ALBERT

Note: Contents 1 Introduction References Part I Molecular Stress Physiology 2 General Themes of Molecular Stress Physiology 2.1 Definitions and Concepts 2.1.1 Stress 2.1.2 Quantification of Stress 2.1.3 Escape–Resistance–Avoidance–Tolerance 2.1.4 Stress Responses–Acclimation–Adaptation 2.1.5 Filters Determining Species Distribution 2.2 Activation of Stress Tolerance and Avoidance Mechanisms 2.2.1 Stress Sensing and Signal Transduction 2.2.2 Transcriptional Control 2.2.3 Oxidative Stress 2.2.4 Long-Distance Stress Signalling 2.2.5 The Model System Arabidopsis thaliana 2.3 Stress and Growth Regulation 2.4 Molecular Basis of Escape and Anticipation of Stress 2.4.1 Circadian Rhythms 2.4.2 Anticipation of Seasonal Changes in Environmental Conditions 2.4.3 Developmental Switches Triggered by Favourable Conditions 2.4.4 Trans-Generational Stress Memory Summary References 3 Light 3.1 The Dual Significance of Light 3.2 Visible Light 3.2.1 Avoidance of Light Stress and Permanent or Dynamic Acclimation 3.2.2 Overexcitation and Damage to Photosynthetic Membranes. 3.2.3 Flexible Acclimation to Changes in Light Intensity 3.2.4 Continuous Light 3.2.5 Light Triggers Plant Adaptation and Acclimation to the Environment 3.3 UV-B Radiation 3.3.1 Ranges of Ultraviolet Radiation and Biological Activity 3.3.2 Ultraviolet-B Damage and Repair Mechanisms 3.3.3 Avoidance of Ultraviolet-B-Induced Stress 3.3.4 Ultraviolet-B Perception and Signalling 3.3.5 Crosstalk Between Ultraviolet-B and Visible Light Responses Summary References 4 Temperature 4.1 The Temperature Challenge 4.1.1 Temperature Dependence of Life 4.1.2 Plants as Poikilothermic Organisms 4.1.3 Variations in Temperature Range 4.1.4 Strategies to Cope with Temperature Fluctuations and Temperature Extremes 4.2 Cold Acclimation and Freezing Tolerance 4.2.1 Adjustment of Membrane Fluidity 4.2.2 Prevention of Photoinhibition 4.2.3 Cryoprotective Proteins 4.2.4 Control of Ice Formation 4.2.5 Signalling Networks Involved in Cold Acclimation 4.2.6 Freezing Avoidance and Freezing Tolerance in Tropical High Mountain Plants 4.3 Heat Stress 4.3.1 Heat Stress Avoidance 4.3.2 Acquired Thermotolerance 4.3.3 The Heat Shock Response 4.4 Temperature Sensing 4.4.1 Sensing of Extreme Temperatures 4.4.2 Sensing of Ambient Temperature Changes Summary References 5 Oxygen Deficiency 5.1 Conditions of Flooded Soil 5.2 Hypoxia-Induced Damage: Energy Metabolism of Plants Under Oxygen Deficiency 5.3 Natural Variation in the Ability to Endure Inundation by Water 5.4 Adaptations to Flooding-Prone Habitats 5.4.1 Anatomical–Morphological Adaptations and Modifications 5.4.2 Biochemical Modifications 5.5 Sensing of Flooding and Ensuing Signal Transduction 5.5.1 Ethylene Signal Transduction 5.5.2 Oxygen Sensing 5.6 Regulation of Avoidance and Tolerance Strategies Summary References 6 Water Deficiency (Drought) 6.1 The Properties of Water 6.2 Water Acquisition and Movement: Cellular Aspects 6.2.1 The Water Potential 6.2.2 Facilitation of Intercellular and Intracellular Water Flow: Aquaporins 6.3 Drought Stress Responses: Avoidance and Tolerance 6.3.1 Control of the Osmotic Potential 6.3.2 Protective Proteins 6.3.3 Regulation of the Stomatal Aperture 6.4 Acclimation of Growth 6.4.1 Inhibition of Shoot Growth 6.4.2 Stimulation of Root Growth 6.5 Sensing of Water Status and Signal Transduction 6.5.1 Sensing of Water Status 6.5.2 ABA Signal Transduction 6.5.3 ABA-Independent Signalling 6.6 Photosynthesis Variants with Improved Water Use Efficiency 6.6.1 C4 Photosynthesis 6.6.2 Evolution of C 4 Photosynthesis 6.6.3 Crassulacean Acid Metabolism 6.6.4 Evolution of Crassulacean Acid Metabolism Photosynthesis Summary References 7 Adverse Soil Mineral Availability 7.1 Mineral Nutrients 7.2 The Mineral Nutrition Challenge 7.2.1 Elements in the Soil 7.2.2 Element Toxicity 7.3 Nutrient Acquisition and Responses to Nutrient Scarcity 7.3.1 Modulation of Nutrient Availability 7.3.2 Cellular Ion Transport Mechanisms 7.3.3 Modulation of Nutrient Uptake in Response to Deficiency 7.3.4 Intracellular Transport and Cellular Aspects of Long-Distance Transport 7.3.5 Plasticity of Root Architecture and Responses to Nutrient Deficiency 7.3.6 Sensing of Nutrient Availability and Nutrient Status . 7.4 Nutrient Acquisition Symbioses 7.4.1 Mycorrhizae 7.4.2 Nitrogen Fixation 7.4.3 The Common Sym Pathway 7.5 Responses to Element Toxicity and Tolerance Mechanisms 7.5.1 Essential Metal Toxicity and Tolerance 7.5.2 Metal Hyperaccumulators as Models for Adaptation to Extreme Environments 7.5.3 Sodium Toxicity 7.5.4 Aluminium Toxicity and Tolerance 7.5.5 Non-Essential Toxic Metals Summary References 8 Biotic Stress 8.1 Plant Disease Caused by Pathogens 8.1.1 Types of Pathogens: Viruses, Bacteria, Fungi, Oomycetes and Nematodes 8.1.2 Pathogenicity Mechanisms 8.2 Plant Defences Against Microbial Pathogens and Viruses 8.2.1 Preformed Defences Against Bacteria, Fungi and Oomycetes 8.2.2 Inducible Local Defences 8.2.3 Inducible Systemic Resistance 8.2.4 Defence Against Viruses via Gene Silencing 8.3 Herbivory 8.3.1 Constitutive Defences 8.3.2 Inducible Defences Against Herbivores 8.3.3 How Plant–Herbivore Interactions Drive Genetic Diversity 8.4 Parasitic Plants 8.5 Allelopathy Summary References Part II Physiological and Biophysical Plant Ecology 9 Thermal Balance of Plants and Plant Communities 9.1 Energy Balance of the Atmospheric Boundary Layer 9.2 Microclimate Near the Ground Surface 9.2.1 Daily Changes in Temperature Near the Ground 9.2.2 Modification of Environmental Radiation and Temperature by Abiotic Factors 9.2.3 Modification of the Radiation Budget and Temperature by Biotic Factors 9.3 Energy Balance of Leaves 9.4 Acclimation and Adaptation to Temperature Extremes 9.4.1 Acclimation and Adaptation to High Temperatures 9.4.2 Acclimation and Adaptation to Low Temperatures Summary References 10 Water Relations 10.1 Water as an Environmental Factor 10.1.1 Water Use by Plants and Animals 10.1.2 Availability of Water on Earth 10.1.3 Drivers of Water Flow Between the Soil and the Atmosphere 10.2 Water Transport from the Soil to the Plant 10.2.1 Water Uptake 10.2.2 Xylem Water Transport 10.2.3 Phloem Water Transport 10.3 Transpiration 10.3.1 Stomatal Responses to Plant-Internal Factors 10.3.2 Stomatal Responses to Environmental Factors Summary References 11 Nutrient Relations 11.1 Availability of Soil Nutrients and Ion Use 11.1.1 Plant Nutrients 11.1.2 Availability of Nutrients in Soil 11.1.3 General Aspects of Plant Nutrition 11.1.4 Nutrient Deficiency and Excess 11.2 Nitrogen Nutrition 11.2.1 Nitrogen in Plant Metabolism 11.2.2 Nitrogen Uptake and Nutrition 11.2.3 Nitrogen Requirements for Growth 11.2.4 Nitrogen Storage 11.2.5 Insectivorous Plants 11.2.6 Nitrogen Deficiency and Excess 11.3 Sulphur Nutrition 11.3.1 Sulphur in Plant Metabolism 11.3.2 Sulphur Uptake and Plant Requirements 11.3.3 Indicators of Sulphur Deficiency and Excess 11.4 Phosphate Nutrition 11.4.1 Phosphorus in Plant Metabolism 11.4.2 Phosphate Uptake and Plant Requirements 11.4.3 Indicators of Phosphorus Deficiency and Excess 11.5 Alkaline Cation Nutrition 11.5.1 Magnesium 11.5.2 Calcium 11.5.3 Potassium Summary References 12 Carbon Relations 12.1 Photosynthetic CO2 Uptake: Physiological and Physical Basis 12.1.1 Photosynthesis as a Diffusion Process 12.1.2 Evolution of C 3, C4 and Crassulacean Acid Metabolism Plant Species 12.2 Photosynthesis Models and Calculation of 13C/12C Fluxes (Contribution by A. Arneth) 12.2.1 RubisCO-Limited or RuBP-Saturated Rate (Av) 12.2.2 RuBP Regeneration–Dependent and Electron Transport–Limiting Rate (Aj) 12.2.3 Supply of CO 2 Through Stomata 12.2.4 13C/12C Discrimination 12.3 Specific Leaf Area, Nitrogen Concentrations and Photosynthetic Capacity 12.3.1 Specific Leaf Area 12.3.2 Maximum Rates of CO2 Assimilation 12.4 Response of Photosynthesis to Environmental Variables 12.4.1 Light Response of CO 2 Assimilation 12.4.2 Temperature Response of CO2 Assimilation 12.4.3 Relative Air Humidi

Note: Contents: Introduction ; Part 1: European Cities in Global Competition ; 1 Dynamic Competition in Space: Theoretical Models, Empirical Evidence, Political Challenges ; 2 Increasing the Innovative Capacity of European Cities: Making Use of Proven Concepts from the National Level ; Part 2: City Management and Direct Democracy ; 3 Open Government: Exploring Patterns of Mobile Interaction Between Citizens and Local Government ; 4 Building the Smart City: Leipzig ; 5 Location Communication in Leipzig and Thoughts About Destination Management ; Part 3: Success Factors in Global Competition Among Cities ; 6 Key Factors for Successful City Marketing: An Example from Münster ; 7 Strategies for Cities in Global Competition: An Essay on Spatial Economics and Management Science ; Part 4: Complementarity Between Region and City ; 8 The Significance of the Region for Urban Growth: The Example of Bonn and the Rhein-Sieg District ; 9 The Digital City: Using the Example of “Mönchengladbach on eBay” ; Part 5: Cost Efficiency in City Management ; 10 A Mechanism Design Approach to Planning Problems in Intermodal Transport Logistics of Large City Sea Ports and Megahubs

Note: Contents 1 An Observational Overview of the Equatorial Ocean 1.1 The Thermocline: The Tropical Ocean as a Two-Layer Model 1.2 Equatorial Currents 1.3 The Somali Current and the Monsoon 1.4 Deep Internal Jets 1.5 The El Niño/Southern Oscillation (ENSO) 1.6 Upwelling in the Gulf of Guinea 1.7 Seasonal Variations of the Thermocline 1.8 Summary References 2 Basic Equations and Normal Modes 2.1 Model 2.2 Boundary Conditions 2.3 Separation of Variables 2.4 Lamb’s Parameter, Equivalent Depths, Kelvin Phase Speeds and All that 2.5 Vertical Modes and Layer Models 2.6 Nondimensionalization References 3 Kelvin, Yanai, Rossby and Gravity Waves 3.1 Latitudinal Wave Modes: An Overview 3.2 Latitudinal Wave Modes: Structure and Spatial Symmetries 3.3 Dispersion Relations: Exact and Approximate Frequencies 3.4 Analytic Approximations to Equatorial Wave Frequencies 3.4.1 Explicit Formulas 3.4.2 Long Wave Series 3.5 Separation of Time Scales 3.6 Forced Waves 3.7 How the Mixed-Rossby Gravity Wave Earned Its Name 3.8 Hough-Hermite Vector Basis 3.8.1 Introduction 3.8.2 Inner Product and Orthogonality 3.8.3 Orthonormal Basis Functions 3.9 Applications of the Hough-Hermite Basis: Linear Initial-Value Problems 3.10 Initialization Through Hough-Hermite Expansion 3.11 Energy Relationships 3.12 The Equatorial Beta-Plane as the Thin Limit of the Nonlinear Shallow Water Equations on the Sphere References 4 The “Long Wave” Approximation & Geostrophy 4.1 Introduction 4.2 Quasi-Geostrophy 4.3 The “Meridional Geostrophy”, “Low Frequency” or “Long Wave” Approximation 4.4 Boundary Conditions 4.5 Frequency Separation of Slow [Rossby/Kelvin] and Fast [Gravity] Waves 4.6 Initial Value Problems in an Unbounded Ocean, Linearized About a State of Rest, in the Long Wave Approximation 4.7 Reflection from an Eastern Boundary in the Long Wave Approximation 4.7.1 The Method of Images 4.7.2 Dilated Images 4.7.3 Zonal Velocity 4.8 Forced Problems in the Long Wave Approximation References 5 The Equator as Wall: Coastally Trapped Waves and Ray-Tracing 5.1 Introduction 5.2 Coastally-Trapped Waves 5.3 Ray-Tracing For Coastal Waves 5.4 Ray-Tracing on the Equatorial Beta-Plane 5.5 Coastal and Equatorial Kelvin Waves 5.6 Topographic and Rotational Rossby Waves and Potential Vorticity References 6 Reflections and Boundaries 6.1 Introduction 6.2 Reflection of Midlatitude Rossby Waves from a Zonal Boundary 6.3 Reflection of Equatorial Waves from a Western Boundary 6.4 Reflection from an Eastern Boundary 6.5 The Meridional Geostrophy/Long Wave Approximation and Boundaries 6.6 Quasi-normal Modes: Definition and Other Weakly Non-existent Phenomena 6.7 Quasi-normal Modes in the Long Wave Approximation: Derivation 6.8 Quasi-normal Modes in the Long Wave Approximation: Discussion 6.9 High Frequency Quasi-free Equatorial Oscillations 6.10 Scattering and Reflection from Islands References 7 Response of the Equatorial Ocean to Periodic Forcing 7.1 Introduction 7.2 A Hierarchy of Models for Time-Periodic Forcing 7.3 Description of the Model and the Problem 7.4 Numerical Models: Reflections and “Ringing” 7.5 Atlantic Versus Pacific 7.6 Summary References 8 Impulsive Forcing and Spin-Up 8.1 Introduction 8.2 The Reflection of the Switched-On Kelvin Wave 8.3 Spin-Up of a Zonally-Bounded Ocean: Overview 8.4 The Interior (Yoshida) Solution 8.5 Inertial-Gravity Waves 8.6 Western Boundary Response 8.7 Sverdrup Flow on the Equatorial Beta-Plane 8.8 Spin-Up: General Considerations 8.9 Equatorial Spin-Up: Details 8.10 Equatorial Spin-Up: Summary References 9 Yoshida Jet and Theories of the Undercurrent 9.1 Introduction 9.2 Wind-Driven Circulation in an Unbounded Ocean: f-Plane 9.3 The Yoshida Jet 9.4 An Interlude: Solving Inhomogeneous Differential Equations at Low Latitudes 9.4.1 Forced Eigenoperators: Hermite Series 9.4.2 Hutton–Euler Acceleration of Slowly Converging Hermite Series 9.4.3 Regularized Forcing 9.4.4 Bessel Function Explicit Solution for the Yoshida Jet 9.4.5 Rational Approximations: Two-Point Padé Approximants and Rational Chebyshev Galerkin Methods 9.5 Unstratified Models of the Undercurrent 9.5.1 Theory of Fofonoff and Montgomery (1955) 9.5.2 Model of Stommel (1960) 9.5.3 Gill (1971) and Hidaka (1961) References 10 Stratified Models of Mean Currents 10.1 Introduction 10.2 Modal Decompositions for Linear, Stratified Flow 10.3 Different Balances of Forces 10.3.1 Bjerknes Balance 10.4 Forced Baroclinic Flow in the “Bjerknes” Approximation 10.4.1 Other Balances 10.5 The Sensitivity of the Undercurrent to Parameters 10.6 Observations of Subsurface Countercurrents (Tsuchiya Jets) 10.7 Alternate Methods for Vertical Structure with Viscosity 10.8 McPhaden’s Model of the EUC and SSCC’s: Results 10.9 A Critique of Linear Models of the Continuously-Stratified, Wind-Driven Ocean References 11 Waves and Beams in the Continuously Stratified Ocean 11.1 Introduction 11.1.1 Equatorial Beams: A Theoretical Inevitability 11.1.2 Slinky Physics and Impedance Mismatch, or How Water Can Be as Reflective as Silvered Glass 11.1.3 Shallow Barriers to Downward Beams 11.1.4 Equatorial Methodology 11.2 Alternate Form of the Vertical Structure Equation 11.3 The Thermocline as a Mirror 11.4 The Mirror-Thermocline Concept: A Critique 11.5 The Zonal Wavenumber Condition for Strong Excitation of a Mode 11.6 Kelvin Beams: Background 11.7 Equatorial Kelvin Beams: Results References 12 Stable Linearized Waves in a Shear Flow 12.1 Introduction 12.2 UðyÞ: Pure Latitudinal Shear 12.3 Neutral Waves in Flow Varying with Both Latitude and Height: Numerical Studies 12.4 Vertical Shear and the Method of Multiple Scales References 13 Inertial Instability, Pancakes and Deep Internal Jets 13.1 Introduction: Stratospheric Pancakes and Equatorial Deep Jets 13.2 Particle Argument 13.2.1 Linear Inertial Instability 13.3 Centrifugal Instability: Rayleigh’s Parcel Argument 13.4 Equatorial Gamma-Plane Approximation 13.5 Dynamical Equator 13.6 Gamma-Plane Instability 13.7 Mixed Kelvin-Inertial Instability 13.8 Summary References 14 Kelvin Wave Instability: Critical Latitudes and Exponentially Small Effects 14.1 Proxies and the Optical Theorem 14.2 Six Ways to Calculate Kelvin Instability 14.2.1 Power Series for the Eigenvalue 14.2.2 Hermite-Padé Approximants 14.2.3 Numerical Methods 14.3 Instability for the Equatorial Kelvin Wave in the Small Wavenumber Limit 14.3.1 Beyond-All-Orders Rossby Wave Instability 14.3.2 Beyond-All-Orders Kelvin Wave Instability in Weak Shear in the Long Wave Approximation 14.4 Kelvin Instability in Shear: The General Case References 15 Nonmodal Instability 15.1 Introduction 15.2 Couette and Poiseuille Flow and Subcritical Bifurcation 15.3 The Fundamental Orr Solution 15.4 Interpretation: The “Venetian Blind Effect” 15.5 Refinements to the Orr Solution 15.6 The “Checkerboard” and Bessel Solution 15.6.1 The “Checkerboard” Solution 15.7 The Dandelion Strategy 15.8 Three-Dimensional Transients 15.9 ODE Models and Nonnormal Matrices 15.10 Nonmodal Instability in the Tropics 15.11 Summary References 16 Nonlinear Equatorial Waves 16.1 Introduction 16.2 Weakly Nonlinear Multiple Scale Perturbation Theory 16.2.1 Reduction from Three Space Dimensions to One 16.2.2 Three Dimensions and Baroclinic Modes 16.3 Solitary and Cnoidal Waves 16.4 Dispersion and Waves 16.4.1 Derivation of the Group Velocity Through the Method of Multiple Scales 16.5 Integrability, Chaos and the Inverse Scattering Method 16.6 Low Order Spectral Truncation (LOST) 16.7 Nonlinear Equatorial Kelvin Waves 16.7.1 Physics of the One-Dimensional Advection (ODA) Equation: ut + cux + buux = 0 16.7.2 Post-Breaking: Overturning, Taylor Shock or “Soliton Clusters”? 16.7.3 Viscous Regularization of Kelvin Fronts: Burgers’ Equation And Matched Asymptotic Perturbation Theory 16.8 Kelvin-Gravity Wave Shortwave Resonance: Curving Fronts and Undulations 16.9 Kelvin Solitary and Cnoidal Waves 16.10 Corner Waves and the Cnoidal-Corner-Breaking Scenario 16.11 Rossby Solitary Waves 16.12 Antisymmetr

Note: Contents: Einleitung - um was geht es in diesem Buch?- Erster Teil: Energiewende - was steckt dahinter?- Drei Ziele der Energiewende - Beschreibung. Drei Ziele der Energiewende - Analyse. Vier Motive der Energiewende - Beschreibung. Vier Motive der Energiewende - Analyse. Rahmenbedingungen der Energiewende - Beschreibung. Rahmenbedingungen der Energiewende - Analyse. Systemische Folgen - Beschreibung -- Zweiter Teil: Energie-Wende - Wo stehen wir heute?- Einführung. Status quo 2015 - Ziele. Status quo 2015 - Motive. Status quo 2015 - Rahmenbedingungen. Status quo 2015 - Systemische Folgen. Zusammenfassung -- Dritter Teil: Energiewende - was kostet sie wirklich?- Einführung. Phase 1 der Energiewende (2000-2014). Phase 2 der Energiewende (2015-2030). Phase 3 der Energiewende (2030-2050). Zusammenfassung -- Vierter Teil: Energiewende - Bequeme und unbequeme Wahrheiten -- 10 Antworten

Note: Contents: 1 Computing with Formulas. - 1.1 The First Programming Encounter: a Formula. - 1.1.1 Using a Program as a Calculator. - 1.1.2 About Programs and Programming. - 1.1.3 Tools for Writing Programs. - 1.1.4 Writing and Running Your First Python Program. - 1.1.5 Warning About Typing Program Text. - 1.1.6 Verifying the Result. - 1.1.7 Using Variables. - 1.1.8 Names of Variables. - 1.1.9 Reserved Words in Python. - 1.1.10 Comments. - 1.1.11 Formatting Text and Numbers. - 1.2 Computer Science Glossary. - 1.3 Another Formula: Celsius-Fahrenheit Conversion. - 1.3.1 Potential Error: Integer Division. - 1.3.2 Objects in Python. - 1.3.3 Avoiding Integer Division. - 1.3.4 Arithmetic Operators and Precedence. - 1.4 Evaluating Standard Mathematical Functions. - 1.4.1 Example: Using the Square Root Function. - 1.4.2 Example: Computing with sinh x. - 1.4.3 A First Glimpse of Rounding Errors. - 1.5 Interactive Computing. - 1.5.1 Using the Python Shell. - 1.5.2 Type Conversion. - 1.5.3 IPython. - 1.6 Complex Numbers. - 1.6.1 Complex Arithmetics in Python. - 1.6.2 Complex Functions in Python. - 1.6.3 Unified Treatment of Complex and Real Functions. - 1.7 Symbolic Computing. - 1.7.1 Basic Differentiation and Integration. - 1.7.2 Equation Solving. - 1.7.3 Taylor Series and More. - 1.8 Summary. - 1.8.1 Chapter Topics. - 1.8.2 Example: Trajectory of a Ball. - 1.8.3 About Typesetting Conventions in This Book. - 1.9 Exercises. - 2 Loops and Lists. - 2.1 While Loops. - 2.1.1 A Naive Solution. - 2.1.2 While Loops. - 2.1.3 Boolean Expressions. - 2.1.4 Loop Implementation of a Sum. - 2.2 Lists. - 2.2.1 Basic List Operations. - 2.2.2 For Loops. - 2.3 Alternative Implementations with Lists and Loops. - 2.3.1 While Loop Implementation of a for Loop. - 2.3.2 The Range Construction. - 2.3.3 For Loops with List Indices. - 2.3.4 Changing List Elements. - 2.3.5 List Comprehension. - 2.3.6 Traversing Multiple Lists Simultaneously. - 2.4 Nested Lists. - 2.4.1 A table as a List of Rows or Columns. - 2.4.2 Printing Objects. - 2.4.3 Extracting Sublists. - 2.4.4 Traversing Nested Lists. - 2.5 Tuples. - 2.6 Summary. - 2.6.1 Chapter Topics. - 2.6.2 Example: Analyzing List Data. - 2.6.3 How to Find More Python Information. - 2.7 Exercises. - 3 Functions and Branching. - 3.1 Functions. - 3.1.1 Mathematical Functions as Python Functions. - 3.1.2 Understanding the Program Flow. - 3.1.3 Local and Global Variables. - 3.1.4 Multiple Arguments. - 3.1.5 Function Argument or Global Variable?. - 3.1.6 Beyond Mathematical Functions. - 3.1.7 Multiple Return Values. - 3.1.8 Computing Sums. - 3.1.9 Functions with No Return Values. - 3.1.10 Keyword Arguments. - 3.1.11 Doc Strings. - 3.1.12 Functions as Arguments to Functions. - 3.1.13 The Main Program. - 3.1.14 Lambda Functions. - 3.2 Branching. - 3.2.1 If-else Blocks. - 3.2.2 Inline if Tests. - 3.3 Mixing Loops, Branching, and Functions in Bioinformatics Examples. - 3.3.1 Counting Letters in DNA Strings. - 3.3.2 Efficiency Assessment. - 3.3.3 Verifying the Implementations. - 3.4 Summary. - 3.4.1 Chapter Topics. - 3.4.2 Example: Numerical Integration. - 3.5 Exercises. - 4 User Input and Error Handling. - 4.1 Asking Questions and Reading Answers. - 4.1.1 Reading Keyboard Input. - 4.2 Reading from the Command Line. - 4.2.1 Providing Input on the Command Line. - 4.2.2 A Variable Number of Command-Line Arguments. - 4.2.3 More on Command-Line Arguments. - 4.3 Turning User Text into Live Objects. - 4.3.1 The Magic Eval Function. - 4.3.2 The Magic Exec Function. - 4.3.3 Turning String Expressions into Functions. - 4.4 Option-Value Pairs on the Command Line. - 4.4.1 Basic Usage of the Argparse Module. - 4.4.2 Mathematical Expressions as Values. - 4.5 Reading Data from File. - 4.5.1 Reading a File Line by Line. - 4.5.2 Alternative Ways of Reading a File. - 4.5.3 Reading a Mixture of Text and Numbers. - 4.6 Writing Data to File. - 4.6.1 Example: Writing a Table to File. - 4.6.2 Standard Input and Output as File Objects. - 4.6.3 What is a File, Really?. - 4.7 Handling Errors. - 4.7.1 Exception Handling. - 4.7.2 Raising Exceptions. - 4.8 A Glimpse of Graphical User Interfaces. - 4.9 Making Modules. - 4.9.1 Example: Interest on Bank Deposits. - 4.9.2 Collecting Functions in a Module File. - 4.9.3 Test Block. - 4.9.4 Verification of the Module Code. - 4.9.5 Getting Input Data. - 4.9.6 Doc Strings in Modules. - 4.9.7 Using Modules. - 4.9.8 Distributing Modules. - 4.9.9 Making Software Available on the Internet. - 4.10 Making Code for Python 2 and 3. - 4.10.1 Basic Differences Between Python 2 and 3. - 4.10.2 Turning Python 2 Code into Python 3 Code. - 4.11 Summary. - 4.11.1 Chapter Topics. - 4.11.2 Example: Bisection Root Finding. - 4.12 Exercises. - 5 Array Computing and Curve Plotting. - 5.1 Vectors. - 5.1.1 The Vector Concept. - 5.1.2 Mathematical Operations on Vectors. - 5.1.3 Vector Arithmetics and Vector Functions. - 5.2 Arrays in Python Programs. - 5.2.1 Using Lists for Collecting Function Data. - 5.2.2 Basics of Numerical Python Arrays. - 5.2.3 Computing Coordinates and Function Values. - 5.2.4 Vectorization. - 5.3 Curve Plotting. - 5.3.1 MATLAB-Style Plotting with Matplotlib. - 5.3.2 Matplotlib; Pyplot Prefix. - 5.3.3 SciTools and Easyviz. - 5.3.4 Making Animations. - 5.3.5 Making Videos. - 5.3.6 Curve Plots in Pure Text. - 5.4 Plotting Difficulties. - 5.4.1 Piecewisely Defined Functions. - 5.4.2 Rapidly Varying Functions. - 5.5 More Advanced Vectorization of Functions. - 5.5.1 Vectorization of StringFunction Objects. - 5.5.2 Vectorization of the Heaviside Function. - 5.5.3 Vectorization of a Hat Function. - 5.6 More on Numerical Python Arrays. - 5.6.1 Copying Arrays. - 5.6.2 In-Place Arithmetics. - 5.6.3 Allocating Arrays. - 5.6.4 Generalized Indexing. - 5.6.5 Testing for the Array Type. - 5.6.6 Compact Syntax for Array Generation. - 5.6.7 Shape Manipulation. - 5.7 High-Performance Computing with Arrays. - 5.7.1 Scalar Implementation. - 5.7.2 Vectorized Implementation. - 5.7.3 Memory-Saving Implementation. - 5.7.4 Analysis of Memory Usage. - 5.7.5 Analysis of the CPU Time. - 5.8 Higher-Dimensional Arrays. - 5.8.1 Matrices and Arrays. - 5.8.2 Two-Dimensional Numerical Python Arrays. - 5.8.3 Array Computing. - 5.8.4 Matrix Objects. - 5.9 Some Common Linear Algebra Operations. - 5.9.1 Inverse, Determinant, and Eigenvalues. - 5.9.2 Products. - 5.9.3 Norms. - 5.9.4 Sum and Extreme Values. - 5.9.5 Indexing. - 5.9.6 Transpose and Upper/Lower Triangular Parts. - 5.9.7 Solving Linear Systems. - 5.9.8 Matrix Row and Column Operations. - 5.9.9 Computing the Rank of a Matrix. - 5.9.10 Symbolic Linear Algebra. - 5.10 Plotting of Scalar and Vector Fields. - 5.10.1 Installation. - 5.10.2 Surface Plots. - 5.10.3 Parameterized Curve. - 5.10.4 Contour Lines. - 5.10.5 The Gradient Vector Field. - 5.11 Matplotlib. - 5.11.1 Surface Plots. - 5.11.2 Contour Plots. - 5.11.3 Vector Field Plots. - 5.12 Mayavi. - 5.12.1 Surface Plots. - 5.12.2 Contour Plots. - 5.12.3 Vector Field Plots. - 5.12.4 A 3D Scalar Field and Its Gradient Field. - 5.12.5 Animations. - 5.13 Summary. - 5.13.1 Chapter Topics. - 5.13.2 Example: Animating a Function. - 5.14 Exercises. - 6 Dictionaries and Strings. - 6.1 Dictionaries. - 6.1.1 Making Dictionaries. - 6.1.2 Dictionary Operations. - 6.1.3 Example: Polynomials as Dictionaries. - 6.1.4 Dictionaries with Default Values and Ordering. - 6.1.5 Example: Storing File Data in Dictionaries. - 6.1.6 Example: Storing File Data in Nested Dictionaries. - 6.1.7 Example: Reading and Plotting Data Recorded at Specific Dates. - 6.2 Strings. - 6.2.1 Common Operations on Strings. - 6.2.2 Example: Reading Pairs of Numbers. - 6.2.3 Example: Reading Coordinates. - 6.3 Reading Data fromWeb Pages. - 6.3.1 About Web Pages. - 6.3.2 How to Access Web Pages

Note: Introduction -- Geodetic Data Collection Techniques -- Geodetic datum and Geodetic Control Network -- Geoid and Height System -- Reference Ellipsoid and Geodetic Coordinate System -- Gauss and UTM Conformal Projection and Plane Rectangular Coordinate System -- Establishment of Geodetic Coordinate System

Note: Contents 1 Introduction 2 Basic theory of quantitative remote sensing 3 Radiometric calibration in thermal infrared 4. Retrieval of land surface emissivity from remotely sensed data 5. Land surface temperature retrieval from thermal infrared data 6. Estimation and validation of evapotranspiration from thermal infrared remote sensing data 7. Application of thermal remote sensing in agriculture drought monitoring and thermal anomaly detection 8. Future development and perspectives Index.

Note: Contents: 1 Introduction. - 1.1 The world cold regions. - 1.2 Water in frozen soils. - 1.3 Permafrost. - 1.3.1 Definitions. - 1.3.2. Distribution. - 1.3.3. Factors influencing permafrost occurence. - 1.4 Permafrost and hydrology. - 1.4.1 Permafrost hydrology. - 1.4.2 Hydrologic behavior of seasonal frost and permafrost. - 1.5 Environments of permafrost regions. - 1.5.1 Hydroclimatology. - 1.5.2 Geology. - 1.5.3 Glaciation. - 1.5.4 Physiography. - 1.5.5 Vegetation. - 1.5.6 Peat cover. - 1.6 Presentation of the book. - 2 Moisture and heat. - 2.1 Precipitation. - 2.1.1 General pattern. - 2.1.2 Cyclones. - 2.1.3 Recycling. - 2.1.4 Trace precipitation. - 2.2 Surface energy balance. - 2.3 Evaporation. - 2.3.1 Eddy Fluctuation Method. - 2.3.2 Aerodynamic method. - 2.3.3 Bowen Ratio Method. - 2.3.4 Priestley and Taylor Method. - 2.4 Energy balance of the active layer. - 2.4.1 Energy Balance. - 2.4.2 Thermal conductivity and heat capacity. - 2.5 Ground temperature. - 2.5.1 Penetration of temperature waves. - 2.5.2 Frost table development. - 2.6 Heat and moisture flows in frozen soils. - 2.6.1 Stefan's Algorithm. - 2.6.2 Near-Surface ground temperature. - 2.6.3 Moisture migration and ice lens formation. - 2.7 Ground ice. - 2.7.1 Types of ground ice. - 2.7.2 Excess ice. - 3 Groundwater. - 3.1 Groundwater occurence in permafrost. - 3.1.1 Suprapermafrost groundwater. - 3.1.2 Intrapermafrost groundwater. - 3.1.3 Subpermafrost groundwater. - 3.2 Groundwater recharge and circulation. - 3.2.1 Recharge. - 3.2.2 Groundwater movement. - 3.3 Groundwater discharge. - 3.3.1 Seeps. - 3.3.2 Springs. - 3.3.3 Baseflow. - 3.3.4 Ponds and lakes. - 3.4 Icings. - 3.4.1 Ground and spring icings. - 3.4.2 River icings. - 3.4.3 Icing dimension. - 3.4.4 Icing problems. - 3.5 Domed ice features. - 3.5.1 Frost mounds and icing mounds. - 3.5.2 Pingos. - References. - 4 Snow cover. - 4.1 Snow accumulation. - 4.1.1 Winter precipitation. - 4.1.2 Blowing snow. - 4.1.3 Terrain heterogeneity. - 4.1.4 Vegetation cover. - 4.2 Characteristics of the snow cover. - 4.2.1 Snow temperature and insulation. - 4.2.2 Snow metamorphism. - 4.2.3 Snow stratigraphy. - 4.3 Snowmelt processes. - 4.3.1 Radiation melt. - 4.3.2 Turbulent fluxes melt. - 4.3.3 Other melt terms. - 4.4 Snowmelt in permafrost areas. - 4.4.1 Tundra and Barren areas. - 4.4.2 Dirty snow. - 4.4.3 Shrub fields. - 4.4.4 Forests. - 4.5 Meltwater movement in snow. - 4.5.1 Dry snow. - 4.5.2 Wet snow. - References. - 5 Active layer dynamics. - 5.1 Freeze-back and winter periods. - 5.1.1 Snow cover and ground freezing. - 5.1.2 Moisture flux and ice formation. - 5.1.3 Vapor flux from soil to snow. - 5.2 Snowmelt period. - 5.2.1 Snowmelt and basal ice. - 5.2.2 Infiltration into frozen soil. - 5.2.3 Soil warming. - 5.2.4 Surface saturation, evaporation and runoff. - 5.3 Summer. - 5.3.1 Active layer thaw. - 5.3.2 Summer precipitation. - 5.3.3 Evaporation. - 5.3.4 Rainwater infiltration. - 5.3.5 Soil moisture. - 5.3.6 Groundwater. - References. - 6 Slope processes. - 6.1 Flow paths. - 6.1.1 Flow paths in snow. - 6.1.2 Surface and subsurface flows. - 6.1.3 Flow in bedrock areas. - 6.1.4 Flow in unconsolidated materials. - 6.2 Water sources. - 6.3 Factors influencing slope runoff generation. - 6.3.1 Microclimatic control. - 6.3.2 Topographic influence. - 6.3.3 Importance of the Frost table. - 6.3.4 Roles of organic materials. - 6.3.5 Bedrock control. - 6.4 Basin slopes in permafrost regions. - 6.4.1 High Arctic slopes. - 6.4.2 Low Arctic slopes. - 6.4.3 Subarctic slopes. - 6.4.4 Alpine permafrost zones. - 6.4.5 Precambrian bedrock terrain. - 6.5 Concepts for basin flow generation. - 6.5.1 Variable source area and fill-and-spill concepts. - 6.5.2 Heterogenous slopes. - References. - 7 Cold lakes. - 7.1 Types of lake. - 7.2 Lake ice. - 7.2.1 Lake ice regime. - 7.2.2 Ice formation and growth. - 7.2.3 Ice decay. - 7.3 Lake circulation. - 7.4 Hydrologic inputs. - 7.5 Lake evaporation. - 7.6 Lake outflow. - 7.6.1 Outflow conditions. - 7.6.2 Fill-and-Spill concept and lake outflow. - 7.7 Lake level. - 7.8 Large lakes. - 7.9 Permafrost and lakes. - References. - 8 Northern wetlands. - 8.1 Wetlands in permafrost regions. - 8.2 Factors favoring wetland occurence. - 8.2.1 Climate. - 8.2.2 Topography. - 8.2.3 Stratigraphy. - 8.2.4 Other factors. - 8.3 Hydrogeomorphic features in wetlands. - 8.3.1 Bog-related features. - 8.3.2 Fen-related features. - 8.3.3 Marshes and swamps. - 8.3.4 Shallow water bodies. - 8.4 Hydrologic behavior of wetlands. - 8.4.1 Seasonality of hydrologic activities. - 8.4.2 Wetland storage. - 8.4.3 Flow paths. - 8.4.4 Application of Fill-and-Spill concept. - 8.5 Patchy arctic wetlands. - 8.5.1 Wetlands maintained by snowmelt. - 8.5.2 Groundwater-fed wetlands. - 8.5.3 Valley bottom fens. - 8.5.4 Wetlands due to lateral inundation. - 8.5.5 Tundra ponds. - 8.5.6 Lake-fed and lake-bed wetlands. - 8.6 Extensive wetlands. - 8.6.1 Wet terrain. - 8.6.2 Ice-wedge polygon fields. - 8.6.3 Coastal plains. - 8.6.4 Deltas. - 8.6.5 Subarctic continental wetlands. - 8.7 Wetlands, permafrost and disturbances. - References. - 9 Rivers in cold regions. - 9.1 Drainage patterns. - 9.2 In-valley conditions. - 9.2.1 Geological setting for channels. - 9.2.2 River ice. - 9.2.3 River icing. - 9.2.4 In-channel snow. - 9.2.5 Permafrost. - 9.2.6 Alluvial environment. - 9.3 In-channel hydrology. - 9.3.1 Lateral inflow. - 9.3.2 Channel inflow. - 9.3.3 Vertical water exchanges. - 9.3.4 Storage in channels. - 9.4 Flow connectivity and delivery. - 9.4.1 Flow network integration. - 9.4.2 Decoupling of flow network. - 9.4.3 Flow delivery. - References. - 10 Basin hydrology. - 10.1 Basin outflow generation. - 10.1.1 The roles of snow. - 10.1.2 Meltwater from glaciers. - 10.1.3 Rainfall contribution. - 10.1.4 Groundwater supply. - 10.1.5 Evaporation losses. - 10.1.6 Permafrost effects. - 10.1.7 Consequences of basin storage. - 10.2 Streamflow hydrograph. - 10.3 Streamflow regimes. - 10.3.1 Nival regime. - 10.3.2 Proglacial regime. - 10.3.3 Pluvial regime. - 10.3.4 Spring-fed Regime. - 10.3.5 Prolacustrine regime. - 10.3.6 Wetland regime. - 10.4 Streamflow in large basins. - 10.4.1 Scaling up to large rivers. - 10.4.2 Flow generation in a large basin: the Liard river. - 10.4.3 Regulated discharge of large rivers. - 10.4.4 Flow in a sub-continental scale basin: Mackenzie basin. - 10.5 Basin water balance. - 10.5.1 Considerations in water balance investigation. - 10.5.2 Regional tendencies. - 10.5.3 Examples from permafrost environments. - 10.6 Permafrost basin hydrology: general remarks. - References. - Appendices. - Index.

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: Inhalt Vorwort Einleitung / Sonja Germer, Matthias Naumann, Oliver Bens Zur gegenwärtigen Situation der Fokusregion Berlin-Brandenburg / Sonja Germer, Matthias Naumann, Oliver Bens I. Umweltwandel und die Folgen für den Landschaftswasserhaushalt Einleitung / Sonja Germer, Barbara Köstner, Herbert Sukopp, Jost Heintzenberg Temperaturaufzeichnungen in Berlin für die letzten 310 Jahre / Ulrich Cubasch, Christopher Kadow Simulation des gegenwärtigen und zukünftigen Regionalklimas von Brandenburg / Eberhard Schaller Simulation von Wasserhaushaltskomponenten unter dem Wandel des regionalen Klimas / Barbara Köstner, Matthias Kuhnert Reaktionen von Seeökosystemen auf Umweltveränderungen / Michael Hupfer, Brigitte Nixdorf, Klement Tockner Anthropogene Einflussfaktoren des Landschaftswasserhaushalts / Gunnar Lischeid Wasserhaushaltliche und wasserwirtschaftliche Bilanzen / Uwe Grünewald Kernaussagen / Barbara Köstner, Sonja Germer, Jost Heintzenberg II. Wandel von Landnutzungen und deren Konsequenzen für Wasserressourcen Einleitung / Inge Broer, Alfred Pühler, Mihaiela Rus Regionale Landwirtschaft im globalen Wandel / Konrad Hagedorn Den Rahmen setzen für die Entwicklung der Kulturlandschaften von morgen. Regionale Antworten auf globale Herausforderungen finden / Werner Konold Strategien zum Integrierten Land- und Wasserressourcenmanagement im märkischen Feuchtgebietsgürtel Oderbruch-Havelland / Joachim Quast Wassermanagement in der Landwirtschaft / Katrin Drastig, Annette Prochnow, Reiner Brunsch Waldbewirtschaftung unter den Bedingungen des Klimawandels in Brandenburg / Ralf Kätzel, Klaus Höppner Erzeugung und Verbrauch von landwirtschaftlichen Produkten aus Brandenburg in Berlin / Hans Kögl Neue Entwicklungen in der Pflanzenzüchtung und Systembetrachtungen der Pflanze-Umwelt-Interaktion / Inge Broer, Reiner Brunsch Kernaussagen / Inge Broer, Alfred Pühler, Mihaiela Rus III. Infrastrukturen neu denken: gesellschaftliche Funktionen und Weiterentwicklung / Eva Barlösius, Karl-Dieter Keim, Georg Meran, Timothy Moss, Claudia Neu Gegenwärtige Situation der Infrastrukturen Ausgangspunkt: LandInnovation Leistungen der Infrastrukturen in der Vergangenheit Wasser- und Bildungsinfrastrukturen: Gemeinsamkeiten und Unterschiede Kernaussagen über Infrastrukturen IV. Handeln unter Bedingungen des globalen Wandels / Sonja Germer, Karl-Dieter Keim, Matthias Naumann, Oliver Bens, Rolf Emmermann, Reinhard F. Hüttl Übergeordnete Herausforderungen des globalen Wandels Brückenprinzipien als Handlungsorientierung für den Umgang mit dem globalen Wandel Stärkung der interdisziplinären Forschung und des Transfers Abbildungsverzeichnis Tabellenverzeichnis Verzeichnis der Autorinnen und Autoren Verzeichnis der Mitglieder der interdisziplinären Arbeitsgruppe Globaler Wandel – Regionale Entwicklung Verzeichnis der Diskussionspapiere der interdisziplinären Arbeitsgruppe Globaler Wandel – Regionale Entwicklung