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Author: Sarah Bailey King Publisher: ISBN: Category : Languages : en Pages : 159
Book Description
Time-resolved photoelectron imaging is used to investigate the dynamics of electron attachment and electron interaction with the molecules uracil (U), thymine (T), adenine (A) and imidazole (Im). In this technique, the molecule of interest is clustered with an iodide atom, and a tunable UV photon induces ultrafast electron transfer from iodide to the molecule, forming a transient negative ion with femtosecond time resolution. After a known time delay, a second photon detaches the transient negative ion and the resulting photoelectrons are detected using velocity map imaging. This experimental method allows for insight into how biologically relevant molecules in the gas phase interact with, and accommodate, an excess electron, an important question in radiation biology. Uracil and thymine interact similarly with excess electrons. We observe two different electron attachment motifs, dependent on the pump pulse excitation energy that induces charge transfer from the iodide atom. The vertical detachment energy (VDE) of the iodide-uracil cluster is 4.11 " 0.05 eV and 4.05 " 0.05 eV for the iodide-thymine cluster. Excitation of the clusters with photon energies of approximately 500-700 meV above the I-U and I-T VDEs results in electrons with approximately 500-700 meV of kinetic energy that scatter directly into the valence-bound orbitals of uracil and thymine, forming the valence bound anion. Using lower excitation energies, between 120 meV below the VDE and 110 meV above the I-U and I-T VDEs, the I-T anion ground state is photoexcited to an anion state where the excess electron is bound in a dipole-bound (DB) anion state by the dipole moment of the cluster. Due to a changing photodetachment cross-section of the uracil and thymine DB anion from geometry relaxation at early times, the DB photoelectron signal has a rise-time longer than the cross-correlation of the pump and probe pulses. Subsequently, a small population of the uracil and thymine DB anions transition to the valence-bound (VB) anions, in agreement with theoretical predictions. However, no participation of the uracil or thymine DB anion is observed in the formation of the respective VB anion at excitation energies 500-700 meV above the I-U/T VDEs, contrary to experiments that invoked participation of the dipole-bound anions to explain features in the dissociative electron attachment spectra. The uracil and thymine DB and VB anions ultimately decay through a variety of mechanisms. In the lower excitation energy region, both the DB and VB anions of uracil and thymine decay bi-exponentially at all of the excitation energies studied. The decay lifetimes range between 2 to 25 ps for the short decay lifetime and 30-2000 ps for the long decay lifetime, depending on excitation energy and anion state. In the higher excitation energy region, the thymine VB anion signal decays completely by 10 ps, unlike uracil that has a bi-exponential long-time lifetime that persists until at least 100 ps. The bi-exponential decays for the DB and VB anions of uracil and thymine are attributed to various mechanisms depending on the molecule and excitation energy including: different rates of autodetachment prior and subsequent to iodine loss, and non-statistical autodetachment versus statistical autodetachment. Experiments investigating the electron attachment dynamics to adenine show evidence of multiple tautomers of adenine participating in the dynamics. Excitation from the ground state I-A anion cluster to the iodine-adenine DB anion, is induced with excitation energies near the 3.96 " 0.05 eV VDE of the I-A9 canonical tautomer. The DB anion of adenine is initially formed with a ~250 fs rise-time due to a changing photodetachment cross-section correlated with relaxation of the cluster geometry from the Franck-Condon region, as is observed in uracil and thymine. The DB anion undergoes a complete ultrafast transition to the VB anion at some excitation energies, and a partial transition at other excitation energies. However, electronic structure calculations do not predict a stable valence bound anion of the A9 canonical tautomer of adenine, and the relative intensities of the dipole-bound and valence-bound anions and the dipole-bound anion decay lifetimes display non-monotonic trends. These dynamics are consistent with two tautomers present in the ion beam clustered to iodide, the A9 canonical tautomer and the A3 non-canonical tautomer. The DB to VB transition is due to the A3 tautomer. The A3 tautomer is calculated to support a VB anion with an exothermic transition from the DB to VB state. The A9 canonical tautomer however only supports an excess electron in a DB orbital and the DB anion is formed in a narrower excitation energy range than the A3 tautomer, causing the non-monotonic trends in the dipole-bound and valence-bound anion intensity ratios and dipole-bound anion decay lifetimes. Imidazole, like the A9 tautomer of adenine, only supports an excess electron in a DB orbital. The VDE of the iodide-imidazole binary cluster is 3.90 " 0.05 eV. With excitation energies just below 3.90 eV, the ground state I-Im cluster is excited to the I Im-(DB) anionic excited state with an ultrafast rise-time due to geometry changes in the [I Im]- cluster. The DB state decays multi-exponentially with decay dynamics that change rapidly with small changes in the excitation energy. These dynamics suggest that the degree of vibrational excitation in the dipole-bound cluster considerably effects the decay dynamics of the transient [I Im]- ion. Overall, the systems studied provide a wide picture of the various ways that biologically relevant molecules can interact with, and accommodate, excess charge in dipole- and valence-bound anion states, and the various ways that iodide(iodine) can influence the observed dynamics, through the rise time of the dipole-bound state and the decay of both dipole- and valence-bound anions. A detailed understanding of the electron kinetic energy dependent mechanisms of electron attachment in nucleobases, and any subsequent dipole-bound anion to valence-bound anion transition, is crucial for understanding the various mechanisms of low-energy electron damage to DNA.
Author: Sarah Bailey King Publisher: ISBN: Category : Languages : en Pages : 159
Book Description
Time-resolved photoelectron imaging is used to investigate the dynamics of electron attachment and electron interaction with the molecules uracil (U), thymine (T), adenine (A) and imidazole (Im). In this technique, the molecule of interest is clustered with an iodide atom, and a tunable UV photon induces ultrafast electron transfer from iodide to the molecule, forming a transient negative ion with femtosecond time resolution. After a known time delay, a second photon detaches the transient negative ion and the resulting photoelectrons are detected using velocity map imaging. This experimental method allows for insight into how biologically relevant molecules in the gas phase interact with, and accommodate, an excess electron, an important question in radiation biology. Uracil and thymine interact similarly with excess electrons. We observe two different electron attachment motifs, dependent on the pump pulse excitation energy that induces charge transfer from the iodide atom. The vertical detachment energy (VDE) of the iodide-uracil cluster is 4.11 " 0.05 eV and 4.05 " 0.05 eV for the iodide-thymine cluster. Excitation of the clusters with photon energies of approximately 500-700 meV above the I-U and I-T VDEs results in electrons with approximately 500-700 meV of kinetic energy that scatter directly into the valence-bound orbitals of uracil and thymine, forming the valence bound anion. Using lower excitation energies, between 120 meV below the VDE and 110 meV above the I-U and I-T VDEs, the I-T anion ground state is photoexcited to an anion state where the excess electron is bound in a dipole-bound (DB) anion state by the dipole moment of the cluster. Due to a changing photodetachment cross-section of the uracil and thymine DB anion from geometry relaxation at early times, the DB photoelectron signal has a rise-time longer than the cross-correlation of the pump and probe pulses. Subsequently, a small population of the uracil and thymine DB anions transition to the valence-bound (VB) anions, in agreement with theoretical predictions. However, no participation of the uracil or thymine DB anion is observed in the formation of the respective VB anion at excitation energies 500-700 meV above the I-U/T VDEs, contrary to experiments that invoked participation of the dipole-bound anions to explain features in the dissociative electron attachment spectra. The uracil and thymine DB and VB anions ultimately decay through a variety of mechanisms. In the lower excitation energy region, both the DB and VB anions of uracil and thymine decay bi-exponentially at all of the excitation energies studied. The decay lifetimes range between 2 to 25 ps for the short decay lifetime and 30-2000 ps for the long decay lifetime, depending on excitation energy and anion state. In the higher excitation energy region, the thymine VB anion signal decays completely by 10 ps, unlike uracil that has a bi-exponential long-time lifetime that persists until at least 100 ps. The bi-exponential decays for the DB and VB anions of uracil and thymine are attributed to various mechanisms depending on the molecule and excitation energy including: different rates of autodetachment prior and subsequent to iodine loss, and non-statistical autodetachment versus statistical autodetachment. Experiments investigating the electron attachment dynamics to adenine show evidence of multiple tautomers of adenine participating in the dynamics. Excitation from the ground state I-A anion cluster to the iodine-adenine DB anion, is induced with excitation energies near the 3.96 " 0.05 eV VDE of the I-A9 canonical tautomer. The DB anion of adenine is initially formed with a ~250 fs rise-time due to a changing photodetachment cross-section correlated with relaxation of the cluster geometry from the Franck-Condon region, as is observed in uracil and thymine. The DB anion undergoes a complete ultrafast transition to the VB anion at some excitation energies, and a partial transition at other excitation energies. However, electronic structure calculations do not predict a stable valence bound anion of the A9 canonical tautomer of adenine, and the relative intensities of the dipole-bound and valence-bound anions and the dipole-bound anion decay lifetimes display non-monotonic trends. These dynamics are consistent with two tautomers present in the ion beam clustered to iodide, the A9 canonical tautomer and the A3 non-canonical tautomer. The DB to VB transition is due to the A3 tautomer. The A3 tautomer is calculated to support a VB anion with an exothermic transition from the DB to VB state. The A9 canonical tautomer however only supports an excess electron in a DB orbital and the DB anion is formed in a narrower excitation energy range than the A3 tautomer, causing the non-monotonic trends in the dipole-bound and valence-bound anion intensity ratios and dipole-bound anion decay lifetimes. Imidazole, like the A9 tautomer of adenine, only supports an excess electron in a DB orbital. The VDE of the iodide-imidazole binary cluster is 3.90 " 0.05 eV. With excitation energies just below 3.90 eV, the ground state I-Im cluster is excited to the I Im-(DB) anionic excited state with an ultrafast rise-time due to geometry changes in the [I Im]- cluster. The DB state decays multi-exponentially with decay dynamics that change rapidly with small changes in the excitation energy. These dynamics suggest that the degree of vibrational excitation in the dipole-bound cluster considerably effects the decay dynamics of the transient [I Im]- ion. Overall, the systems studied provide a wide picture of the various ways that biologically relevant molecules can interact with, and accommodate, excess charge in dipole- and valence-bound anion states, and the various ways that iodide(iodine) can influence the observed dynamics, through the rise time of the dipole-bound state and the decay of both dipole- and valence-bound anions. A detailed understanding of the electron kinetic energy dependent mechanisms of electron attachment in nucleobases, and any subsequent dipole-bound anion to valence-bound anion transition, is crucial for understanding the various mechanisms of low-energy electron damage to DNA.
Author: James F Wishart Publisher: World Scientific ISBN: 9814467057 Category : Science Languages : en Pages : 634
Book Description
Recent Trends in Radiation Chemistry is a state-of-the-art review of the present status and future trends in the field of radiation chemistry research. It covers a broad spectrum of topics, ranging from the historical perspective, instrumentation of accelerators in the nanosecond to femtosecond region, through the use of radiation chemical methods in the study of antioxidants and nanomaterials, radiation-induced DNA damage by ionizing radiation involving both direct and indirect effects, to ultrafast events in free electron transfer, radiation-induced processes at solid-liquid interfaces and the recent work on infrared spectroscopy and radiation chemistry.The contributors to the book are world-renowned specialists. The book is unique in that it covers a wide spectrum of topics that will be of great interest to beginners as well as experts. Recent data on ultrafast phenomena from the recently established world-class laser-driven accelerators facilities in the US, France and Japan are reviewed.There has not been a significant book covering the important field of radiation chemistry for the last 5 years. This timely book, which includes highlights of recent work, will appeal not only to the specialists working in the area but also to other researchers involved in related specialties. remove /a remove
Author: D. Michael P. Mingos Publisher: Springer Nature ISBN: 3030647439 Category : Science Languages : en Pages : 285
Book Description
This volume summarises recent developments and possible future directions for small molecule X-ray crystallography. It reviews specific areas of crystallography which are rapidly developing and places them in a historical context. The interdisciplinary nature of the technique is emphasised throughout. It introduces and describes the chemical crystallographic and synchrotron facilities which have been at the cutting edge of the subject in recent decades. The introduction of new computer-based algorithms has proved to be very influential and stimulated and accelerated the growth of new areas of science. The challenges which will arise from the acquisition of ever larger databases are considered and the potential impact of artificial intelligence techniques stressed. Recent advances in the refinement and analysis of X-ray crystal structures are highlighted. In addition the recent developments in time resolved single crystal X-ray crystallography are discussed. Recent years have demonstrated how this technique has provided important mechanistic information on solid-state reactions and complements information from traditional spectroscopic measurements. The volume highlights how the prospect of being able to routinely “watch” chemical processes as they occur provides an exciting possibility for the future. Recent advances in X-ray sources and detectors that have also contributed to the possibility of dynamic single-crystal X-ray diffraction methods are presented. The coupling of crystallography and quantum chemical calculations provides detailed information about electron distributions in crystals and has resulted in a more detailed understanding of chemical bonding. The volume will be of interest to chemists and crystallographers with an interest in the synthesis, characterisation and physical and catalytic properties of solid-state materials. Postgraduate students entering the field will benefit from a historical introduction to the subject and a description of those techniques which are currently used. Since X-ray crystallography is used so widely in modern chemistry it will serve to alert senior chemists to those developments which will become routine in coming decades. It will also be of interest to the broad community of computational chemists who study chemical systems.
Author: George Atkinson Publisher: Elsevier ISBN: 0323162215 Category : Science Languages : en Pages : 419
Book Description
Time-Resolved Vibrational Spectroscopy covers the proceedings of the International Conference on Time-Resolved Vibrational Spectroscopy, convened in Lake Placid, New York on August 16-20, 1982. This book is organized into six sections encompassing 51 chapters. The first section deals with the theoretical and computational developments concerning Raman scattering and two-photon and optical spectroscopies. Section II focuses on the instrumentation and techniques of various time-resolved vibrational spectroscopies (TRVS), such as Raman techniques, stroboscopic interferometry, and infrared multiphoton. Sections III and IV deal with the chemical (ground and excited states) and biochemical systems of TRVS. The concluding sections discuss the theoretical principles and methods of observation of nonlinear Raman spectroscopy and surface-enhanced and colloidal Raman scattering. This book is of value to chemists, spectroscopists, and photobiologists.
Author: Yoneho Tabata Publisher: CRC Press ISBN: 9780849348815 Category : Science Languages : en Pages : 520
Book Description
Pulse Radiolysis presents an in-depth discussion of the pulse radiolysis technique, one of the most important and powerful means for detecting transient and relaxation phenomena and following their behavior in irradiated systems. The book covers the principle of pulse radiolysis, identifies various kinds of pulse radiolysis techniques, and discusses recent advancements in the field. The text also discusses new experimental pulse radiolysis techniques (basic and applied) in broad scientific fields such as physics, chemistry, biology, and engineering. These techniques include picosecond pulse radiolysis, single particle radiolysis, and muon-induced transient phenomena. Pulse Radiolysis provides essential information for all professionals involved with pulse radiolysis research.
Author: C.D. Jonah Publisher: Elsevier ISBN: 008054021X Category : Science Languages : en Pages : 777
Book Description
During the twentieth century, radiation chemistry emerged as a multi-faceted field encompassing all areas of science. Radiation chemical techniques are becoming increasingly popular and are being routinely used not only by chemists but also by biologists, polymer scientists, etc. "Radiation Chemistry: Present Status and Future Trends" presents an overall view of the different aspects of the subject. The chapters review the current status of the field and present the future opportunities in utilizing radiation chemical techniques. This will be of interest to chemists in general and in particular to radiation chemists, chemical kineticists, photochemists, physical-organic chemists and spectroscopists. In view of the diverse nature of the field, the book is a multi-authored effort by several experts in their particular areas of research. Six main areas, both basic and applied, were identified and the book is organized around them. The topics were selected in terms of their relative importance and the contribution of radiation chemistry to the general areas of chemistry, biology and physics. The topics covered are as diverse as gas phase radiation chemistry, the use of radiation chemical techniques, the treatment of water pollutants, the chemical basis of radiation biology, and muonium chemistry. The book also contains an update of the next generation electron accelerators.
Book Description
This book gives a progress report on the many and original contributions of radiation chemistry to the fundamental knowledge of the vast domain of chemical reactions and its applications. Radiation chemistry techniques indeed make it possible to elucidate detailed physicochemical mechanisms in inorganic and organic chemistry (including in space) and in biochemistry. Moreover, this comprehension is applied in materials science to precisely control syntheses by radiation, such as radiopolymerisation, radiografting, specific treatment of surfaces (textiles, paintings, inks, etc.), synthesis of complex nanomaterials, degradation of environmental pollutants and radioresistance of materials for nuclear reactors. In life sciences, the study of the effects of radiation on biomacromolecules (DNA, proteins, lipids) not only permits the comprehension of normal or pathological biological mechanisms, but also the improvement of our health. In particular, many advances in cancer radiotherapy, in the radioprotection of nuclear workers and the general population, as well as in the treatment of diseases and the radiosterilization of drugs, could be obtained thanks to this research. Abundantly illustrated and written in English by top international specialists who have taken care to render the subjects accessible, this work will greatly interest those curious about a scientific field that is new to them and students attracted by the original and multidisciplinary aspects of the field. At a time when radiation chemistry research is experiencing spectacular development in numerous countries, this book will attract many newcomers to the field.
Author: Sarah Bailey King
Author: Sarah Bailey King
Author: James F Wishart
Author: D. Michael P. Mingos
Author: George Atkinson
Author: Yoneho Tabata
Author: Eckhard Mandelkov
Author: Gordon Hughes
Author: C.D. Jonah
Author: Pierre J. Ausloos
Author: Jacqueline Belloni