Advances In Quantum Chemistry: Theory Of The Interaction Of Radiation With Biomolecules

Other | December 1, 2006

bySabin, John R., John R. Sabin

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Advances in Quantum Chemistrypresents surveys of current developments in this rapidly developing field that falls between the historically established areas of mathematics, physics, chemistry, and biology. With invited reviews written by leading international researchers, each presenting new results, it provides a single vehicle for following progress in this interdisciplinary area.

* publishes articles, invited reviews and proceedings of major international conferences and workshops
* written by leading international researchers in quantum and theoretical chemistry
* highlights important interdisciplinary developments

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Advances in Quantum Chemistrypresents surveys of current developments in this rapidly developing field that falls between the historically established areas of mathematics, physics, chemistry, and biology. With invited reviews written by leading international researchers, each presenting new results, it provides a single vehicle for fo...

John R. Sabin was born in Springfield, Mass, and educated at Williams College (BA) and the University of New Hampshire (PhD). Following that, he was a postdoctoral at Uppsala University in Sweden, and at Northwestern University in Evanston, Ill. For the past four decades, he has worked in the Quantum Theory Project, Department of Physi...
Format:OtherDimensions:326 pages, 1 × 1 × 1 inPublished:December 1, 2006Publisher:Academic PressLanguage:English

The following ISBNs are associated with this title:

ISBN - 10:0080467407

ISBN - 13:9780080467405

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Table of Contents

Theoretical studies of the interaction of radiation with biomolecules (J.R. Sabin).
Free-radical-induced DNA damage as approached by quantum-mechanical and Monte Carlo calculations: an overview from the standpoint of an experimentalist
(C. von Sonntag).
Energy deposition models at the molecular level in biological systems (A. Munoz).
DFT Treatment of Radiation Produced Radicals in DNA Model Systems (Xifeng Li, M.D. Sevilla).
Computational Studies of Radicals Relevant to Nucleic Acid Damage (F. Turecek).
Radical cations of the nucleic bases and radiation damage to DNA: ab initio study (E. Cauët, J. Liévin).
Charge exchange and fragmentation in slow collisions of He2+ with water molecules (N. Stolterfohtet al.).
How Very Low-energy (0.1-2 eV) Electrons Cause DNA Strand Breaks (J. Simons).
Electron-driven molecular processes induced in biological systems by electromagnetic and other ionizing sources (I. Baccarelliet al.).
Electron Attachment to DNA Base Complexes (A.F. Jalbout, L. Adamowicz).
Accelerating multiple scattering of electrons emitted by ion impact: Contribution to molecular fragmentation and radiation damages (B. Sulik, K. Tokési).
Total Electron Stopping Powers and CSDA- Ranges from 20 eV to 10 MeV electron energies for components of DNA and RNA (A. Akaret al.).
The Influence of Stopping Powers upon Dosimetry for Radiation Therapy with energetic Ions (H. Paulet al.)