ALBERT

Note: N.F. entfällt ab 57.2000. - Volltext auch als Teil einer Datenbank verfügbar , Ersch. ab 2000 in engl. Sprache mit dt. Hauptsacht.

Note: Contents List of Contributors Preface Chapter 1 An Introduction to the Ocean Soundscape 1.1 Introduction 1.2 Seismic Waves 1.2.1 Body Waves 1.2.2 Surface Waves 1.3 Noise Sources in the Oceans 1.3.1 Noise from Geological Origins (Geophony) 1.3.2 Noise from Biological Origins (Biophony) 1.3.3 Noise from Anthropogenic Origins (Anthrophony) 1.4 Tools for Recording Marine Noise 1.4.1 Ocean-Bottom Seismometers 1.4.2 Ocean-Bottom Nodes 1.4.3 Ocean-Bottom Observatories 1.4.4 Acoustic Doppler Current Profilers 1.4.5 Echosounders 1.4.6 Drifters and Floats 1.5 Common Data-Processing Methods 1.5.1 Time-Drift Correction 1.5.2 Data Reduction 1.5.3 Instrument Relocation through Travel-Time Analysis 1.5.4 Rotation for Geophone Reorientation 1.5.5 Converting from Counts to Physical Units 1.5.6 Removing the Mean from the Data Set 1.5.7 Frequency Spectrum, Spectrogram, and Power Spectral Density 1.5.8 Frequency Filtering 1.5.9 Polarization Analysis 1.6 Summary of Chapters 1.7 Future Developments of Acoustic Measurements in the Ocean References Chapter 2 Seismic Ambient Noise: Application to Taiwanese Data 2.1 Introduction 2.2 Background Ambient Seismic Noise in Taiwan 2.3 Ambient Seismic Noise Generated by Intense Storms 2.4 Deepsea Internal Waves Southeast of Offshore Taiwan 2.5 Gas Emissions at the Seafloor and "Bubble" SDEs in SW Offshore Taiwan 2.6 Conclusion Acknowledgments References Chapter 3 Seasonal and Geographical Variations in the Quantified Relationship Between Significant Wave Heights and Microseisms: An Example From Taiwan 3.1 Introduction 3.2 Method and Data Processing 3.2.1 Data 3.2.2 Method 3.3 Testing and Determining Parameters 3.4 Results and Discussion 3.4.1 Seasonal Variation 3.4.2 Geographical Variation 3.4.3 Residual Distributions of the SHW Simulation 3.5 Conclusions -- Acknowledgments References Chapter 4 Listening for Diverse Signals From Emergent and Submarine Volcanoes 4.1 Introduction 4.2 Detection and Monitoring of Submarine Volcanism 4.2.1 Hydroacoustic Arrays 4.2.2 Seismometer Arrays 4.2.3 Cabled Systems 4.2.4 Limitations in Detecting Submarine Volcanism 4.3 Diverse Volcano Signals Recorded Underwater 4.3.1 Distinguishing Signal from Noise in the Ocean 4.3.2 High-Frequency Volcanic Signals 4.3.3 Low-Frequency Volcanic Signals 4.3.4 Volcanic Tremor Signals 4.3.5 Volcanic Explosion-Type Signals 4.3.6 Volcanic Landslide Signals 4.4 Conclusions Availability Statement Acknowledgments References Chapter 5 Seismic and Acoustic Monitoring of Submarine Landslides: Ongoing Challenges, Recent Successes, and Future Opportunities 5.1 Introduction 5.1.1 Recent Advances in Direct Monitoring of Submarine Landslides 5.1.2 Aims 5.2 Passive Geophysical Monitoring of Terrestrial Landslides 5.3 Which Aspects of Submarine Landslides Should We Be Able to Detect with Passive Systems? 5.4 Recent Advances and Opportunities in Passive Monitoring of Submarine Landslides 5.4.1 Determining the Timing and Location of Submarine Landslides at a Margin Scale Using Land-Based Seismological Networks 5.4.2 Quantifying Landslide Kinematics Using Hydrophones 5.4.3 Characterizing Landslide Run-Out to Enhance Hazard Assessments 5.4.4 Opportunities Using Distributed Cable-Based Sensing 5.5 The Application of Passive Geophysical Monitoring in Advancing Submarine Landslide Science 5.5.1 Can Passive Seismic and Acoustic Techniques Overcome the Logistical Challenges That Have Previously Hindered the Monitoring of Submarine Landslides? 5.5.2 What Aspects of Submarine Landslides Can We Assess from Passive Remote Sensing Techniques, and What Needs To Be Resolved? 5.5.3 Suggestions for Future Directions 5.6 Concluding Remarks Acknowledgments References Chapter 6 Iceberg Noise 6.1 Introduction 6.2 Waveforms of Iceberg Noise 6.2.1 Iceberg Bursts 6.2.2 Iceberg Tremor 6.2.3 Iceberg Harmonic Tremor 6.3 Observation and Location of Iceberg Noise 6.3.1 Hydroacoustic Records at Long Distances 6.3.2 Records of Regional Hydroacoustic Networks 6.3.3 Seismic Records in Antarctica 6.4 Spatial and Temporal Variations of Iceberg Noise 6.5 Source Mechanisms of Iceberg Noise 6.6 Discussion 6.7 Conclusion Acknowledgments References Chapter 7 The Sound of Hydrothermal Vents 7.1 Introduction 7.2 Theory of Sound Production by Hydrothermal Vents 7.2.1 Radiation Efficiency 7.2.2 Monopole 7.2.3 Dipole 7.2.4 Quadrupole 7.2.5 Estimated Source Sound Pressure Levels 7.2.6 Estimated Source Spectra 7.3 Survey of Acoustic Measurements 7.3.1 Very Low Frequency (〈 10 Hz) 7.3.2 Narrowband 7.3.3 Broadband 7.3.4 Tidal Variability 7.3.5 Summary of Acoustic Measurements 7.4 Other Sources of Ambient Noise 7.4.1 Microseisms 7.4.2 Local and Teleseismic Events 7.4.3 Biological Sources 7.4.4 Anthropogenic Sources 7.5 Measurement and Analysis Considerations 7.5.1 Flow Noise and Coupled Vibration 7.5.2 Sound Speed in Hydrothermal Fluid 7.5.3 Near Field vs Far Field 7.5.4 Hydrophone Array Measurements 7.6 Conclusion Nomenclature References Chapter 8 Atypical Signals: Characteristics and Sources of Short-Duration Events 8.1 Introduction 8.2 Signal Characteristics 8.3 Worldwide Distribution of SDEs 8.4 Observations and Studies Advancing SDE Understanding 8.4.1 Observations from Different Types of Ocean Bottom Instruments 8.4.2 Continuous Long-Term, Multidisciplinary Monitoring of Gas Emissions 8.4.3 Correlation with Acoustic Monitoring of Gas Emissions 8.4.4 Correlation with Earthquakes 8.4.5 Correlation with Tides 8.4.6 Controlled in situ and Laboratory Experiments 8.5 Discussion of SDE Potential Sources 8.5.1 Biological Origin 8.5.2 Action of Ocean/Sea Currents 8.5.3 Fluids in Near-Surface Sediments 8.5.4 Low-Magnitude Seismicity 8.5.5 Source Modeling 8.6 Conclusion Acknowledgments References Chapter 9 Short-Duration Events Associated With Active Seabed Methane Venting: Scanner Pockmark, North Sea 9.1 Introduction 9.2 Scanner Pockmark Complex 9.3 CHIMNEY Seismic Experiment 9.4 Methods 9.5 Results 9.6 Discussion 9.6.1 Characteristics of SDEs 9.6.2 Spatial Distribution of SDEs 9.6.3 Negative Correlation with the Tide 9.6.4 Efficiency of SDE Detection 9.7 Conclusion Acknowledgments References Chapter 10 Ambient Bubble Acoustics: Seep, Rain, and Wave Noise 10.1 Introduction 10.2 Bubbles as Acoustic Sources 10.2.1 The Injection of a Gas Bubble 10.2.2 Bubbles as Simple Harmonic Oscillators 10.2.3 Minnaert Frequency 10.3 Subsurface Gas Release 10.3.1 Gas-Seep Acoustics 10.4 Rainfall Acoustics 10.5 Acoustics of Breaking Waves 10.6 Conclusion Further Reading Appendix Symbology References Chapter 11 Baleen Whale Vocalizations 11.1 Introduction 11.1.1 Marine Mammal Classification 11.2 Physical Description of Sound and Its Conventions 11.2.1 Sound Pressure Level (SPL) 11.2.2 Source Level (SL) 11.2.3 Whale-Sound Analysis 11.3 Marine Mammal Vocalizations 11.3.1 Sirenia and Carnivora 11.3.2 Toothed Whales 11.3.3 Baleen Whales 11.4 Conclusions Acknowledgments References Chapter 12 Tracking and Monitoring Fin Whales Offshore Northwest Spain Using Passive Acoustic Methods 12.1 Introduction 12.1.1 Passive Acoustic Monitoring 12.1.2 Fin Whale Vocalizations 12.1.3 Data Available for This Study 12.2 Methods 12.2.1 Call Detection 12.2.2 Delay Estimation 12.2.3 Localization and Tracking 12.2.4 Kalman Filter 12.3 Results 12.3.1 Detections 12.3.2 Localization 12.3.3 Tracking 12.4 Discussion 12.5 Conclusions Acknowledgments References Chapter 13 Noise From Marine Traffic 13.1 Introduction 13.2 Underwater Radiated Noise 13.2.1 Sources of Shipping Noise 13.2.2 Measuring Radiated Noise 13.2.3 Modeling Underwater Radiated Noise 13.3 Noise Mapping 13.3.1 Modeling Shipping Contributions 13.3.2 Source Properties 13.3.3 Acoustic Propagation 13.3.4 Noise-Mapping Applications 13.4 Conclusion Acknowledgments References Chapter 14 Tracking Multiple Underwater Vessels With Passive Sonar Using Beamforming and a Trajectory PHD Filter 14.1 Introduction 14.2 Narrow-Band Signal Model 14.3 Detection via Beamforming and CA-CFAR 14.3.1 CBF 14.3.2 CA-CFAR 14.4 T

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Note: Contents Foreword Prologue Earth’s Freezer: Introduction to Permafrost Frozen grounds: Permafrost in the Arctic Permafrost in profile: Landscape features Frozen in time: The history of permafrost An icy balance: Arctic permafrost physiography What lies within: Organic carbon in permafrost When ice grows up: Pingo Canadian Landmark Drilling down: Learning the secrets of permafrost Portrait: Annett Bartsch Un/settled: Life on frozen ground Frozen States I: Russian Federation Portrait: Vyacheslav Shadrin Frozen States II: North America Portrait: Jessi Pascal Frozen States III: Nordic region Portrait: Palle Jeremiassen Awakening Giant: Permafrost and Climate Change Warming up, warming down: Increasing ground temperatures The chill is gone: Thickening of the active layer Disappearing act: Declining permafrost extent Microorganisms, macro effects: Permafrost carbon cycle Faster, deeper, stronger I: Speed of thaw in North America Faster, deeper, stronger II: Speed of thaw in Scandinavia and the Russian Federation Crossing the threshold: Future scenarios of carbon release Portrait: Dmitry Streletskiy Moving Grounds: Permafrost Changes Frost and flora: The role of vegetation in permafrost landscapes Fire on ice: Peat, permafrost, and fire State of matter: Water, snow, and permafrost The rivers run through it: Arctic rivers, deltas and hydrology Along the edge of the world: Arctic coastal classification Wear and tear: Erosion of Arctic permafrost coasts Eating into the landscape: Retrogressive thaw slumps Portrait: Angus Alunik Losing ground: Projected rates of Arctic coastal erosion Beneath the waves: Changes in subsea permafrost Arctic Ripples: Impacts of Permafrost Thaw Feeling the heat: Permafrost thaw impacts on infrastructure Risky business I: North American Arctic and Kalaallit Nunaat (Greenland) Risky business II: The Russian Federation and Scandinavian Arctic Terra infirma I: Coastal infrastructure in Yamalo-Nenets Portrait: Susanna Gartler Terra infirma II: Reinforcing runways in Paulatuk Terra infirma III: Keeping cold food cold in Alaska Terra infirma IV: Urban planning in Ilulissat Nothing in isolation: Health and wellness and permafrost Portrait: Gwen Healey Akearok Toxic grounds: Contaminants and environmental health Coming back to life: Reemerging pathogens Frozen assets I: The formal economy Frozen assets II: Traditional and subsistence activities Cultural homeland: Alaas landscapes in Yakutia Holding Tight: Adaptation to Permafrost Thaw Bumpy road ahead: Transportation infrastructure and permafrost Undermined: Mining infrastructure and permafrost Keeping the light on: Energy infrastructure and permafrost No time to waste: Waste management and permafrost Modern history: Preserving Svalbard’s cultural heritage Portrait: Ingrid Rekkavik Going South: Permafrost in Other Areas A planetary perspective: Permafrost outside the Arctic Frozen giants: Permafrost in the mountains The view from the top: The Qinghai-Tibetan Plateau, Hindu Kush Himalaya, and Andes Europe’s frozen heart: Permafrost in the Alps The ends of the Earth I: Permafrost in Antarctica The ends of the Earth II: Antarctic Peninsula The ends of the Earth III: Queen Maud Land, Victoria Land, and the McMurdo Dry Valleys Over the Horizon Authors and contributors Acknowledgments Artist spotlight: Olga Borjon-Privé (Oluko) Artist spotlight: Katie Orlinsky Glossary Acronyms References

Note: Contents Acknowledgements Legend for the cover image Chiarella, D., Archer, S. G., Howell, J. A., Jackson, C. A.-L., Kombrink, H. and Patruno, S. / Cross-border subsurface geology in the Atlantic Margin and the Barents Sea: an introduction Tectonic evolution Libak, A., Torabi, A. and Alaei, B. / Normal fault geometric attribute variations with lithology: examples from the Norwegian Barents Sea Anell, I., Indrevær, K. and Serck, C. S. / Influence of structural highs on Triassic deposition on the western Barents Shelf Kristensen, T. B., Rotevatn, A., Marvik, M., Henstra, G. A., Gawthorpe, R. L. and Ravnås, R. / Quantitative analysis of fault-and-fold growth in a transtensional basin: the Sørvestsnaget Basin, Western Barents Sea Trice, R., Hiorth, C. and Holdsworth, R. / Fractured basement play development on the UK and Norwegian rifted margins Millett, J. M., Manton, B. M., Zastrozhnov, D., Planke, S., Maharjan, D., Bellwald, B., Gernigon, L., Faleide, J. I., Jolley, D. W., Walker, F., Abdelmalak, M. M., Jerram, D. A., Myklebust, R., Kjølhamar, B. E., Halliday, J. and Birch-Hawkins, A. / Basin structure and prospectivity of the NE Atlantic volcanic rifted margin: cross-border examples from the Faroe–Shetland, Møre and Southern Vøring basins Stratigraphic, sedimentological and reservoir characterization Jones, G. E. D., Welbon, A. I. F., Mohammadlou, H., Sakharov, A., Ford, J., Needham, T. and Ottesen, C. / Complex stratigraphic fill of a small, confined syn-rift basin: an Upper Jurassic example from offshore mid-Norway Chiarella, D. and Joel, D. / Stratigraphic and sedimentological characterization of the Late Cretaceous post-rift intra Lange Sandstones of the Gimsan Basin and Grinda Graben (Halten Terrace, Norwegian Sea) Walker, F., Schofield, N., Millett, J., Jolley, D., Hole, M. and Stewart, M. / Paleogene volcanic rocks in the northern Faroe–Shetland Basin and Møre Marginal High: understanding lava field stratigraphy Klausen, T. G., Müller, R., Poyatos-Moré, M., Olaussen, S. and Stueland, E. / Tectonic, provenance and sedimentological controls on reservoir characteristics in the Upper Triassic–Middle Jurassic Realgrunnen Subgroup, SW Barents Sea Riis, F. and Wolff, A. / Use of pore pressure data from the Norwegian Continental Shelf to characterize fluid-flow processes in geological timescales Hunt, G. A., Williams, R., Charnock, M. A., Moss, A., Meltveit, J. and Florescu, D. / Geological and petrophysical applications of imaging infrared spectroscopy for mineralogical analysis of core and cuttings: examples from the North Sea, Norwegian Sea and Barents Sea Index