aspects of Radiation Chemistry (the effects of high energy or ionizing radiation), both basic and applied, made during the period 1995^1999, after the last report issued at the end of 1994. 1 Classically, two main classes of studies are relevant. The ¢rst one includes the primary phenomena induced by the interaction of high-energy radiation with a chemical system. The way the energy is spatially deposited is indeed highly nonhomogeneous and depends on the type of radiation considered. Mutual reactions between the primary species produced also depend on their initial spatial distribution, and therefore on the energy absorption pattern. The kinetic aspects derive directly from the initial events following radiation absorption and thus, when observed at times as short as possible, give useful information on the early energy distribution for each of the radiation types, X-and g-photons, electrons and heavy particles, and, on the in£uence of their intensity and energy per particle.The second class of studies utilizes the background knowledge of radiation chemistry to generate and then to observe the fate of chemical transient species known to be involved in very important chemical or biochemical processes. Numerous data, such as the nature of reaction products, the absolute rate constants, the sequence of elementary reactions constituting a mechanism, and the thermodynamic and spectroscopic properties of short-lived species have been attained. This kind of study of transients and reaction mechanisms, which can be approached only by pulse techniques (essentially pulse radiolysis or laser photolysis, each with its speci¢c advantages), constitutes the new ¢eld of fast to ultrafast chemistry. It concerns extended domains of physical, organic, inorganic, and bio-chemistry. Moreover, the understanding of mechanisms is quite helpful in suggesting new ways of synthesis or degradation induced by irradiation and is now extensively used in developing various speci¢c processes in applied chemistry. The number of studies on the chemical mechanisms and in applied radiation chemistry constitutes an increased fraction of the total publications in radiation chemistry, which we estimate to be around 4000 over the period considered (almost constant compared to the preceding 5-year

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