Subject |
Bioinorganic chemistry.
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Chemistry, Inorganic.
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Chemistry.
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Descript |
1 online resource (598 p.) |
Note |
Description based upon print version of record. |
Contents |
Applications of Physical Methods to Inorganic and Bioinorganic Chemistry -- Copyright Page -- Contents -- List of Contributors -- Series Preface -- Volume Preface -- Circular Dichroism (CD) Spectroscopy -- Method Summary -- 1 Introduction -- 2 Technical Background -- 2.1 Measuring CD Spectra -- 2.2 Choice of Cuvettes -- 3 Applications -- 3.1 Identification of Protein Secondary Structure -- 3.2 CD Spectra of: Complexes of the Group 8-10 Transition Metals -- 3.3 CD Spectra of Group 11 Metals -- 3.4 CD Spectra of Complexes involving Group 12 metals |
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3.5 CD Spectral Data from other Metal Complexes -- 3.6 Metallothioneins: a Special Case of a Metalloprotein with Highly Sensitive Metal-dependent CD Spectral Properties -- 4 Acknowledgments -- 5 Abbreviations and Acronyms -- 6 References -- Electrochemistry -- Method Summary -- 1 Introduction -- 2 Technical Background -- 2.1 Electrode Reaction Fundamentals -- 2.2 Potentials of Electrochemical Reactions, E. -- 2.3 Electrochemical Cells and Practical Considerations -- 2.4 Electrochemical Processes -- 3 Applications -- 3.1 Potential Sweep Methods -- 3.2 Potential Step/Pulsed Methods |
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3.3 Hydrodynamic Methods -- 3.4 Bulk Electrolysis (BE) -- 3.5 Electrochemical Simulations -- 3.6 Correlation of Electrochemistry to Electronic Spectroscopy -- 3.7 Coupled Techniques -- 4 Acknowledgments -- 5 Abbreviations and Acronyms -- 6 Further Reading -- 7 References -- Electron Paramagnetic Resonance (EPR) Spectroscopy -- Method Summary -- 1 Introduction -- 1.1 History and Terminology -- 2 Relationship Between ''Spin'', Angular Momentum, and Magnetic Moment -- 3 Zeeman Interaction -- 4 Electrons in Atoms and Molecules -- 5 The EPR Experiment-Measuring ''g'' |
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5.1 The EPR Spectrometer-How it Works -- 5.2 What Energy Is Used for Irradiation? -- 5.3 How Much Sample Is Needed? -- 5.4 Why the First Derivative? -- 5.5 Line Shape -- 5.6 Saturation and Spin Relaxation -- 6 The EPR Spectrometer-Setting the Parameters -- 7 Rapid Passage -- 8 Hyperfine Interaction-the Effect of Nuclear Spin -- 9 Anisotropy -- 10 Powder Spectra -- 11 Examples of S = 1/2 Signals in Metalloproteins -- 11.1 Sign of the Deviation of the g-factor from ge -- 11.2 Copper (Cu2+) -- 11.3 Vanadium (V4+) -- 11.4 Molybdenum (Mo5+) -- 11.5 Low-spin Heme (Fe3+) -- 11.6 Iron-Sulfur Clusters |
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12 S > 1/2 Spectra -- 12.1 The Energy Equation -- 12.2 Half-integer (Kramers) Systems -- 13 Example of S = 3/2 System-MoFe Protein of Nitrogenase -- 14 Example of S = 5/2 -- 14.1 Aquometmyoglobin -- 15 Integer-Spin (non-Kramers) Systems -- 16 Abbreviations and Acronyms -- 17 Related Articles -- 18 Further Reading -- 19 References -- Electron Spin Echo Envelope Modulation (ESEEM) Spectroscopy -- Method Summary -- 1 Introduction -- 2 Technical Background -- 2.1 Two-pulse ESEEM -- 2.2 Three-pulse ESEEM -- 2.3 Two-dimensional ESEEM -- 2.4 Practical Aspects of ESEEM Experiments |
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3 Application-Eseem Studies of Fe(II)/α-Ketoglutarate-Dependent Dioxygenases |
Note |
200 annual accesses. UkHlHU |
Alt author |
Lukehart, Charles M.
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ISBN |
9781118625262 |
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