ALBERT

Note: Contents Preface Part 1 Mathematical tools M 1 Algebra of vectors M 1.1 Basic concepts and definitions M 1.2 Reference frames M 1.3 Vector multiplication M 1.4 Reciprocal coordinate systems M 1.5 Vector representations M 1.6 Products of vectors in general coordinate systems M 1.7 Problems M 2 Vector functions M 2.1 Basic definitions and operations M 2.2 Special dyadics M 2.3 Principal-axis transformation of symmetric tensors M 2.4 Invariants of a dyadic M 2.5 Tensor algebra M 2.6 Problems M 3 Differential relations M 3.1 Differentiation of extensive functions M 3.2 The Hamilton operator in generalized coordinate systems M 3.3 The spatial derivative of the basis vectors M 3.4 Differential invariants in generalized coordinate systems M 3.5 Additional applications M 3.6 Problems M 4 Coordinate transformations M 4.1 Transformation relations of time-independent coordinate systems M 4.2 Transformation relations of time-dependent coordinate systems M 4.3 Problems M 5 The method of covariant differentiation M 5.1 Spatial differentiation of vectors and dyadics M 5.2 Time differentiation of vectors and dyadics M 5.3 The local dyadic of vP M 5.4 Problems M 6 Integral operations M 6.1 Curves, surfaces, and volumes in the general qi system M 6.2 Line integrals, surface integrals, and volume integrals M 6.3 Integral theorems M 6.4 Fluid lines, surfaces, and volumes M 6.5 Time differentiation of fluid integrals M 6.6 The general form of the budget equation M 6.7 Gauss' theorem and the Dirac delta function M 6.8 Solution of Poisson's differential equation M 6.9 Appendix: Remarks on Euclidian and Riemannian spaces M 6.10 Problems M 7 Introduction to the concepts of nonlinear dynamics M 7.1 One-dimensional flow M 7.2 Two-dimensional flow Part 2 Dynamics of the atmosphere 1 The laws of atmospheric motion 1.1 The equation of absolute motion 1.2 The energy budget in the absolute reference system 1.3 The geographical coordinate system 1.4 The equation of relative motion 1.5 The energy budget of the general relative system 1.6 The decomposition of the equation of motion 1.7 Problems 2 Scale analysis 2.1 An outline of the method 2.2 Practical formulation of the dimensionless flow numbers 2.3 Scale analysis of large-scale frictionless motion 2.4 The geostrophic wind and the Euier wind 2.5 The equation of motion on a tangential plane 2.6 Problems 3 The material and the local description of flow 3.1 The description of Lagrange 3.2 Lagrange's version of the continuity equation 3.3 An example of the use of Lagrangian coordinates 3.4 The local description of Euler 3.5 Transformation from the Eulerian to the Lagrangian system 3.6 Problems 4 Atmospheric flow fields 4.1 The velocity dyadic 4.2 The deformation of the continuum 4.3 Individual changes with time of geometric fluid configurations 4.4 Problems 5 The Navier-Stokes stress tensor 5.1 The general stress tensor 5.2 Equilibrium conditions in the stress field 5.3 Symmetry of the stress tensor 5.4 The frictional stress tensor and the deformation dyadic 5.5 Problems 6 The Helmholtz theorem 6.1 The three-dimensional Helmholtz theorem 6.2 The two-dimensional Helmholtz theorem 6.3 Problems 7 Kinematics of two-dimensional flow 7.1 Atmospheric flow fields 7.2 Two-dimensional streamlines and normals 7.3 Streamlines in a drifting coordinate system 7.4 Problems 8 Natural coordinates 8.1 Introduction 8.2 Differential definitions of the coordinate lines 8.3 Metric relationships 8.4 Blaton's equation 8.5 Individual and local time derivatives of the velocity 8.6 Differential invariants 8.7 The equation of motion for frictionless horizontal flow 8.8 The gradient wind relation 8.9 Problems 9 Boundary surfaces and boundary conditions 9.1 Introduction 9.2 Differential operations at discontinuity surfaces 9.3 Particle invariance at boundary surfaces, displacement velocities 9.4 The kinematic boundary-surface condition 9.5 The dynamic boundary-surface condition 9.6 The zeroth-order discontinuity surface 9.7 An example of a first-order discontinuity surface 9.8 Problems 10 Circulation and vorticity theorems 10.1 ErteFs form of the continuity equation 10.2 The baroclinic Weber transformation 10.3 The baroclinic Ertel-Rossby invariant 10.4 Circulation and vorticity theorems for frictionless baroclinic flow 10.5 Circulation and vorticity theorems for frictionless barotropic flow 10.6 Problems 11 Turbulent systems 11.1 Simple averages and fluctuations 11.2 Weighted averages and fluctuations 11.3 Averaging the individual time derivative and the budget operator 11.4 Integral means 11.5 Budget equations of the turbulent system 11.6 The energy budget of the turbulent system 11.7 Diagnostic and prognostic equations of turbulent systems 11.8 Production of entropy in the microturbulent system 11.9 Problems 12 An excursion into spectral turbulence theory 12.1 Fourier Representation of the continuity equation and the equation of motion 12.2 The budget equation for the amplitude of the kinetic energy 12.3 Isotropie conditions, the transition to the continuous wavenumber space 12.4 The Heisenberg spectrum 12.5 Relations for the Heisenberg exchange coefficient 12.6 A prognostic equation for the exchange coefficient 12.7 Concluding remarks on closure procedures 12.8 Problems 13 The atmospheric boundary layer 13.1 Introduction 13.2 Prandtl-layer theory 13.3 The Monin-Obukhov similarity theory of the neutral Prandtl layer 13.4 The Monin-Obukhov similarity theory of the diabatic Prandtl layer 13.5 Application of the Prandtl-layer theory in numerical prognostic models 13.6 The fluxes, the dissipation of energy, and the exchange coefficients 13.7 The interface condition at the earth's surface 13.8 The Ekman layer - the classical approach 13.9 The composite Ekman layer 13.10 Ekman pumping 13.11 Appendix A: Dimensional analysis 13.12 Appendix B: The mixing length 13.13 Problems 14 Wave motion in the atmosphere 14.1 The representation of waves 14.2 The group velocity 14.3 Perturbation theory 14.4 Pure sound waves 14.5 Sound waves and gravity waves 14.6 Lamb waves 14.7 Lee waves 14.8 Propagation of energy 14.9 External gravity waves 14.10 Internal gravity waves 14.11 Nonlinear waves in the atmosphere 14.12 Problems 15 The barotropic model 15.1 The basic assumptions of the barotropic model 15.2 The tinfiltered barotropic prediction model 15.3 The filtered barotropic model 15.4 Barotropic instability 15.5 The mechanism of barotropic development 15.6 Appendix 15.7 Problems 16 Rossby waves 16.1 One-and two-dimensional Rossby waves 16.2 Three-dimensional Rossby waves 16.3 Normal-mode considerations 16.4 Energy transport by Rossby waves 16.5 The influence of friction on the stationary Rossby wave 16.6 Barotropic equatorial waves 16.7 The principle of geostrophic adjustment 16.8 Appendix 16.9 Problems 17 Inertial and dynamic stability 17.1 Inertial motion in a horizontally homogeneous pressure field 17.2 Inertial motion in a homogeneous geostrophic wind field 17.3 Inertial motion in a geostrophic shear wind field 17.4 Derivation of the stability criteria in the geostrophic wind field 17.5 Sectorial stability and instability 17.6 Sectorial stability for normal atmospheric conditions 17.7 Sectorial stability and instability with permanent adaptation 17.8 Problems 18 The equation of motion in general coordinate systems 18.1 Introduction 18.2 The covariant equation of motion in general coordinate systems 18.3 The contravariant equation of motion in general 18.4 The equation of motion in orthogonal coordinate systems 18.5 Lagrange's equation of motion 18.6 Hamilton's equation of motion 18.7 Appendix 18.8 Problems 19 The geographical coordinate systems 19.1 The equation of motion 19.2 Application of Lagrange's equation of motion 19.3 The first metric simplification 19.4 The coordinate simplification 19.5 The continuity equation 19.6 Problems 20 The stereographic coordinate system 20.1 The stereographic projection 20.2 Metric forms in stereographic coordinates 20.

Note: Introduction: human-environment dynamics in the high-mountain cryosphere; References; Part I Global drivers; 2 Influence of climate variability and large-scale circulation on the mountain cryosphere; 2.1 Introduction; 2.2 European mountains; 2.3 North American Cordillera; 2.4 Tibetan Plateau and the surrounding high-mountain ranges; 2.5 The tropical Andes; 2.6 Mt. Kilimanjaro: a case study from East Africa; 2.7 Conclusions; Acknowledgements; References. 3 Temperature, precipitation and related extremes in mountain areas3.1 Introduction; 3.2 Basic characteristics of near surface temperature in mountain topography; 3.2.1 Altitude dependence of 2m temperature; 3.2.2 Altitude dependence of daily temperature anomalies; 3.2.3 The relation between surface air pressure and 2m temperature; 3.3 Temperature extremes; 3.4 Precipitation patterns in mountain areas; 3.4.1 Measuring and monitoring precipitation; 3.5 Precipitation extremes; 3.5.1 Selected gridded data products; 3.5.1.1 Reanalyses; 3.5.1.2 Combined observations. 3.5.1.3 Interpolated rain-gauge station data3.5.2 Comparison and discussion of the gridded data products; 3.6 Conclusions; Acknowledgments; References; 4 Snow and avalanches; 4.1 Introduction; 4.1.1 Snow cover; 4.1.2 Snow avalanche hazard and risk; 4.2 Environmental change; 4.2.1 Climate change and mountain snow cover; 4.2.2 Effects on snow avalanches; 4.3 Socio-economic change; 4.3.1 Drivers of socio-economic change; 4.3.2 Effects on snow avalanche risk; 4.3.2.1 Temporal dynamics of socio-economic changes; 4.3.2.2 Spatial dynamics of socio-economic changes; 4.4 Conclusions; References. 5 The frozen frontier: the extractives super cycle in a time of glacier recession5.1 Introduction; 5.2 The icy edge of climate change; 5.3 The icy edge of the global extractives super cycle; 5.4 New mountains of mines and the frozen north; 5.5 Extending the extractives complex into the cryosphere; 5.6 Liquid relations and stratified societies; 5.7 The frigid fringe: extractive bio-futures and the freezing depths; 5.8 Conclusion; References; 6 Cultural values of glaciers; 6.1 Introduction; 6.2 Three cases in the Alps, the Andes, and the North Cascades. 6.3 Understanding the cultural values of glaciers6.4 Case study 1: Stilfs, South Tirol, Italian Alps; 6.4.1 The role of glaciers for community, identity, and self-reliance in Stilfs; 6.5 Case study 2: Siete Imperios, Cordillera Blanca, Peru; 6.5.1 The role of glaciers and mountains for community, identity, and self-reliance in Siete Imperios; 6.6 Case study 3: Glacier and Concrete, North Cascades, USA; 6.6.1 The role of glaciers and mountains for community, identity, and self-reliance in Glacier and Concrete; 6.7 Discussion and conclusions; Acknowledgments; References; Part II Processes. 7 Implications for hazard and risk of seismic and volcanic responses to climate change in the high-mountain cryosphere.

Note: Preface ; Acknowledgements ; List of contributors ; Part I. Diagnostics and Prediction of High-Impact Weather: 1. Global prediction of high-impact weather: diagnosis and performance Mark Rodwell and Alan Thorpe ; 2. Severe weather diagnosis from the perspective of generalized slantwise vorticity development Guoxiong Wu, Yongjun Zheng and Yimin Liu ; 3. Probabilistic extreme event attribution Pardeep Pall, Michael Wehner and Dáithí Stone ; 4. Observed and projected changes in temperature and precipitation extremes Xuebin Zhang and Francis Zwiers ; Part II. High-Impact Weather in Mid-Latitudes: 5. Rossby wave breaking: climatology, interaction with low-frequency climate variability, and links to extreme weather events Olivia Martius and Gwendal Rivière ; 6. The influence of jet stream regime on extreme weather events Nili Harnik, Chaim Garfinkel and Orli Lachmy ; 7. Forecasting high-impact weather using ensemble prediction systems Richard Swinbank, Petra Friederichs and Sabrina Wahl ; 8. Storm tracks, blocking and climate change: a review Tim Woollings ; 9. The North Atlantic and Arctic Oscillations: climate variability, extremes and stratosphere troposphere interaction Adam A. Scaife ; Part III. Tropical Cyclones: 10. Opportunities and challenges in dynamical and predictability studies of tropical cyclone events Russell L. Elsberry and Hsiao-Chung Tsai ; 11. Predictability of severe weather and tropical cyclones at the mesoscales Fuqing Zhang, Christopher Melhauser, Dandan Tao, Y. Qiang Sun, Erin B. Munsell, Yonghui Weng and Jason A. Sippel ; 12. Dynamics, predictability, and high-impact weather associated with the extratropical transition of tropical cyclones Patrick Harr and Heather M. Archambault ; 13. Secondary eyewall formation in tropical cyclones Chun-Chieh Wu, Yi-Hsuan Huang and Zhe-Min Tan ; 14. Seasonal forecasting of floods and tropical cyclones Tom Beer and Oscar Alves ; Part IV. Heat-Waves and Cold-Air Outbreaks: 15. European heat waves: the effect of soil moisture, vegetation and land use Fabio D'Andrea, Philippe Drobinski and Marc Stéfanon ; 16. Western North American extreme heat, associated large scale synoptic-dynamics, and performance by a climate model Richard Grotjahn ; 17. Decadel to interdecadel variations of Northern China heatwave frequency: impact of the Tibetan Plateau snow cover Zhiwei Wu and Jianping Li ; 18. Global warming targets and heatwave risk Robin Clark ; 19. Cold-air outbreaks over East Asia associated with blocking highs: mechanisms and their interaction with the polar stratosphere Hisashi Nakamura, Kazuaki Nishii, Lin Wang, Yvan J. Orsolini and Koutarou Takaya ; Part V. Ocean Connections: 20. Response of the Atlantic Ocean circulation to North Atlantic freshwater perturbations Henk A. Dijkstra ; 21. Key role of Atlantic Multidecadal Oscillation in twentieth-century drought and wet periods over the US Great Plains and the Sahel Sumant Nigam and Alfredo Ruiz-Barradas ; 22. Floods and droughts along the Guinea Coast in connection with the South Atlantic Dipole Hyacinth C. Nnamchi and Jianping Li ; 23. The effect of global dynamical factors on the interannual variability of land-based rainfall Peter G. Baines and Benjamin J. Henley ; 24. MJO and extreme weather and climate events Chidong Zhang ; Part VI. Asian Monsoons: 25. Extreme weather and seasonal events during the Indian summer monsoon and prospects of improvement in their prediction skill under India's monsoon mission D. R. Sikka ; 26. Interannual variability and predictability of summer climate over the Northwest Pacific and East Asia Shang-Ping Xie and Yu Kosaka ; 27. Impacts of Annular Modes on extreme climate events over the East Asian monsoon region Jianping Li ; Index.

Note: 1. Geomaterials and crustal geomechanics -- 2. Elements of rheology -- 3. Forces and stresses -- 4. Elements of kinematics -- 5. Elements of linear elasticity -- 6. From continuum mechanics to fluid mechanics -- 7. Elements of linear fracture mechanics -- 8. Laboratory investigations on geomaterials under compression -- 9. Homogenized geomaterials -- 10. Fractures and faults -- 11. Elements of seismology -- 12. Elements of solid-fluid interactions -- 13. Methods for stress fields evaluation from in situ observations -- 14. Elements of stress fields and crustal rheology -- References -- Appendix A. Elements of tensors in rectangular coordinates -- Index..

Note: Cover; Half title; Title; Copyright; Contents; Contributors; Preface; 1 Introduction; 2 Intraplate earthquakes in Australia; 2.1 Introduction; 2.2 Two centuries of earthquake observations in Australia; 2.2.1 Mechanism, geographic distribution, and strain rate; 2.2.2 Seismogenic depth; 2.2.3 Attenuation and scaling relations; 2.3 A long-term landscape record of large (morphogenic) earthquakes; 2.3.1 Variation in fault scarp length and vertical displacement; 2.3.2 The influence of crustal type and character on seismic activity rates; 2.4 Patterns in earthquake occurrence. , 2.5 Maximum magnitude earthquake2.5.1 Scarp length as a proxy for paleo-earthquake magnitude; 2.6 Implications for SCR analogue studies: factors important in earthquake localisation; 2.6.1 Mechanical and thermal influences; 2.6.2 Structural architectural influences; 2.7 Conclusions; Acknowledgements; 3 Intraplate seismicity in Brazil; 3.1 Introduction; 3.2 Earthquake catalogue; 3.3 Seismicity map; 3.4 Seismotectonic correlations; 3.4.1 Lower seismicity in Precambrian cratonic provinces; 3.4.2 Intraplate seismicity and cratonic roots; 3.4.3 Passive margin seismicity. , 3.4.4 Influence of neotectonic faults3.4.5 Flexural stresses; 3.5 Discussion and conclusions; Acknowledgments; 4 Earthquakes and geological structures of the St. Lawrence Rift System; 4.1 Introduction; 4.2 Historical earthquakes and their impact; 4.3 Seismic zones of the SLRS; 4.3.1 Charlevoix; 4.3.2 Lower St. Lawrence; 4.3.3 Western Quebec; 4.3.4 Background seismicity; 4.4 The St. Lawrence Rift System; 4.5 The rift hypothesis and the SLRS: discussion and conclusions; Acknowledgments; 5 Intraplate earthquakes in North China; 5.1 Introduction; 5.2 Tectonic background; 5.2.1 Geological history. , 5.2.2 Lithospheric structure5.2.3 Major seismogenic faults; 5.3 Active tectonics and crustal kinematics; 5.4 Strain rates and seismicity; 5.5 Seismicity; 5.5.1 Paleoseismicity; 5.5.2 Large historic events; 1303 Hongdong earthquake (M 8.0); 1556 Huaxian earthquake (M 8.3); 1668 Tancheng earthquake (M 8.5); 1679 Sanhe earthquake (M 8.0); 1695 Linfen earthquake (M 7.5-8.0); 5.5.3 Large instrumentally recorded earthquake; The 1966 Xingtai earthquake (Ms 7.2); The 1975 Haicheng earthquake (Ms 7.3); The 1976 Tangshan earthquake (Ms 7.8); 5.6 Spatiotemporal patterns of large earthquakes. , 5.6.1 Long-distance roaming of large earthquakes5.6.2 Fault coupling and interaction; 5.6.3 A conceptual model for mid-continental earthquakes; 5.7 Implications for earthquake hazards; Acknowledgements; 6 Seismogenesis of earthquakes occurring in the ancient rift basin of Kachchh, Western India; 6.1 Introduction; 6.2 Tectonic framework, structure, and tectonic evolution of Kachchh Rift basin; 6.2.1 Structure and tectonics; 6.2.2 Tectono-volcanic events; 6.2.3 Tectonic evolution and existing earthquake generation models of the Kachchh Rift zone. , 6.2.4 Identification of magmatic intrusive bodies.

Note: Contents: 1. Why climate change litigation matters; 2. Model for understanding litigation's regulatory impact; 3. Litigation as a mitigation tool; 4. Litigation as an adaptation tool; 5. Corporate responses to litigation; 6. Litigation's role in shaping social norms; 7. Barriers to progress; 8. The future of climate change litigation..

Note: Contents; Preface; 1 Introduction; 2 Fundamentals of rock failure physics; 2.1 Mechanical properties and constitutive relations; 2.1.1 Elastic deformation; 2.1.2 Ductile deformation; 2.1.3 Fracture; 2.1.4 Friction; 2.2 Basics of rock fracture mechanics; 2.2.1 Energy release rate and resistance to rupture growth; 2.2.2 Stress concentration and cohesive zone model; 2.2.3 Breakdown zone model for shear failure; 2.2.4 j-integral and energy criterion for shear failure; 2.2.5 Relation between resistance to rupture growth and constitutive relation parameters. , 3 Laboratory-derived constitutive relations for shear failure3.1 Shear failure of intact rock; 3.1.1 Method and apparatus used; 3.1.2 Constitutive relations derived from data on the shear failure of intact rock; 3.1.3 Geometric irregularity of shear-fractured surfaces and characteristic length; 3.2 Frictional slip failure on precut rock interface; 3.2.1 Method and apparatus used; 3.2.2 Geometric irregularity of precut fault surfaces and characteristic length; 3.2.3 Constitutive relations derived from data on frictional stick-slip failure. , 3.2.4 Laboratory-derived relationships between physical quantities observed during dynamic slip rupture propagation3.3 Unifying constitutive formulation and a constitutive scaling law; 3.3.1 Unification of constitutive relations for shear fracture and for frictional slip failure; 3.3.2 A constitutive scaling law; 3.3.3 Critical energy required for shear fracture and for frictional stick-slip failure; 3.3.4 Stabilityinstability of the breakdown process; 3.3.5 Breakdown zone size; 3.4 Dependence of constitutive law parameters on environmental factors; 3.4.1 Introduction. , 3.4.2 Dependence of shear failure strength on environmental factors3.4.3 Dependence of breakdown stress drop on environmental factors; 3.4.4 Dependence of breakdown displacement on environmental factors; 4 Constitutive laws for earthquake ruptures; 4.1 Basic foundations for constitutive formulations; 4.2 Rate-dependent constitutive formulations; 4.3 Slip-dependent constitutive formulations; 4.4 Depth dependence of constitutive law parameters; 5 Earthquake generation processes; 5.1 Shear failure nucleation processes observed in the laboratory; 5.1.1 Introduction; 5.1.2 Experimental method. , 5.1.3 Nucleation phases observed on faults with different surface roughnessesRough fault; Smooth fault; Extremely smooth fault; 5.1.4 Scaling of the nucleation zone size; 5.2 Earthquake rupture nucleation; 5.2.1 Seismogenic background; 5.2.2 Physical modeling and theoretical derivation of the nucleation zone size; 5.2.3 Comparison of theoretical relations with seismological data; 5.2.4 Foreshock activity associated with the nucleation process; 5.3 Dynamic propagation and generation of strong motion seismic waves; 5.3.1 Slip velocity and slip acceleration in the breakdown zone. , 5.3.2 The cutoff frequency fs max of the power spectral density of slip acceleration at the source.

Note: Contents: 1 Introduction. - 1.1 Basic Concepts and Definitions. - 1.1.1 What Gas Seepage Is, What It Is Not. - 1.1.2 A Jungle of Names: Seeps, Macroseeps, Microseepage, Microseeps, and Miniseepage. - 1.1.3 Seepage id est Migration. - 1.1.4 Microbial, Thermogenic, and Abiotic Methane. - 1.2 Significance of Seepage and Implications. - 1.2.1 Seepage and Petroleum Exploration. - 1.2.2 Marine Seepage on the Crest of the Wave. - 1.2.3 From Sea to Land. - 1.2.4 A New Vision. - References. - 2 Gas Seepage Classification and Global Distribution. - 2.1 Macro-Seeps. - 2.1.1 Gas Seeps. - 2.1.2 Oil Seeps. - 2.1.3 Gas-Bearing Springs. - 2.1.4 Mud Volcanoes. - 2.1.5 Miniseepage. - 2.1.6 The Global Distribution of Onshore Macro-Seeps. - 2.2 Microseepage. - 2.3 Marine Seepage Manifestations. - References. - 3 Gas Migration Mechanisms. - 3.1 Fundamentals. - 3.1.1 Sources and Pathways. - 3.1.2 Diffusion and Advection. - 3.2 Actual Mechanisms and Migration Forms. - 3.2.1 Bubble and Microbubble Flow. - 3.2.2 Gas Seepage Velocity. - 3.2.3 Matter Transport by Microbubbles. - 3.2.4 The Concept of Carrier Gas and Trace Gas. - References. - 4 Detecting and Measuring Gas Seepage. - 4.1 Gas Detection Methods. - 4.1.1 Above-Ground (Atmospheric) Measurements. - 4.1.2 Ground Measurements. - 4.1.3 Measurements in Aqueous Systems. - 4.2 Indirect Methods. - 4.2.1 Chemical-Mineralogical Alterations of Soils. - 4.2.2 Vegetation Changes (Geobotanical Anomalies). - 4.2.3 Microbiological Analyses of Soils. - 4.2.4 Radiometric Surveys. - 4.2.5 Geophysical Techniques. - References. - 5 Seepage in Field Geology and Petroleum Exploration. - 5.1 Seepage and Faults. - 5.2 Microseepage Applied to Areal Petroleum Exploration. - 5.2.1 Which Gas Can Be Measured?. - 5.2.2 Microseepage Methane Flux Measurements. - 5.3 Seep Geochemistry for Petroleum System Evaluation. - 5.3.1 Recognising Post-genetic Alterations of Gases. - 5.3.2 Assessing Gas Source Type and Maturity. - 5.3.3 The Presence of Undesirable Gases (CO2, H2S, N2). - 5.3.4 Helium in Seeps… for Connoisseurs. - References. - 6 Environmental Impact of Gas Seepage. - 6.1 Geohazards. - 6.1.1 Methane Explosiveness. - 6.1.2 The Toxicity of Hydrogen Sulphide. - 6.1.3 Mud Expulsions and the Degradation of Soil-Sediments. - 6.2 Stray Gas, Natural versus Man-Made. - 6.3 Hypoxia in Aquatic Environments. - 6.4 Gas Emissions to the Atmosphere. - 6.4.1 Methane Fluxes and the Global Atmospheric Budget. - 6.4.2 Ethane and Propane Seepage, a Forgotten Potential Source of Ozone Precursors. - 6.5 Natural Seepage and CO2 Geological Sequestration. - References. - 7 Seepage in Serpentinised Peridotites and on Mars. - 7.1 Seeps and Springs in Active Serpentinisation Systems. - 7.1.1 Where Abiotic Methane Is Seeping. - 7.1.2 How Abiotic Methane in Land-Based Serpentinisation Systems Is Formed. - 7.1.3 How to Distinguish Abiotic and Biotic Methane. - 7.1.4 Seepage to the Surface. - 7.1.5 Is Abiotic Gas Seepage Important for the Atmospheric Methane Budget?. - 7.2 Potential Methane Seepage on Mars. - 7.2.1 Looking for Methane on Mars. - 7.2.2 A Theoretical Martian Seepage. - References. - 8 Gas Seepage and Past Climate Change. - 8.1 Past Seepage Stronger than Today. - 8.2 Potential Proxies of Past Seepage. - 8.3 Methane and Quaternary Climate Change. - 8.3.1 Traditional Models: Wetlands versus Gas Hydrates. - 8.3.2 Adding Submarine Seeps. - 8.3.3 Considering Onshore and Offshore Seepage in Total. - 8.3.4 CH4 Isotope Signatures in Ice Cores. - 8.4 Longer Geological Time Scale Changes. - 8.4.1 The Concept of Sedimentary Organic Carbon Mobilization. - 8.4.2 Paleogene Changes. - References. - 9 Seeps in the Ancient World: Myths, Religions, and Social Development. - 9.1 Seeps in Mythology and Religion. - 9.2 Seeps in Social and Technological Development. - References. - Epilogue. - Index.

Note: Contents: Contents: 1. A long, dark shadow over democratic politics ; 2. The doctrine of democratic irrationalism ; 3. Is democratic voting inaccurate? ; 4. The Arrow general possibility theorem ; 5. Is democracy meaningless? Arrow's condition of unrestricted domain ; 6. Is democracy meaningless? Arrow's condition of the independence of irrelevant alternatives ; 7. Strategic voting and agenda control ; 8. Multidimensional chaos ; 9. Assuming irrational actors: the Powell Amendment ; 10. Assuming irrational actors: the Depew amendment ; 11. Unmanipulating the manipulation: the Wilmot proviso ; 12. Unmanipulating the manipulation: the election of Lincoln ; 13. Antebellum politics concluded ; 14. More of Riker's cycles debunked ; 15. Other cycles debunked ; 16. New dimensions ; 17. Plebiscitarianism against democracy : 18. Democracy resplendent