Time-resolved mass spectrometry /
Time is an important factor in physical and natural sciences. It characterizes the progress of chemical and biochemical processes. Mass spectrometry provides the means to study molecular structures by detecting gas-phase ions with the unique mass-to-charge ratios. Time-resolved mass spectrometry (TR...
Clasificación: | Libro Electrónico |
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Autores principales: | , , |
Formato: | Electrónico eBook |
Idioma: | Inglés |
Publicado: |
Chichester, West Sussex :
John Wiley & Sons, Inc.,
2016.
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Temas: | |
Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Title Page; Copyright; Table of Contents; Author Biographies; Preface; Acknowledgments; List of Acronyms; Chapter 1: Introduction; 1.1 Time in Chemistry; 1.2 Mass Spectrometry; 1.3 Time-resolved Mass Spectrometry; 1.4 Dynamic Matrices; 1.5 Real-time vs. Single-point Measurements; 1.6 Further Reading; References; Chapter 2: Ion Sources for Time-resolved Mass Spectrometry; 2.1 Electron Ionization; 2.2 Chemical Ionization; 2.3 Atmospheric Pressure Chemical Ionization; 2.4 Electrospray Ionization; 2.5 Atmospheric Pressure Photoionization; 2.6 Desorption/Ionization.
- 2.7 Innovations in the 21st Century2.8 Concluding Remarks; References; Chapter 3: Mass Analyzers for Time-resolved Mass Spectrometry; 3.1 Overview; 3.2 Individual Mass Analyzers; 3.3 Integrated Analytical Techniques; References; Chapter 4: Interfaces for Time-resolved Mass Spectrometry; 4.1 Molecules in Motion; 4.2 Time-resolved Mass Spectrometry Systems; 4.3 Concluding Remarks; References; Chapter 5: Balancing Acquisition Speed and Analytical Performance of Mass Spectrometry; 5.1 Overview; 5.2 Spectrum Acquisition Speed.
- 5.3 Relationship between Spectrum Acquisition Time and Mass Spectrometer PerformanceReferences; Chapter 6: Hyphenated Mass Spectrometric Techniques; 6.1 Introduction; 6.2 Separation Techniques Coupled with Mass Spectrometry; 6.3 Ion-mobility Spectrometry; 6.4 Other Hyphenated Systems; 6.5 Influence of Data Acquisition Speed; 6.6 Concluding Remarks; References; Chapter 7: Microfluidics for Time-resolved Mass Spectrometry; 7.1 Overview; 7.2 Fabrication; 7.3 Microreaction Systems; 7.4 Hydrodynamic Flow; 7.5 Coupling Microfluidics with Mass Spectrometry; 7.6 Examples of Applications.
- 7.7 Digital Microfluidics7.8 Concluding Remarks; References; Chapter 8: Quantitative Measurements by Mass Spectrometry; 8.1 The Challenge of Quantitative Mass Spectrometry Measurements; 8.2 Selection of Instrument; 8.3 Solutions to Quantitative Mass Spectrometry; 8.4 Data Treatment; 8.5 Concluding Remarks; References; Chapter 9: Data Treatment in Time-resolved Mass Spectrometry; 9.1 Overview; 9.2 Definition of Terms; 9.3 Spectral Patterns; 9.4 Mass Accuracy; 9.5 Structural Derivation; 9.6 Molecule Abundance; 9.7 Time-dependent Data Treatment; References.
- Chapter 10: Applications in Fundamental Studies of Physical Chemistry10.1 Overview; 10.2 Chemical Kinetics; 10.3 Chemical Equilibrium; References; Chapter 11: Application of Time-resolved Mass Spectrometry in the Monitoring of Chemical Reactions; 11.1 Organic Reactions; 11.2 Catalytic Reactions; 11.3 Photochemical Reactions; 11.4 Concluding Remarks; References; Chapter 12: Applications of Time-resolved Mass Spectrometry in the Studies of Protein Structure Dynamics; 12.1 Electrospray Ionization in Protein Studies; 12.2 Mass Spectrometry Strategies for Ultra-fast Mixing and Incubation.