ALBERT

Note: Passadena, California Inst. of Technology, Diss., 1980

Note: Contents Preface Preface to the First Edition List of figures Abbreviations 1 Historical perspective (Roland A. Madden and Paul R. Julian) 1.1 Introduction 1.2 The intraseasonal, tropospheric oscillation 1.3 The elementary 4-D structure 1.4 Other early studies of the oscillation 1.5 The oscillation in 1979 1.6 Complexity of cloud movement and structure 1.7 Seasonal variations in the oscillation 1.8 The oscillation in the zonal average 1.9 Other effects of the oscillation 1.10 Summary 1.11 References 2 South Asian monsoon (B. N. Goswami) 2.1 Introduction 2.1.1 South Asian summer monsoon and active/break cycles 2.1.2 Amplitude and temporal and spatial scales 2.1.3 Regional propagation characteristics 2.1.4 Relationship between poleward-propagating ISOs and monsoon onset 2.1.5 Relationship with the MJO 2.2 Mechanism for temporal-scale selection and propagation 2.2.1 30 to 60-day mode 2.2.2 10 to 20-day mode 2.3 Air-sea interactions 2.4 Clustering of synoptic events by ISOs 2.5 Monsoon ISOs and predictability of the seasonal mean 2.6 Aerosols and monsoon ISOs 2.7 Predictability and prediction of monsoon ISOs 2.8 Summary and discussion 2.9 Acknowledgments 2.10 Appendix 2.11 References 3 Intraseasonal variability of the atmosphere-ocean-climate system: East Asian monsoon (Huang-Hsiung Hsu) 3.1 Introduction 3.2 General characteristics of EA/WNP monsoon flow 3.3 Periodicity, seasonality, and regionality 3.4 Intraseasonal oscillation propagation tendency 3.5 Relationship with monsoon onsets and breaks 3.6 The 10 to 30-day and 30 to 60-day boreal summer ISO 3.6.1 The 30 to 60-day northward/northwestward-propagating pattern 3.6.2 The 10 to 30-day westward-propagating pattern 3.7 Relationship with tropical cyclone activity 3.8 Upscale effect of TC and synoptic systems 3.9 Final remarks 3.9.1 Close association with the EA/WNP monsoon 3.9.2 The CISO vs. interannual variability 3.9.3 Multiperiodicities and multiscale interaction 3.9.4 Others 3.10 References 4 Pan America (Kingtse C. Mo, Charles Jones, and Julia Nogues Paegle) 4.1 Introduction 4.2 Variations in the IS band 4.3 IS variability in December-March 4.3.1 EOF modes 4.3.2 The Madden Julian Oscillation 4.3.3 The submonthly oscillation 4.4 IS variability in June-September 4.4.1 EOF modes 4.4.2 Madden-Julian Oscillation 4.4.3 Submonthly oscillation 4.5 Intraseasonal modulation of hurricanes 4.6 Summary 4.7 References 5 Australasian monsoon (M. C. Wheeler and J. L. McBride) 5.1 Introduction 5.2 Seasonal cycle of background flow 5.3 Broadband intraseasonal behavior: Bursts and breaks 5.4 Broadband intraseasonal behavior: Spectral analysis 5.5 Meteorology of the bursts and breaks 5.6 Characteristics and influence of the MJO 5.7 1983/1984 and 1987/1988 case studies 5.8 MJO influence on monsoon onset 5.9 Other modes and sources of ISV 5.10 Modulation of tropical cyclones 5.11 Extratropical-tropical interaction 5.12 Prediction 5.13 Conclusions 5.14 References 6 The oceans (William S. Kessler) 6.1 Introduction 6.2 Heat fluxes 6.2.1 Salinity and the barrier layer 6.2.2 A 1-D heat balance? 6.2.3 The role of advection 6.3 Vertical structure under westerly winds 6.4 Remote signatures of wind-forced Kelvin waves 6.5 El Nino and rectification of ISV 6.6 ISV in the Indian Ocean 6.6.1 Differences between the Indian and Pacific Ocean warm pools and their consequences 6.6.2 Oscillations lasting about 60 days in the western equatorial Indian Ocean 6.6.3 Recent models of wind-forced ISV in the Indian Ocean 6.7 Other intrinsic oceanic ISV 6.7.1 Global ISV 6.7.2 Non-TISO-forced ISV in the tropical Indo-Pacific 6.7.3 ISV outside the equatorial Indo-Pacific 6.8 Conclusion 6.9 References 7 Air-sea interaction (Harry Hendori) 7.1 Introduction 7.2 Air-sea fluxes for the eastward MJO 7.3 Air-sea fluxes associated with northward propagation in the Indian summer monsoon 7.4 SST variability 7.5 Mechanisms of SST variability 7.6 SST-atmosphere feedback 7.7 Impact of slow SST variations on MJO activity 7.8 Concluding remarks 7.9 Acknowledgments 7.10 References 8 Mass, momentum, and geodynamics (Benjamin F. Chao and David A. Salstein) 8.1 Introduction 8.2 Angular momentum variations and Earth rotation 8.2.1 Length-of-day variation and axial angular momentum 8.2.2 Polar motion excitation and equatorial angular momentum 8.2.3 Angular momentum and torques 8.3 Time-variable gravity 8.4 Geocenter motion 8.5 Conclusions 8.6 Acknowledgments 8.7 References 9 El Nino Southern Oscillation connection (William K. M. Lau) 9.1 Introduction 9.2 A historical perspective 9.3 Phase 1: The embryonic stage 9.3.1 OLR time-longitude sections 9.3.2 Seasonality 9.3.3 Supercloud clusters 9.3.4 Early modeling framework 9.4 Phase 2: The exploratory stage 9.4.1 MJO and ENSO interactions 9.4.2 WWEs 9.5 Phase 3: ENSO case studies 9.5.1 El Nino of 1997/1998 9.5.2 Stochastic forcings 9.6 Phase-4: Recent development 9.6.1 A new ISO index 9.6.2 Composite events 9.6.3 The ISV-ENSO biennial rhythm 9.7 TISV and predictability 9.8 Acknowledgments 9.9 References 10 Theories (Bin Wang) 10.1 Introduction 10.2 Review of ISO theories 10.2.1 Wave CISK 10.2.2 Wind-evaporation feedback or WISHE 10.2.3 Frictional convergence instability (FCI) 10.2.4 Cloud-radiation feedback 10.2.5 Convection-water vapor feedback and the moisture mode 10.2.6 Multiscale interaction theory 10.2.7 Mechanisms of the boreal summer intraseasonal oscillation 10.2.8 Atmosphere-ocean interaction 10.3 A general theoretical framework 10.3.1 Fundamental physical processes 10.3.2 Governing equations 10.3.3 Boundary layer dynamics near the equator 10.3.4 The 1.5-layer model for the MJO 10.3.5 The 2.5-layer model including the effects of basic flows 10.4 Dynamics of the MJO 10.4.1 Low-frequency equatorial waves and the associated Ekman pumping 10.4.2 Frictional convergence instability (FCI) 10.4.3 FCI mode under nonlinear heating 10.4.4 The role of multiscale interaction (MSI) in MJO dynamics 10.5 Dynamics of boreal summer ISO 10.5.1 Effects of mean flows on the ISO 10.5.2 Mechanism of northward propagation 10.6 Role played by atmospheric-ocean interaction 10.7 Summary and discussion 10.7.1 Understanding gained from the FCI theory 10.7.2 Model limitations 10.7.3 Outstanding issues 10.8 Acknowledgments 10.9 References 11 Modeling intraseasonal variability (K. R. Sperber, J. M. Slingo, and P. M. Inness) 11.1 Introduction 11.2 Modeling the MJO in boreal winter 11.2.1 Interannual and decadal variability of the MJO 11.2.2 Sensitivity to formulation of the atmospheric model 11.2.3 Modeling the MJO as a coupled ocean-atmosphere phenomenon 11.3 Boreal summer intraseasonal variability 11.3.1 GCM simulations 11.3.2 Air-sea interaction and boreal summer intraseasonal variability 11.3.3 Modeling studies of the links between boreal summer intraseasonal and interannual variability 11.4 The impact of vertical resolution in the upper ocean 11.5 Concluding remarks 11.6 Acknowledgments 11.7 References 12 Predictability and forecasting (Duane Waliser) 12.1 Introduction 12.2 Empirical models 12.3 Dynamical forecast models 12.4 Predictability 12.5 Real time forecasts 12.6 Discussion 12.7 Appendix 12.8 Acknowledgments 12.9 References 13 Africa and West Asia (Mathew Barlow) 13.1 Overview 13.2 Summary of Africa research 13.2.1 West Africa 13.2.2 Eastern Africa 13.2.3 Southern Africa 13.3 Summary of West Asia research 13.4 Station data analysis 13.4.1 Methodology and data 13.4.2 Nairobi 13.4.3 Riyadh 13.5 Relevance of Gill-Matsuno dynamics and the role of mean wind 13.6 Summary and discussion 13.7 References 14 Tropical-extratropical interactions (Paul E. Roundy) 14.1 Introduction 14.2 A boreal winter composite of the global flow associated with the MJO 14.3 Response of the global atmosphere to heating in tropical convection 14.4 Influence of extratropical waves on tropical convection 14.5 Two-way interactions between the tropics and extratropics 14.6 MJO inf

Note: Contents: Preface to the Second Edition. - Preface to the First Edition. - 1. INTRODUCTION AND HISTORICAL BACKGROUND. - History. - The Discovery of X-Rays. - The Discovery of X-Ray Diffraction. - History of Clay Mineralogy. - The Importance of Clay Mineralogy. - Box 1.1 Clay Minerals as Catalysts. - The Literature of Clay Mineralogy. - Summary. - References. - 2. NATURE AND PRODUCTION OF X-RAYS. - Box 2.1 Other Methods. - Safety and Protection. - Box 2.2 Defining a Dose of Radiation. - The Nature or X-Rays. - Continuous or White Radiation. - Characteristic Radiation. - General Absorption of X-Rays. - Characteristic Absorption. - Equipment for Producing and Recording X-Rays. - Stabilizing the Voltage. - Generating X-Rays. - The Diffractometer. - Step-Scanning with Automated Diffractometers. - The Single-Crystal Monochromator. - The Detector. - Signal Processing Circuitry. - The Strip-Chart Recorder. - An Example of a Checklist for Operating XRD Equipment. - Summary. - References. - 3. X-RAY DIFFRACTION. - Scattering. - Interference. - Scattering from a Row of Atoms. - Scattering from a Three-Dimensional Array of Atoms. - Bragg's Law. - Box 3.1 Diffraction and Reflection. - The Arithmetic of Scattering. - The Summation of Scattering Amplitudes. - The Structure Factor F. - Information from Intensity. - The Reciprocal Lattice. - Real versus Idealized Peaks on XRD Tracings. - The Interference Function F: Diffraction from a Crystal. - Whose Unit Cell Has a Unitary Scattering Factor. - The Lorentz-Polarization Factors. - Putting It All Together—Building an 001 Diffraction Pattern. - Exercise: Calculation of the Intensity from d(001) for Illite. - Points to Remember. - References. - 4. STRUCTURE AND PROPERTIES: GENERAL TREATMENT. - General Structural Features. - Tetrahedral Sheets. - Octahedral Sheets. - Dioctahedral and Trioctahedral. - Joining the Sheets. - Stacking the Layers. - Properties. - Total Charge, Layer or Permanent Charge, and Variable Charge. - Electric Double Layer. - Exchangeable Ions or Cation-Exchange Capacity. - Interaction of Water with Clay Mineral Surfaces. - Interaction with Organic Compounds. - Classification. - Box 4.1 Nomenclature. - References. - 5. STRUCTURE, NOMENCLATURE, AND OCCURRENCES OF CLAY MINERALS. - The Individual Clay Minerals. - The 1:1 Layer Type. - Serpentine minerals. - Berthierine. - Odinite. - Kaolin minerals. - Box 5.1 Uses of Kaolinite. - Allophane and imogolite. - The 2:1 Layer Type, x = 0. - The 2:1 Layer Type, x ~ 1. - The trioctahedral subgroup. - The dioctahedral subgroup. - The 2:1 Layer Types with x 〈 1. - Illite. - Glauconite. - Smectite. - Box 5.2 Alteration of Ash-Fall Layers. - Vermiculite. - Chlorite. - Mixed-Layered Clay Minerals. - Mixed-layering, interlayering, and interstratification. - Illite/smectite (I/S). - Box 5.3 Reichweite or Ordering. - Models for smectite-to-illite transition. - MacEwan crystallite model. - Fundamental particle model. - Two-solid-solution model. - Chlorite/smectite (C/S). - Serpentine/chlorite. - Kaolinite/expandables (K/E). - Sepiolite and Palygorskite. - The Origin of Clay Minerals. - Summary. - Exercise: Calculating Structural Formulas. - Exercise: Making Structural Models of Layer Silicates. - References. - 6. SAMPLE PREPARATION TECHNIQUES FOR CLAY MINERALS. - Evaluating the Sample. - Disaggregating the Rock. - Separating Clay Minerals from Clastic Rocks. - Separating Clay Minerals from Carbonate Rocks. - Separating Clay Minerals from Sulfate Rocks. - Separating Clay Minerals from Unconsolidated Materials. - Box 6.1 Glacial Deposits, North American Interior. - Chemical Pretreatments. - Removal of Iron Oxides. - Removal of Organic Materials. - Saturating the Clay Minerals with Different Cations. - Particle-Size Separation. - Preparing the Oriented Clay Mineral Aggregates. - The Glass Slide Method. - The Smear Mount Method. - The Millipore® Filter Transfer Method. - The Centrifuged Porous Plate Method. - Dealing with Curlers or Peelers. - Making the Random Powder Mount. - Everyday random powder packs. - Freeze-dried random powder packs. - Ethylene Glycol Solvation. - Final Note. - References. - IDENTIFICATION OF CLAY MINERALS AND ASSOCIATED MINERALS. - Clay Mineral Identification—General Principles. - Illite and Glauconite. - Chlorite and Kaolinite. - Vermiculite. - Smectite. - Sepiolite, Palygorskite, and Halloysite. - 060 Reflections. - The Use of hkl Reflections for the Determination of Polytypes. - Chlorite Polytypes. - The Kaolin Polytypes. - The Micas, Illite, and Glauconite. - Nonclay Minerals. - Silica Minerals. - Feldspar. - Zeolites. - Carbonates. - Apatite, Pyrite, and Jarosite. - Gypsum, Anhydrite, Celestite, and Barite. - Lepidocrocite, Goethite, Gibbsite, and Anatase. - Summary. - References. - 8. IDENTIFICATION OF MIXED-LAYERED CLAY MINERALS. - Méring's Principles and Mixed-Layered Nomenclature. - The Q Rule, a Broadening Descriptor. - Mixed-Layered Clay Minerals. - Illite/Smectite. - Chlorite/Smectite and Chlorite/Vermiculite. - Kaolinite/Smectite. - Serpentine/Chlorite. - Mica/Vermiculite. - Summary. - References. - 9. QUANTITATIVE ANALYSIS. - Required Sample Characteristics. - Sample Length. - Sample Thickness. - Sample Position. - Homogeneity of the Sample. - Equations for Quantitative Analysis. - Basic Quantitative Diffraction Equation. - Derivation of a Working Form of the Equation for Analysis. - The Method of the Orienting Internal Standard. - Mineral Reference Intensities. - General Comments. - Calculated Mineral Reference Intensities. - Practical Examples of the Application of Reference. - Intensities. - Measurement of Peak Intensity. - Comments and Summary. - References. - 10. DISORDER IN SMECTITE, ILLITE/SMECTITE, AND ILLITE. - Small Crystals in Reciprocal Space. - Turbostratic Disorder. - Theory. - Smectite. - Illite/Smectite. - Rotational Disorder in Illite and Illite/Smectite. - Cis-Vacant Elite and Interstratified Cis- and Trans-Vacant. - Illite/Smectite. - Conclusions. - References. - APPENDIX: MODELING ONE-DIMENSIONAL X-RAY PATTERNS. - The Input Variables. - Simulating the Instrument. - Describing the Clay Mineral. - Theory. - Structures of the Component Layers. - Advanced Techniques. - Pure Minerals. - Compositional Superstructures. - Layer Types Not Specifically Included. - Atom Types Not Incorporated in the Model. - Defect Broadening. - References. - INDEX.