Record Display for the EPA National Library Catalog

RECORD NUMBER: 710 OF 1241

OLS Field Name OLS Field Data
Main Title Modern Optical Spectroscopy With Exercises and Examples from Biophysics and Biochemistry / [electronic resource] :
Type EBOOK
Author Parson, William W.
Publisher Springer Berlin Heidelberg : Imprint: Springer,
Year Published 2015
Call Number QH345; QD415-436
ISBN 9783662467770
Subjects Life sciences. ; Spectroscopy. ; Biochemistry.
Internet Access
Description Access URL
http://dx.doi.org/10.1007/978-3-662-46777-0
Edition 2nd ed. 2015.
Collation XVI, 572 p. 196 illus. online resource.
Notes
Due to license restrictions, this resource is available to EPA employees and authorized contractors only
Contents Notes
Introduction -- Basic concepts of quantum mechanics -- Light -- Electronic absorption -- Fluorescence -- Vibrational absorption -- Resonance energy transfer -- Exciton interactions -- Circular dichroism -- Coherence and dephasing -- Pump-probe spectroscopy, photon echoes and vibrational wavepackets -- Raman scattering and other two-photon processes -- Appendix. This textbook offers clear explanations of optical spectroscopic phenomena and shows how spectroscopic techniques are used in modern molecular and cellular biophysics and biochemistry. The topics covered include electronic and vibrational absorption, fluorescence, resonance energy transfer, exciton interactions, circular dichroism, coherence and dephasing, ultrafast pump-probe and photon-echo spectroscopy, single-molecule and fluorescence-correlation spectroscopy, Raman scattering, and multiphoton absorption. This revised and updated edition provides expanded discussions of quantum optics, metal-ligand charge-transfer transitions, entropy changes during photoexcitation, electron transfer from excited molecules, normal-mode calculations, vibrational Stark effects, studies of fast processes by resonance energy transfer in single molecules, and two-dimensional electronic and vibrational spectroscopy. The explanations are sufficiently thorough and detailed to be useful for researchers and graduate students and advanced undergraduates in chemistry, biochemistry and biophysics. They are based on time-dependent quantum mechanics, but are developed from first principles with a clarity that makes them accessible to readers with little prior training in this field. Extra topics and highlights are featured in special boxes throughout the text. The author also provides helpful exercises for each chapter.