Electron Transfer--From Isolated Molecules to Biomolecules, Part Two (V107 Advances in Chemical Physics)
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More About This Title Electron Transfer--From Isolated Molecules to Biomolecules, Part Two (V107 Advances in Chemical Physics)
English
an integrated approach to electron transfer phenomena
This two-part stand-alone volume in the prestigious Advances in Chemical Physics series provides the most comprehensive overview of electron transfer science today. It draws on cutting-edge research from diverse areas of chemistry, physics, and biology-covering the most recent developments in the field, and pointing to important future trends. This second volume offers the following sections:
* Solvent control, including ultrafast solvation dynamics and related topics
* Ultrafast electron transfer and coherence effects
* Molecular electronics
* Electron transfer and exciplex chemistry
* Biomolecules-from electron transfer tubes to kinetics in a DNA environment
Part One addresses the historical perspective, electron transfer phenomena in isolated molecules and clusters, general theory, and electron transfer kinetics in bridged compounds.
Electron transfer science has seen tremendous progress in recent years. Technological innovations, most notably the advent of femtosecond lasers, now permit the real-time investigation of intramolecular and intermolecular electron transfer processes on a time scale of nuclear motion. New scientific information abounds, illuminating the processes of energy acquisition, storage, and disposal in large molecules, clusters, condensed phase, and biophysical systems.
Electron Transfer: From Isolated Molecules to Biomolecules is the first book devoted to the exciting work being done in nonradiative electron transfer dynamics today. This two-part edited volume emphasizes the interdisciplinary nature of the field, bringing together the contributions of pioneers in chemistry, physics, and biology. Both theoretical and experimental topics are featured. The authors describe modern approaches to the exploration of different systems, including supersonic beam techniques, femtosecond laser spectroscopy, chemical syntheses, and methods in genetic and chemical engineering. They examine applications in such areas as supersonic jets, solvents, electrodes, semi- conductors, respiratory and enzymatic protein systems, photosynthesis, and more. They also relate electron transfer and radiationless transitions theory to pertinent physical phenomena, and provide a conceptual framework for the different processes.
Complete with over two hundred illustrations, Part Two opens with solvent control issues, including electron transfer reactions and ultrafast solvation dynamics. Other topics include ultrafast electron transfer and coherence effects, molecular electronics, and electron transfer in exciplex chemistry. This volume concludes with a section on biomolecules-from electron transfer tubes to experimental electron transfer and transport in DNA.
Timely, comprehensive, and authoritative, Electron Transfer: From Isolated Molecules to Biomolecules is an essential resource for physical chemists, molecular physicists, and researchers working in nonradiative dynamics today.
This two-part stand-alone volume in the prestigious Advances in Chemical Physics series provides the most comprehensive overview of electron transfer science today. It draws on cutting-edge research from diverse areas of chemistry, physics, and biology-covering the most recent developments in the field, and pointing to important future trends. This second volume offers the following sections:
* Solvent control, including ultrafast solvation dynamics and related topics
* Ultrafast electron transfer and coherence effects
* Molecular electronics
* Electron transfer and exciplex chemistry
* Biomolecules-from electron transfer tubes to kinetics in a DNA environment
Part One addresses the historical perspective, electron transfer phenomena in isolated molecules and clusters, general theory, and electron transfer kinetics in bridged compounds.
Electron transfer science has seen tremendous progress in recent years. Technological innovations, most notably the advent of femtosecond lasers, now permit the real-time investigation of intramolecular and intermolecular electron transfer processes on a time scale of nuclear motion. New scientific information abounds, illuminating the processes of energy acquisition, storage, and disposal in large molecules, clusters, condensed phase, and biophysical systems.
Electron Transfer: From Isolated Molecules to Biomolecules is the first book devoted to the exciting work being done in nonradiative electron transfer dynamics today. This two-part edited volume emphasizes the interdisciplinary nature of the field, bringing together the contributions of pioneers in chemistry, physics, and biology. Both theoretical and experimental topics are featured. The authors describe modern approaches to the exploration of different systems, including supersonic beam techniques, femtosecond laser spectroscopy, chemical syntheses, and methods in genetic and chemical engineering. They examine applications in such areas as supersonic jets, solvents, electrodes, semi- conductors, respiratory and enzymatic protein systems, photosynthesis, and more. They also relate electron transfer and radiationless transitions theory to pertinent physical phenomena, and provide a conceptual framework for the different processes.
Complete with over two hundred illustrations, Part Two opens with solvent control issues, including electron transfer reactions and ultrafast solvation dynamics. Other topics include ultrafast electron transfer and coherence effects, molecular electronics, and electron transfer in exciplex chemistry. This volume concludes with a section on biomolecules-from electron transfer tubes to experimental electron transfer and transport in DNA.
Timely, comprehensive, and authoritative, Electron Transfer: From Isolated Molecules to Biomolecules is an essential resource for physical chemists, molecular physicists, and researchers working in nonradiative dynamics today.
English
JOSHUA JORTNER is Heinemann Professor of Chemistry at Tel Aviv University's School of Chemistry, where he has been on the faculty since 1964. Professor Jortner is President of the International Union of Pure and Applied Chemistry, former President of the Israel National Academy of Sciences and Humanities, and the recipient of the Wolf Prize in Chemistry (1988).
M. BIXON is Chemistry Professor at Tel Aviv University's School of Chemistry, where he has been on the faculty since 1966. He holds a PhD from the Weizmann Institute of Science in Rehovot, Israel.
M. BIXON is Chemistry Professor at Tel Aviv University's School of Chemistry, where he has been on the faculty since 1966. He holds a PhD from the Weizmann Institute of Science in Rehovot, Israel.
English
Interplay Between Ultrafast Polar Solvation and Vibrational Dynamics in Electron Transfer Reactions: Role of High-Frequency Vibrational Modes (B. Bagchi & N. Gayathri).
Solvent Control of Electron Transfer Reactions (F. Raineri & H. Friedman).
Theoretical and Experimental Study of Ultrafast Solvation Dynamics by Transient Four-Photon Spectroscopy (B. Fainberg & D. Huppert).
Coherence and Adiabaticity in Ultrafast Electron Transfer (K. Wynne & R. Hochstrasser).
Electron Transfer and Solvent Dynamics in Two- and Three-State Systems (M. Cho & G. Fleming).
Ultrafast Intermolecular Electron Transfer in Solution (K. Yoshihara).
Electron Transfer in Molecules and Molecular Wires: Geometry Dependence, Coherent Transfer, and Control (V. Mujica, et al.).
Electron Transfer and Exciplex Chemistry (N. Mataga & H. Miyasaka).
Electron-Transfer Tubes (J. Regan & J. Onuchic).
Copper Proteins as Model Systems for Investigating Intramolecular Electron Transfer Processes (O. Farver & I. Pecht).
Applying Marcus's Theory to Electron Transfer in Vivo (G. McLendon, et al.).
Solvent-Fluctuation Control of Solution Reactions and Its Manifestation in Protein Functions (H. Sumi).
Experimental Electron Transfer Kinetics in a DNA Environment (P. Barbara & E. Olson).
Indexes.
Solvent Control of Electron Transfer Reactions (F. Raineri & H. Friedman).
Theoretical and Experimental Study of Ultrafast Solvation Dynamics by Transient Four-Photon Spectroscopy (B. Fainberg & D. Huppert).
Coherence and Adiabaticity in Ultrafast Electron Transfer (K. Wynne & R. Hochstrasser).
Electron Transfer and Solvent Dynamics in Two- and Three-State Systems (M. Cho & G. Fleming).
Ultrafast Intermolecular Electron Transfer in Solution (K. Yoshihara).
Electron Transfer in Molecules and Molecular Wires: Geometry Dependence, Coherent Transfer, and Control (V. Mujica, et al.).
Electron Transfer and Exciplex Chemistry (N. Mataga & H. Miyasaka).
Electron-Transfer Tubes (J. Regan & J. Onuchic).
Copper Proteins as Model Systems for Investigating Intramolecular Electron Transfer Processes (O. Farver & I. Pecht).
Applying Marcus's Theory to Electron Transfer in Vivo (G. McLendon, et al.).
Solvent-Fluctuation Control of Solution Reactions and Its Manifestation in Protein Functions (H. Sumi).
Experimental Electron Transfer Kinetics in a DNA Environment (P. Barbara & E. Olson).
Indexes.
