Physical Methods for Inorganic Biochemistry

Physical Methods for Inorganic Biochemistry by John R. Wright, Wayne A. Hendrickson, Shigemasa Osaki, Gordon T. James.

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Bibliographic Details
Main Authors: Wright, John R. (Author), Hendrickson, Wayne A. (Author), Osaki, Shigemasa (Author), James, Gordon T. (Author)
Corporate Author: SpringerLink (Online service)
Format: eBook
Language:English
Published: New York, NY : Springer US : Imprint: Springer, 1986.
Edition:1st ed. 1986.
Series:Biochemistry of the Elements ; 5
Springer eBook Collection.
Subjects:
Pharmacology.
Biochemistry.
Physical chemistry.
Electronic resources (E-books)
Online Access:Click to view e-book
Holy Cross Note:Loaded electronically.
Electronic access restricted to members of the Holy Cross Community.
Table of Contents:
  • 1. Introduction
  • 1.1 Physical Methods
  • 1.2 Probable Future Trends in Physical Instrumentation
  • References
  • 2. Nuclear Magnetic Resonance (Nmr)
  • 2.1 The Phenomenon
  • 2.2 Multinuclear Nmr
  • 2.3 Nmr Phenomena Related to Molecular Structure
  • 2.4 Instrument Characteristics
  • 2.5 Sample Manipulation (Two-Way Communication)
  • 2.6 Biological Considerations
  • References
  • Appendix A: Correlation Nmr
  • Appendix B: Mathematical Symbols Used in Chapter 2
  • 3. Nuclear Quadrupole Resonance (Nqr)
  • 3.1 Properties of Nqr
  • 3.2 Relationship to Mössbauer, Esr, and Nmr Spectroscopy
  • 3.3 Instrumentation
  • 3.4 Applications
  • References
  • 4. Mössbauer Spectroscopy
  • 4.1 Instrumentation
  • 4.2 Conversion Electron Detection
  • 4.3 Sample Considerations
  • 4.4 Mössbauer Effect and the Chemical Environment
  • 4.5 Biological Applications of 57Fe
  • 4.6 Mössbauer Isotopes Other than 57Fe
  • 4.7 Mössbauer Emission Spectra
  • 4.8 Bragg Scattering Effects
  • References
  • 5. Electron Spin Resonance (Esr)
  • 5.1 Introduction
  • 5.2 Theory
  • 5.3 Esr Instrumentation
  • 5.4 Applications
  • References
  • 6. X-ray Diffraction Methods for the Analysis of Metalloproteins
  • 6.1 Introduction
  • 6.2 Theoretical Basis
  • 6.3 Experimental Procedures
  • 6.4 Structural Analysis
  • 6.5 Applications
  • References
  • 7. Electron Energy Levels: Electron Spectroscopy and Related Methods
  • 7.1 Electron Spectroscopy for Chemical Analysis (ESCA) and Ultraviolet Photoelectron Spectroscopy (UPS)
  • 7.2 Auger (Secondary Electron) Spectroscopy
  • References
  • 8. Laser Applications: Resonance Raman (RR) Spectroscopy and Related Methods
  • 8.1 Perspective
  • 8.2 Resonance Raman (RR) Spectroscopy
  • 8.3 Sample Considerations
  • 8.4 Symmetry and the Intensity of Vibrational Absorptions
  • 8.5 Vibrational Energy Levels
  • 8.6 Applications
  • 8.7 Newer Methods Which Minimize Fluorescence Interference
  • References
  • 9. Circular Dichroism (CD) and Magnetic Circular Dichroism (MCD)
  • 9.1 The Relationship between ORD, CD, MORD, and MCD
  • 9.2 Sample Considerations
  • 9.3 Effects Observed in MCD Spectra
  • 9.4 Biochemical Applications
  • References
  • 10. Kinetic Methods
  • 10.1 Introduction
  • 10.2 Methods
  • 10.3 Applications
  • References
  • 11. Bioinorganic Topochemistry: Microprobe Methods of Analysis
  • 11.1 Electron Probe Microanalysis
  • 11.2 Ion, Laser, and Proton Microprobe Analysis of Elements
  • References
  • 12. Neutron Activation Analysis
  • 12.1 Introduction
  • 12.2 Applications and Examples of Neutron Activation
  • References.

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