Frontiers of Molecular Spectroscopy

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Informationen zum Autor Jaan Laane graduated high school as class valedictorian and then attended the University of Illinois as a Sloan Scholar and James Scholar. He graduated with Highest Distinction in Chemistry in 1964 receiving the Kendall Award as the top chemistry major. He then carried out graduate work at MIT with Richard C. Lord as a National Science Foundation and Woodrow Wilson Fellow, receiving his Ph.D. and the Kodak Award as the top graduate student in 1967. Following a year at Tufts University, Jaan moved to Texas A&M University where he soon was promoted to Full Professor (1976). His research focused on the determination of vibrational potential energy surfaces in both ground and excited electronic states. He has contributed to the theoretical understanding of molecular vibrations and structures and to the experimental methodology in these areas. He has more than 300 publications and three books. He has been in the forefront of writing computer programs for analyzing potential energy surfaces. These have been widely distributed and utilized. Laane has supervised the research of more than 40 Ph.D. students, 60 undergraduates, and dozens of post-docs and visiting professors. He has received the Humboldt Award, a Texas A&M teaching award and the Lippincott Award among others. He was Chair of the Physical and Nuclear Chemistry Division for many years and Associate Dean of Science and Speaker of the Faculty Senate. Since 1994, Laane has been Editor for the Journal of Molecular Structure. Klappentext For more than a century scientists have utilized how electromagnetic radiation, including the microwave, infrared, visible, and ultraviolet regions, interacts with atoms and molecules in order to learn the properties of matter. In this book, twenty chapters written by eminent scientists from around the world describe work at the cutting edge of molecular spectroscopy. Insight into how spectroscopy is used to study biological systems, archeological artifacts, chemical reactions, excited molecules, physical systems, and many others is presented. New methodology, instrumentation, and theory are described providing a broad comprehensive view of molecular spectroscopy at the present time. Inhaltsverzeichnis Preface. 1. Old spectroscopists forget a lot but they do remember their lines (H. Kroto). 2. Frontiers of linear and non-linear Raman spectroscopy : From a molecule to a living cell (H-o. Hamaguchi). 3. Structure and dynamics of high Rydberg states studied by high-resolution spectroscopy and multichannel quantum defect theory (M. Schäfer, F. Merkt). 4. Vibrational potential energy surfaces in electronic excited states (J. Laane). 5. Raman spectroscopy in art and archeology: A new light on historical mysteries (H.G.M. Edwards). 6. Real-time vibrational spectroscopy and ultrafast structural relaxation (T. Kobayashi). 7. Using coherent Raman spectroscopy to detect bacterial spores via optimized pulse configuration (D. Pestov, A.V. Sokolov, M.O. Scully). 8. High resolution Terahertz spectroscopy and applications to astrophysics (S. Schlemmer, et al). 9. Selective protein and nuclear acid detection with biofunctionalized SERS labels (S. Schlücker, W. Kiefer). 10. Surface-enhanced Raman scattering spectroscopy - electromagnetic mechanism and biomedical applications (T. Itoh, A. Sujith, Y. Ozaki). 11. Spectroscopy and broken symmetry (P.R. Bunker, P. Jensen). 12. Broadband modulation of light by coherent molecular oscillations (A.M. Burzo, A.V. Sokolov). 13. Generalized two-dimensional correlation spectroscopy (I. Noda). 14. Microwave spectroscopy: Experimental techniques (J-U. Grabow, W. Caminati). 15. Microwave spectroscopy: Molecular systems (W. Caminati and J-U. Grabow). 16. Raman spectroscopy of viruses and viral proteins (D.Nìmeèek, G.J. Thomas, Jr.). 17. Vibrational spectroscopy via inelastic neutron scattering (B.S. Hudson). 18. Optimal signal ...

List of contents

Preface. 1. Old spectroscopists forget a lot but they do remember their lines (H. Kroto). 2. Frontiers of linear and non-linear Raman spectroscopy : From a molecule to a living cell (H-o. Hamaguchi). 3. Structure and dynamics of high Rydberg states studied by high-resolution spectroscopy and multichannel quantum defect theory (M. Schäfer, F. Merkt). 4. Vibrational potential energy surfaces in electronic excited states (J. Laane). 5. Raman spectroscopy in art and archeology: A new light on historical mysteries (H.G.M. Edwards). 6. Real-time vibrational spectroscopy and ultrafast structural relaxation (T. Kobayashi). 7. Using coherent Raman spectroscopy to detect bacterial spores via optimized pulse configuration (D. Pestov, A.V. Sokolov, M.O. Scully). 8. High resolution Terahertz spectroscopy and applications to astrophysics (S. Schlemmer, et al). 9. Selective protein and nuclear acid detection with biofunctionalized SERS labels (S. Schlücker, W. Kiefer). 10. Surface-enhanced Raman scattering spectroscopy - electromagnetic mechanism and biomedical applications (T. Itoh, A. Sujith, Y. Ozaki). 11. Spectroscopy and broken symmetry (P.R. Bunker, P. Jensen). 12. Broadband modulation of light by coherent molecular oscillations (A.M. Burzo, A.V. Sokolov). 13. Generalized two-dimensional correlation spectroscopy (I. Noda). 14. Microwave spectroscopy: Experimental techniques (J-U. Grabow, W. Caminati). 15. Microwave spectroscopy: Molecular systems (W. Caminati and J-U. Grabow). 16. Raman spectroscopy of viruses and viral proteins (D.Nìmeèek, G.J. Thomas, Jr.). 17. Vibrational spectroscopy via inelastic neutron scattering (B.S. Hudson). 18. Optimal signal processing in cavity ring-down spectroscopy (K.Lehmann, H. Huang). 19. Spectroscopy and dynamics of neutrals and ions by high-resolution IR-VUV laser photoionization and photoelectron methods (C-Y. Ng).