Electric double-layer capacitors (DLCs) can have high storage capacity, but their porous electrodes cause them to perform like resistors in filter circuits that remove ripple from rectified direct current. We have demonstrated efficient filtering of 120-hertz current with DLCs with electrodes made from vertically oriented graphene nanosheets grown directly on metal current collectors. This design minimized electronic and ionic resistances and produced capacitors with RC time constants of less than 200 microseconds, in contrast with ~1 second for typical DLCs. Graphene nanosheets have a preponderance of exposed edge planes that greatly increases charge storage as compared with that of designs that rely on basal plane surfaces. Capacitors constructed with these electrodes could be smaller than the low-voltage aluminum electrolyte capacitors that are typically used in electronic devices.
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.
Intramolecular long-distance electron transfer (EI) has been actively studied in recent years in order to test existing theories in a quantitative way and to provide the necessary constants for predicting ET rates from simple structural parameters. Theoretical predictions of an "inverted region," where increasing the driving force of the reaction will decrease its rate, have begun to be experimentally confirmed. A predicted nonlinear dependence of ET rates on the polarity of the solvent has also been confirmed. This work has implications for the design of efficient photochemical charge-separation devices. Other studies have been directed toward determining the distance dependence of ET reactions. Model studies on different series of compounds give similar distance dependences. When different stereochemical structures are compared, it becomes apparent that geometrical factors must be taken into account. Finally, the mechanism of coupling between donor and acceptor in weakly interacting systems has become of major importance. The theoretical and experimental evidence favors a model in which coupling is provided by the interaction with the orbitals of the intervening molecular fragments, although more experimental evidence is needed.
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