Femtosecond Dynamics in Liquids: Solvated Electrons and Small-Molecule Systems PDF Download
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Author: Erik Peter Farr
Publisher:
ISBN:
Category :
Languages : en
Pages : 240
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Book Description
This thesis is broadly concerned with understanding the structural and energetic details of condensed phase chemistry, primarily on ultrafast timescales. The first chapter focuses on novel contributions regarding the nature of the hydrated electron. It has been thought that this quasi-free solvent-supported electron resided in a cavity by its repulsive Coulombic interactions with nearby water molecules. Instead, a relatively modern but controversial simulation of the hydrated electron has shown that many observables are in fact better described by a non-cavity structure in which the hydrated electron's wave function resides in the interstitial spaces between water that is at, or slightly above, bulk density near and within the electron. The novel contributions have been understanding the effects of temperature on the structure and dynamics of the hydrated electron. This newly observed experimental temperature dependence of dynamics is highly consistent with the new non-cavity model of the hydrated electron. Secondarily, we show that previous methods of determining the hydrated electron's first excited-state lifetime from transient absorption were fraught with parameter correlation, making clean identification of the lifetime impossible. To resolve this we employ a more sophisticated model in combination with better signal to noise from broadband transient absorption measurements to show with certainty that the first excited-state lifetime of the hydrated electron at room temperature is on the order of 100 fs---in agreement with recent time-resolved photoelectron experiments. The second chapter brings these concepts of time-resolved spectroscopy to an advanced undergraduate level through a novel laboratory experiment. In order to provide access to undergraduates, I built a low-cost combined transient absorption and time-resolved fluorescence spectrometer. Simultaneously, I developed an experiment limited by the temporal and spectral resolution of the instrument in which undergraduates measure the fluorescent and phosphorescent lifetimes of the dye Eosin B. With these lifetimes in hand, the undergraduates then arrive at a complete photophysical picture for the molecule and quantitatively interpret their results with introductory quantum mechanics for electronic spectroscopy. Finally, the third chapter highlights time-resolved and steady-state spectroscopic investigations of singly linked di-perylenediimide, a key acceptor material used in competitive organic photovoltaics. We show that this molecule exists in a range geometrical configurations at room temperature, and that these conformations are spectrally distinct. Furthermore, the typical approximations used to describe this dimer as a Kasha H-/J-aggregate do not appear reasonable evidenced by detailed deconvolution of underlying spectral components with a high density of states---further confirmed with time-dependent density functional theory. The overarching theme of these chapters is to understand molecular photophysics in condensed phases on ultrafast timescales by using or refining modern principles of physical chemistry.
Author: Erik Peter Farr
Publisher:
ISBN:
Category :
Languages : en
Pages : 240
Get Book Here
Book Description
This thesis is broadly concerned with understanding the structural and energetic details of condensed phase chemistry, primarily on ultrafast timescales. The first chapter focuses on novel contributions regarding the nature of the hydrated electron. It has been thought that this quasi-free solvent-supported electron resided in a cavity by its repulsive Coulombic interactions with nearby water molecules. Instead, a relatively modern but controversial simulation of the hydrated electron has shown that many observables are in fact better described by a non-cavity structure in which the hydrated electron's wave function resides in the interstitial spaces between water that is at, or slightly above, bulk density near and within the electron. The novel contributions have been understanding the effects of temperature on the structure and dynamics of the hydrated electron. This newly observed experimental temperature dependence of dynamics is highly consistent with the new non-cavity model of the hydrated electron. Secondarily, we show that previous methods of determining the hydrated electron's first excited-state lifetime from transient absorption were fraught with parameter correlation, making clean identification of the lifetime impossible. To resolve this we employ a more sophisticated model in combination with better signal to noise from broadband transient absorption measurements to show with certainty that the first excited-state lifetime of the hydrated electron at room temperature is on the order of 100 fs---in agreement with recent time-resolved photoelectron experiments. The second chapter brings these concepts of time-resolved spectroscopy to an advanced undergraduate level through a novel laboratory experiment. In order to provide access to undergraduates, I built a low-cost combined transient absorption and time-resolved fluorescence spectrometer. Simultaneously, I developed an experiment limited by the temporal and spectral resolution of the instrument in which undergraduates measure the fluorescent and phosphorescent lifetimes of the dye Eosin B. With these lifetimes in hand, the undergraduates then arrive at a complete photophysical picture for the molecule and quantitatively interpret their results with introductory quantum mechanics for electronic spectroscopy. Finally, the third chapter highlights time-resolved and steady-state spectroscopic investigations of singly linked di-perylenediimide, a key acceptor material used in competitive organic photovoltaics. We show that this molecule exists in a range geometrical configurations at room temperature, and that these conformations are spectrally distinct. Furthermore, the typical approximations used to describe this dimer as a Kasha H-/J-aggregate do not appear reasonable evidenced by detailed deconvolution of underlying spectral components with a high density of states---further confirmed with time-dependent density functional theory. The overarching theme of these chapters is to understand molecular photophysics in condensed phases on ultrafast timescales by using or refining modern principles of physical chemistry.
Author: Majed Chergui
Publisher: World Scientific
ISBN: 981454826X
Category :
Languages : en
Pages : 718
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Book Description
This book highlights the latest experimental and theoretical developments in the field of femtochemistry, with papers describing the physics and chemistry of ultrafast processes in small molecules, complex molecular systems, clusters, biological systems, solids, matrices, liquids and at surfaces and interfaces. The recent developments in frequency-domain studies of femtodynamics are also presented. In addition, the latest achievements in femtosecond control of chemical reactions are presented, together with the newest techniques in real-time probing of reactions such as ultrafast x-ray or electron diffraction. The papers are rich in references giving a clearcut state-of-the-art of the topics being discussed. The book should be a valuable tool to all persons in the field and to young scientists.Contributors include: A H Zewail, J Jortner, V S Letokhov, J Manz, R S Berry, C Wittig, K B Eisenthal, A W Castleman Jr., J T Hynes, W H Gadzuk, R Kosloff, S Mukamel, K R Wilson; G Fleming, D Wiersma, K Yoshihara, V Sundström, A Apkarian, N Scherer, A Myers, R Schinke, J R Huber, R B Gerber, G Gerber and P M Champion.
Author: Abderrazzak Douhal
Publisher: World Scientific
ISBN: 9789812777980
Category : Science
Languages : en
Pages : 860
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Book Description
This book contains important contributions from top international scientists on the-state-of-the-art of femtochemistry and femtobiology at the beginning of the new millennium. It consists of reviews and papers on ultrafast dynamics in molecular science.The coverage of topics highlights several important features of molecular science from the viewpoint of structure (space domain) and dynamics (time domain). First of all, the book presents the latest developments, such as experimental techniques for understanding ultrafast processes in gas, condensed and complex systems, including biological molecules, surfaces and nanostructures. At the same time it stresses the different ways to control the rates and pathways of reactive events in chemistry and biology. Particular emphasis is given to biological processes as an area where femtodynamics is becoming very useful for resolving the structural dynamics from techniques such as electron diffraction, and X-ray and IR spectroscopy. Finally, the latest developments in quantum control (in both theory and experiment) and the experimental pulse-shaping techniques are described.
Author: J.D. Simon
Publisher: Springer Science & Business Media
ISBN: 9401109168
Category : Science
Languages : en
Pages : 388
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Book Description
The last decade has witnessed significant advances in the ability to generate short light pulses throughout the optical spectrum. These developments have had a tremendous impact on the field of chemical dynamics. Fundamental questions concerning chemical reactions, once thought to be unaddressable, are now easily studied in real-time experiments. Ultrafast spectroscopies are currently being used to study a variety of fundamental chemical phenomena. This book focuses on some of the experimental and associated theoretical studies of reactions in clusters, liquid and solid media. Many of the advances in our understanding of the fundamental details of chemical reactivity result from the interplay of experiment and theory. This theme is present in many of the chapters, indicating the pervasiveness of a combined approach for eludicating molecular models of chemical reactions. With parallel developments in computer simulation, complex chemical sys tems are being studied at a molecular level. The discussions presented in this book recount many areas at the forefront of "ultrafast chemistry". They serve the purpose of both bringing the expert up to date with the work being done in many laboratories as well as introducing those not directly involved in this field to the diverse set of problems that can be studied. I hope that this book conveys the excitement that both I and the other authors in this volume feel about the field of ultrafast chemistry. John D. Simon 1993 1.D. Simon (ed.), Ultrafast Dynamics of Chemical Systems, vii.
Author: Monique M. Martin
Publisher: Elsevier
ISBN: 0080506267
Category : Science
Languages : en
Pages : 589
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Book Description
This book reflects the heights of knowledge of ultrafast chemical processes attained in these early years of the 21st century : the latest research in femtosecond and picosecond molecular processes in Chemistry and Biology, carried out around the world, is described here in more than 110 articles. The results were presented and discussed at the VIth International Conference on Femtochemistry, in Paris, France, from July 6 to July 10, 2003. The articles published here were reviewed by referees selected from specialists in the Femtochemistry community, guaranteeing a collective responsability for the quality of the research reported in the next 564 pages. Femtochemistry is an ever-growing field, where new research areas are constantly opening up, and one which both stimulates and accompanies the development of ultrafast technologies. The increasing interest in femtobiology and chemistry at the frontier with biology is an obvious indicator of the present impact of life sciences in our society. New materials and reactions at surfaces are also some of the relatively new topics that promise rapid developments. New methodologies and technologies for probing and following in real time molecular dynamical phenomena have appeared within the last ten years or so. These methods, based on multidimensional IR spectroscopies, ultrafast X-ray and electron diffraction techniques, are well represented in this book. Of ever-improving performance, they are now applied to the characterization of structural dynamics of an increasing number of chemical and biological systems.This book reports the state of research in Femtochemistry and Femtobiology presented at Paris, at the Maison de la Chimie, in July 2003, representing the tenth anniversary of the conference.* Overview of the most recent research on ultrafast events* Application of new methodologies on chemical and biological systems* Contributions by key players in the field
Author: Biman Bagchi
Publisher: OUP USA
ISBN: 0199863326
Category : Science
Languages : en
Pages : 331
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Book Description
The book captures recent and exciting developments in molecular relaxation in liquids.
Author: Edwin James Hart
Publisher: John Wiley & Sons
ISBN:
Category : Science
Languages : en
Pages : 298
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Book Description
Author: Chang Q Sun
Publisher: Springer
ISBN: 981138441X
Category : Science
Languages : en
Pages : 316
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Book Description
This book highlights the latest advances and outlines future trends in aqueous solvation studies from the perspective of hydrogen bond transition by charge injection, which reconciles the solvation dynamics, molecular nonbond interactions, and the extraordinary functionalities of various solutes on the solution bond network and properties. Focus is given on ionic and dipolar electrostatic polarization, O:H nonbond interaction, anti-HB and super-HB repulsion, and solute-solute interactions. Its target audience includes researchers, scientists, and engineers in chemistry, physics, surface and interface science, materials science and engineering.
Author: Biman Bagchi
Publisher: Cambridge University Press
ISBN: 1107037298
Category : Medical
Languages : en
Pages : 383
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Book Description
A unified overview of the dynamical properties of water and its unique and diverse role in biological and chemical processes.
Author: Abderrazzak Douhal
Publisher: World Scientific
ISBN: 9814489336
Category : Science
Languages : en
Pages : 854
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Book Description
This book contains important contributions from top international scientists on the-state-of-the-art of femtochemistry and femtobiology at the beginning of the new millennium. It consists of reviews and papers on ultrafast dynamics in molecular science.The coverage of topics highlights several important features of molecular science from the viewpoint of structure (space domain) and dynamics (time domain). First of all, the book presents the latest developments, such as experimental techniques for understanding ultrafast processes in gas, condensed and complex systems, including biological molecules, surfaces and nanostructures. At the same time it stresses the different ways to control the rates and pathways of reactive events in chemistry and biology. Particular emphasis is given to biological processes as an area where femtodynamics is becoming very useful for resolving the structural dynamics from techniques such as electron diffraction, and X-ray and IR spectroscopy. Finally, the latest developments in quantum control (in both theory and experiment) and the experimental pulse-shaping techniques are described.
