Coverart for item
The Resource Frontiers and advances in molecular spectroscopy, edited by Jaan Laane

Frontiers and advances in molecular spectroscopy, edited by Jaan Laane

Label
Frontiers and advances in molecular spectroscopy
Title
Frontiers and advances in molecular spectroscopy
Statement of responsibility
edited by Jaan Laane
Contributor
Editor
Subject
Genre
Language
eng
Cataloging source
IDEBK
Dewey number
539.6
Illustrations
illustrations
Index
index present
LC call number
QC454.M6
Literary form
non fiction
Nature of contents
  • dictionaries
  • bibliography
http://library.link/vocab/relatedWorkOrContributorName
Laane, Jaan
http://library.link/vocab/subjectName
  • Molecular spectroscopy
  • SCIENCE / Chemistry / Analytic
  • Molecular spectroscopy
Label
Frontiers and advances in molecular spectroscopy, edited by Jaan Laane
Instantiates
Publication
Copyright
Bibliography note
Includes bibliographical references at the end of each chapters and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Front Cover; Frontiers and Advances in Molecular Spectroscopy; Copyright; Contents; Contributors; Preface; Chapter 1: Stark-Induced Adiabatic Passage Processes to Selectively Prepare Vibrationally Excited Single and Superpositio ...; 1. Introduction; 1.1. How Can a Large Ensemble of Molecular Targets be Prepared in a Selected Highly Vibrationally Excited Quantum State W ...; 2. Theory of Stark-Induced Adiabatic Raman Passage; 2.1. SchrÃœdinger Equation for Stimulated Raman Pumping; 2.2. Density Matrix Equation; 2.3. Saturation of Raman Pumping in a High-Pressure Gas Cell
  • 2.4. Bloch Vector Model for Stark-Induced Adiabatic Passage2.5. Rabi Oscillations; 2.6. Coherent Population Return is a Problem for Stark-Induced Population Transfer; 2.7. How Do We Accomplish Stark-Induced Adiabatic Passage Using Pulsed Excitation?; 3. Theoretical Simulation of SARP for H2 v=0v=1 Transitions; 3.1. SARP is a Threshold Phenomenon; 4. Experimental Demonstration of SARP Preparing Single and Superpositions of Quantum States; 4.1. Preparation of a Bi-Axial Superposition State Within a Single Rovibrational H2 (v=1, J=2) Eigenstate
  • 4.2. Demonstration That SARP is a Robust Technique for Preparing a Desired Rovibrational M-Quantum State5. SARP Excitation of a High Vibrational (v=4) Level; 6. Vibrational Ladder Climbing Using Multicolor SARP; 6.1. How Do We Prepare A Diatomic Molecule in An Arbitrary High Vibrational Level?; 6.2. Theory of Four-Photon Three-Color SARP; 6.3. Vibrational Ladder Climbing of H2 Using Three-Color SARP; 6.4. Preparation of H2 (v=6, J=0) Using Three-Color SARP; 6.5. Preparation of a Pair of Loosely Bound H Atoms Using Four-Color Ladder SARP; 7. Other Related Adiabatic Passage Processes
  • 7.1. Stimulated Raman Adiabatic Passage7.2. High Vibrational Excitation Using STIRAP; 7.3. Multicolor STIRAP to Prepare High Vibrational States; 7.4. Stark-Chirped Rapid Adiabatic Passage; 8. Concluding Remarks; Acknowledgments; References; Chapter 2: Advances in Two-Dimensional Correlation Spectroscopy (2DCOS); 1. Introduction; 2. Generalized 2D Correlation Analysis; 2.1. Perturbation-Induced Dynamic Spectra; 2.2. 2D Correlation Analysis of Dynamic Spectra; 2.3. Matrix Notation for 2DCOS; 2.4. Unevenly Sampled Dynamic Spectra; 3. Interpreting 2D Correlation Spectra
  • 3.1. Simulated Model Spectra3.2. Properties of Synchronous Spectrum; 3.3. Properties of Asynchronous Spectrum; 4. Illustrative Example of 2DCOS Application; 5. Advanced Tools in 2DCOS; 5.1. Heterocorrelation Analyses; 5.2. Moving Window 2D Correlation; 5.3. Two-Dimensional Codistribution (2DCDS) Analysis; 5.4. Pareto Scaling; 5.5. Null-Space Projection; 6. Conclusions; References; Chapter 3: Applications of 2D-IR Spectroscopy to Probe the Structural Dynamics of DNA; 1. Introduction; 2. Methodology; 2.1. Obtaining 2D-IR Spectra; 2.2. Spectral Assignment of DNA 2D-IR Spectra
Control code
1017714331
Extent
1 online resource (788 pages)
Form of item
online
Isbn
9780128112212
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Other physical details
illustrations.
http://library.link/vocab/ext/overdrive/overdriveId
1048518
Specific material designation
remote
System control number
(OCoLC)1017714331
Label
Frontiers and advances in molecular spectroscopy, edited by Jaan Laane
Publication
Copyright
Bibliography note
Includes bibliographical references at the end of each chapters and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Front Cover; Frontiers and Advances in Molecular Spectroscopy; Copyright; Contents; Contributors; Preface; Chapter 1: Stark-Induced Adiabatic Passage Processes to Selectively Prepare Vibrationally Excited Single and Superpositio ...; 1. Introduction; 1.1. How Can a Large Ensemble of Molecular Targets be Prepared in a Selected Highly Vibrationally Excited Quantum State W ...; 2. Theory of Stark-Induced Adiabatic Raman Passage; 2.1. SchrÃœdinger Equation for Stimulated Raman Pumping; 2.2. Density Matrix Equation; 2.3. Saturation of Raman Pumping in a High-Pressure Gas Cell
  • 2.4. Bloch Vector Model for Stark-Induced Adiabatic Passage2.5. Rabi Oscillations; 2.6. Coherent Population Return is a Problem for Stark-Induced Population Transfer; 2.7. How Do We Accomplish Stark-Induced Adiabatic Passage Using Pulsed Excitation?; 3. Theoretical Simulation of SARP for H2 v=0v=1 Transitions; 3.1. SARP is a Threshold Phenomenon; 4. Experimental Demonstration of SARP Preparing Single and Superpositions of Quantum States; 4.1. Preparation of a Bi-Axial Superposition State Within a Single Rovibrational H2 (v=1, J=2) Eigenstate
  • 4.2. Demonstration That SARP is a Robust Technique for Preparing a Desired Rovibrational M-Quantum State5. SARP Excitation of a High Vibrational (v=4) Level; 6. Vibrational Ladder Climbing Using Multicolor SARP; 6.1. How Do We Prepare A Diatomic Molecule in An Arbitrary High Vibrational Level?; 6.2. Theory of Four-Photon Three-Color SARP; 6.3. Vibrational Ladder Climbing of H2 Using Three-Color SARP; 6.4. Preparation of H2 (v=6, J=0) Using Three-Color SARP; 6.5. Preparation of a Pair of Loosely Bound H Atoms Using Four-Color Ladder SARP; 7. Other Related Adiabatic Passage Processes
  • 7.1. Stimulated Raman Adiabatic Passage7.2. High Vibrational Excitation Using STIRAP; 7.3. Multicolor STIRAP to Prepare High Vibrational States; 7.4. Stark-Chirped Rapid Adiabatic Passage; 8. Concluding Remarks; Acknowledgments; References; Chapter 2: Advances in Two-Dimensional Correlation Spectroscopy (2DCOS); 1. Introduction; 2. Generalized 2D Correlation Analysis; 2.1. Perturbation-Induced Dynamic Spectra; 2.2. 2D Correlation Analysis of Dynamic Spectra; 2.3. Matrix Notation for 2DCOS; 2.4. Unevenly Sampled Dynamic Spectra; 3. Interpreting 2D Correlation Spectra
  • 3.1. Simulated Model Spectra3.2. Properties of Synchronous Spectrum; 3.3. Properties of Asynchronous Spectrum; 4. Illustrative Example of 2DCOS Application; 5. Advanced Tools in 2DCOS; 5.1. Heterocorrelation Analyses; 5.2. Moving Window 2D Correlation; 5.3. Two-Dimensional Codistribution (2DCDS) Analysis; 5.4. Pareto Scaling; 5.5. Null-Space Projection; 6. Conclusions; References; Chapter 3: Applications of 2D-IR Spectroscopy to Probe the Structural Dynamics of DNA; 1. Introduction; 2. Methodology; 2.1. Obtaining 2D-IR Spectra; 2.2. Spectral Assignment of DNA 2D-IR Spectra
Control code
1017714331
Extent
1 online resource (788 pages)
Form of item
online
Isbn
9780128112212
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Other physical details
illustrations.
http://library.link/vocab/ext/overdrive/overdriveId
1048518
Specific material designation
remote
System control number
(OCoLC)1017714331

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