Carol Creutz scite author profile

This is the report of a DOE-sponsored workshop organized to discuss the status of our understanding of charge-transfer processes on the nanoscale and to identify research and other needs for progress in nanoscience and nanotechnology. The current status of basic electron-transfer research, both theoretical and experimental, is addressed, with emphasis on the distance-dependent measurements, and we have attempted to integrate terminology and notation of solution electron-transfer kinetics with that of conductance analysis. The interface between molecules or nanoparticles and bulk metals is examined, and new research tools that advance description and understanding of the interface are presented. The present state-of-the-art in molecular electronics efforts is summarized along with future research needs. Finally, novel strategies that exploit nanoscale architectures are presented for enhancing the efficiences of energy conversion based on photochemistry, catalysis, and electrocatalysis principles.

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Catalysis Research of Relevance to Carbon Management: Progress, Challenges, and Opportunities

Arakawa

et al. 2001

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Direct approach to measuring the Franck-Condon barrier to electron transfer between metal ions

Creutz¹,

Taube²

1969

J. Am. Chem. Soc.

801

476

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Optical transitions of symmetrical mixed-valence systems in the Class II–III transition regimeElectronic supplementary information (ESI) is available: derivation of eqn. (39c), table summarizing the relationships between band maxima and band widths predicted by the two-state model and table of spectral properties of mixed-valence ruthenium(II)/(III) bridged by pyrazine and dicyanamide. See http://www.rsc.org/suppdata/cs/b0/b008034i/

2002

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In the Robin and Day classification, mixed-valence systems are characterized as Class I, II or III depending on the strength of the electronic interaction between the oxidized and reduced sites, ranging from essentially zero (Class I), to moderate (Class II), to very strong electronic coupling (Class III). The properties of Class I systems are essentially those of the separate sites. Class II systems possess new optical and electronic properties in addition to those of the separate sites. However, the interaction between the sites is sufficiently weak that Class II systems are valence trapped or charge localized and can the be described by a double-well potential. In Class III systems the interaction of the donor and acceptor sites is so great that two separate minima are no longer discernible and the energy surface features a single minimum. The electron is delocalized and the system has its own unique properties. The Robin and Day classification has enjoyed considerable success and most of the redox systems studied to date are readily assigned to Class II. However the situation becomes much more complicated when the system shows borderline Class II/III behavior. Such "almost delocalized" mixed-valence systems are difficult to characterize. In this article spectral band shapes and intensities are calculated utilizing increasingly complex models including two to four states. Free-energy surfaces are constructed for harmonic diabetic surfaces and characterized as a function of increasing electronic coupling to simulate the Class II to III transition. The properties of the charge-transfer absorption bands predicted for borderline mixed-valence systems are compared with experimental data. The treatment is restricted to symmetrical (delta G0 = 0) systems.

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Metal—lingad and metal—metal coupling elements

Creutz¹,

Newton²,

Sutin³

1994

Journal of Photochemistry and Photobiology A: Chemistry

425

438

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Carol Creutz

Charge Transfer on the Nanoscale: Current Status

Catalysis Research of Relevance to Carbon Management: Progress, Challenges, and Opportunities

Direct approach to measuring the Franck-Condon barrier to electron transfer between metal ions

Metal—lingad and metal—metal coupling elements

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