Charge Transfer on the Nanoscale:  Current Status

David M. Adams; Louis E. Brus; Christopher E. D. Chidsey; Stephen E. Creager; Carol Creutz; Cherie R. Kagan; Prashant V. Kamat; Marya Lieberman; Stuart Lindsay; R. A. Marcus; Robert M. Metzger; M.E. Michel‐Beyerle; John R. Miller; Marshall D. Newton; Debra R. Rolison; Otto F. Sankey; Kirk S. Schanze; James T. Yardley; Xiaoyang Zhu

doi:10.1021/jp0268462

Charge Transfer on the Nanoscale: Current Status

David M. Adams(Brookhaven National Laboratory), Louis E. Brus(Brookhaven National Laboratory), Christopher E. D. Chidsey(Brookhaven National Laboratory), Stephen E. Creager(Brookhaven National Laboratory), Carol Creutz(Brookhaven National Laboratory), Cherie R. Kagan(Brookhaven National Laboratory), Prashant V. Kamat(Brookhaven National Laboratory), Marya Lieberman(Brookhaven National Laboratory), Stuart Lindsay(Brookhaven National Laboratory), R. A. Marcus(Brookhaven National Laboratory), Robert M. Metzger(Brookhaven National Laboratory), M.E. Michel‐Beyerle(Brookhaven National Laboratory), John R. Miller(Brookhaven National Laboratory), Marshall D. Newton(Brookhaven National Laboratory), Debra R. Rolison(Brookhaven National Laboratory), Otto F. Sankey(Brookhaven National Laboratory), Kirk S. Schanze(Brookhaven National Laboratory), James T. Yardley(Brookhaven National Laboratory), Xiaoyang Zhu(Brookhaven National Laboratory)

The Journal of Physical Chemistry B

June 24, 2003

10.1021/jp0268462

Cited by 1,010

Abstract

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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