Amsterdam ; ; Boston, : Elsevier, 2012

1-78268-947-8

1-283-39629-7

9786613396297

0-444-53783-X

1 online resource (473 p.)

572.51

Bioinorganic chemistry

Electronic books.

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Front Cover; Biological Inorganic Chemistry: A New Introduction to Molecular Structure and Function; Copyright; Contents; Preface to the 2nd Edition; Chapter 1 - An Overview of Metals and Selected Nonmetals in Biology; INTRODUCTION; WHY DO WE NEED ANYTHING OTHER THAN C, H, N, AND O (TOGETHER WITH SOME P AND S)?; WHAT ARE THE ESSENTIAL ELEMENTS AND THE ESSENTIAL METAL IONS?; AN IDIOSYNCRATIC VIEW OF THE PERIODIC TABLE; REFERENCES; Chapter 2 - Basic Coordination Chemistry for Biologists; INTRODUCTION; TYPES OF CHEMICAL BONDS; HARD AND SOFT LIGANDS; COORDINATION GEOMETRY; REDOX CHEMISTRY

REFERENCESChapter 3 - Structural and Molecular Biology for Chemists; INTRODUCTION; THE STRUCTURAL BUILDING BLOCKS OF PROTEINS; PRIMARY, SECONDARY, TERTIARY, AND QUATERNARY STRUCTURE OF PROTEINS; SECONDARY AND TERTIARY STRUCTURES OF NUCLEIC ACIDS; REFERENCES; Chapter 4 - Biological Ligands for Metal Ions; INTRODUCTION; INSERTION OF METAL IONS INTO METALLOPROTEINS; CHELATASE - THE TERMINAL STEP IN TETRAPYRROLE METALLATION; IRON-SULFUR CLUSTER FORMATION; MORE COMPLEX COFACTORS - MOCO, FEMOCO, P-CLUSTERS, H-CLUSTERS, AND CUZ; SIDEROPHORES;

REFERENCES

Chapter 5 - An Overview of Intermediary Metabolism and BioenergeticsINTRODUCTION; REDOX REACTIONS IN METABOLISM; THE CENTRAL ROLE OF ATP IN METABOLISM; THE TYPES OF REACTION CATALYSED BY ENZYMES OF INTERMEDIARY METABOLISM; AN OVERVIEW OF CATABOLISM; SELECTED CASE STUDIES - GLYCOLYSIS AND THE TRICARBOXYLIC ACID CYCLE; AN OVERVIEW OF ANABOLISM; SELECTED CASE STUDIES: GLUCONEOGENESIS AND FATTY ACID BIOSYNTHESIS; BIOENERGETICS - GENERATION OF PHOSPHORYL TRANSFER POTENTIAL AT THE EXPENSE OF PROTON GRADIENTS; REFERENCES; Chapter 6 - Methods to Study Metals in Biological Systems; INTRODUCTION

MAGNETIC PROPERTIESELECTRON PARAMAGNETIC RESONANCE (EPR) SPECTROSCOPY; MÖSSBAUER SPECTROSCOPY; NMR SPECTROSCOPY; ELECTRONIC AND VIBRATIONAL SPECTROSCOPIES; CIRCULAR DICHROISM AND MAGNETIC CIRCULAR DICHROISM; RESONANCE RAMAN SPECTROSCOPY; EXTENDED X-RAY ABSORPTION FINE STRUCTURE (EXAFS); X-RAY DIFFRACTION; REFERENCES; Chapter 7 - Metal Assimilation Pathways; INTRODUCTION; INORGANIC BIOGEOCHEMISTRY; METAL ASSIMILATION IN BACTERIA; METAL ASSIMILATION IN FUNGI AND PLANTS; METAL ASSIMILATION IN MAMMALS; REFERENCES; Chapter 8 - Transport, Storage, and Homeostasis of Metal Ions; INTRODUCTION

METAL STORAGE AND HOMEOSTASIS IN BACTERIAMETAL TRANSPORT, STORAGE, AND HOMEOSTASIS IN PLANTS AND FUNGI; METAL TRANSPORT, STORAGE, AND HOMEOSTASIS IN MAMMALS; REFERENCES; Chapter 9 - Sodium and Potassium - Channels and Pumps; INTRODUCTION - TRANSPORT ACROSS MEMBRANES; SODIUM VERSUS POTASSIUM; POTASSIUM CHANNELS; SODIUM CHANNELS; THE SODIUM-POTASSIUM ATPASE; ACTIVE TRANSPORT DRIVEN BY NA+ GRADIENTS; SODIUM/PROTON EXCHANGERS; OTHER ROLES OF INTRACELLULAR K+; REFERENCES; Chapter 10 - Magnesium-Phosphate Metabolism and Photoreceptors; INTRODUCTION; MAGNESIUM-DEPENDENT ENZYMES

PHOSPHORYL GROUP TRANSFER KINASES

The revised and expanded second edition of Biological Inorganic Chemistry, winner of a 2013 Texty Award from the Text and Academic Authors Association, presents an introduction to this exciting and dynamic field. An increasing understanding of the importance of metals in biology, the environment and medicine, and the multiple roles of metal ions in biological systems, has given rise to biological inorganic chemistry as a field of study.    The book begins with an overview of the concepts, both chemical and biological, required for the detailed analysis which follows. Pathways of

Singapore, : World Scientific Pub. Co., 2013

New Jersey : , : World Scientific, , [2013]

�2013

981-4366-94-3

1 online resource (xi, 281 pages) : illustrations

World Scientific series on nonlinear science. Series A ; ; v. 83

531.1133

Turbulence

Nonlinear waves

Inglese

Description based upon print version of record.

Includes bibliographical references.

Preface; Contents; 1. Wave Turbulence: A Story Far from Over Alan C. Newell and Benno Rumpf; 1.1. Introduction; 1.2. A Tutorial on the Wave Turbulence Closure; 1.3. Solutions of the Kinetic Equation; 1.4. Experimental Evidence; 1.4.1. Capillary wave turbulence; 1.4.2. Gravity wave turbulence; 1.4.3. Vibrating plate turbulence: can one hear the Kolmogorov spectrum?; 1.4.4. Condensates of classical light waves; 1.5. Two Open Questions; 1.6. Open Challenges; Appendix 1. Derivation of the Governing Equation for Gravity-Capillary Waves; Appendix 2. Asymptotic Analysis; Acknowledgment; Bibliography

2. Fluctuations of the Energy Flux in Wave Turbulence S. Aumaıtre, E. Falcon and S. Fauve2.1. Introduction; 2.2. Spectra in the Gravity and Capillary Regimes; 2.3. Direct Measurement of the Injected Power; 2.4. Fluctuations of the Energy Flux; 2.5. Conclusion; Acknowledgment; Bibliography; 3. Wave Turbulence in Astrophysics Sebastien Galtier; 3.1. Introduction; 3.2. Waves and Turbulence in Space Plasmas; 3.2.1. Interplanetary medium; 3.2.2. Solar atmosphere; 3.3. Turbulence and Anisotropy; 3.3.1. Navier-Stokes turbulence; 3.3.2. Incompressible MHD turbulence; 3.3.2.1. Strong turbulence

3.3.2.2. Iroshnikov-Kraichnan spectrum3.3.2.3. Breakdown of isotropy; 3.3.2.4. Emergence of anisotropic laws; 3.3.3. Towards an Alfven wave turbulence theory; 3.3.4. Wave turbulence in compressible MHD; 3.3.5.

Wave turbulence in Hall and electron MHD; 3.4. Wave Turbulence Formalism; 3.4.1. Wave amplitude equation; 3.4.2. Statistics and asymptotics; 3.4.3. Wave kinetic equations; 3.4.4. Finite flux solutions; 3.5. Main Results and Predictions; 3.5.1. Alfven wave turbulence; 3.5.2. Compressible MHD; 3.5.3. Whistler wave turbulence; 3.5.4. Hall MHD; 3.6. Conclusion and Perspectives

3.6.1. Observations3.6.2. Simulations; 3.6.3. Open questions; Bibliography; 4. Optical Wave Turbulence S. K. Turitsyn, S. A. Babin, E. G. Turitsyna, G. E. Falkovich, E. V. Podivilov and D. V. Churkin; 4.1. Optical Wave Turbulence: Introduction; 4.2. Basics of Fiber Lasers; 4.3. Key Mathematical Models; 4.4. Weak Optical Wave Turbulence in Fiber Lasers; 4.4.1. Theory of weak wave turbulence in the context of fiber laser; 4.4.2. Experiments; 4.4.3. Statistical properties and optical rogue wave generation via wave turbulence in RFLs; 4.5. Optical Wave Turbulence in Ultra-Long Fiber Lasers

4.5.1. Basics of ultra-long fiber lasers4.5.2. Mode structure in ultra-long fiber lasers; 4.5.3. Nonlinear broadening of optical spectra; 4.6. Developed Optical Wave Turbulence in Fiber Lasers; 4.6.1. The impact of fiber dispersion; 4.7. Spectral Condensate in Fiber Lasers; 4.8. Conclusions and Perspectives; Acknowledgments; Bibliography; 5. Wave Turbulence in a Thin Elastic Plate: The Sound of the Kolmogorov Spectrum? G. During and N. Mordant; 5.1. Weak Turbulence Theory for Thin Elastic Plates; 5.1.1. The Foppl-von Karman equations for a thin elastic plate

5.1.2. Kinetic equation and spectra

Wave or weak turbulence is a branch of science concerned with the evolution of random wave fields of all kinds and on all scales, from waves in galaxies to capillary waves on water surface, from waves in nonlinear optics to quantum fluids. In spite of the enormous diversity of wave fields in nature, there is a common conceptual and mathematical core which allows us to describe the processes of random wave interactions within the same conceptual paradigm, and in the same language. The development of this core and its links with the applications is the essence of wave turbulence science (WT) whi