Applications to shallow as well as deep survey will be elucidated, compared, and contrasted. Students will be taught the techniques of instrumentation, acquisition, processing and interpretation of near-surface geophysical data. The topics are illustrated by case studies, giving the students the tools to plan, conduct and analyze a near-surface geophysical survey. Burger, H.
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Exploration geophysics of the shallow subsurface. Prentice Hall PTR. Everett, M. Near-surface applied geophysics. Kaufman, A.
Principles of electric methods in surface and borehole geophysics, volume 44 Methods in geochemistry and geophysics. Keller, G. The geoelectrical methods in geophysical exploration Methods in geochemistry and geophysics. American Geophysical Union. Nabighian, M. Electromagnetic methods vol. This course is designed for students to understand the techniques used to acquire, process and interpret gravity and magnetic data with a focus on mineral and oil industry applications. Topics to be covered include: instrumentation, field acquisition, processing, and interpretation of gravity and magnetic data land and marine and anomaly enhancement to define and map geological structures and their depth.
Hands-on exercises provide practice in the use of gravity and magnetic data define ore deposits and to recognize the presence and estimate size of any sedimentary basins, and identify some features within them, such as salt domes. Foster, N. Hinze, W. The Utility of regional gravity and magnetic anomaly maps. Society of Exploration Geophysics.
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Gravity and magnetic exploration: Principles, practices, and applications. Mishra, D. Gravity and magnetic methods for geological studies: Principles, integrated exploration and plate tectonics. Nettleton, L. Gravity and magnetics in oil prospecting McGraw-Hill international series in the earth and planetary sciences. Rama-Rao, B. Gravity and magnetic methods of prospecting.
Arnold Heinemann. This course discusses the basic principles of the many tools and techniques used in borehole logging projects. Applications are presented in terms of broad project objectives, providing a hands-on guide to geophysical logging programmes, including specific examples of how to obtain and interpret data that meet a specific hydrogeologic or environmental objective. Topics to be covered include: Planning a logging programme; log analysis — qualitative versus quantitative; log quality control; electric logs; nuclear logs; acoustic logs; borehole imaging logs; caliper logs; fluid logs; well construction logs; case histories.
Keys, W. Borehole geophysics applied to groundwater investigations. Geological Survey. A practical guide to borehole geophysics in environmental investigations. Labo, J. A practical introduction to borehole geophysics: An overview of wireline well logging principles for geophysicists Geophysical references, vol 2. Society of exploration geophysics. Paillet, F. Application of borehole geophysics in the characterization of flow in fractured rocks.
Geological Survey of Canada. Tang, X. Quantitative borehole acoustic methods, volume 24 Handbook of geophysical exploration: seismic exploration. This course deals with geophysical imaging methods that provide solutions to a wide variety of environmental and engineering problems: protection of soil and groundwater from contamination; disposal of chemical and nuclear waste; geotechnical site testing; landslide and ground subsidence hazard detection; location of archaeological artifacts; detection and mapping of sinkholes and shallow buried objects, etc.
The course comprehensively discusses the theory, data acquisition and interpretation of all of the principal geophysical methods used in engineering and environmental investigations. Each topic is supported by a large number of richly illustrated case histories. Idziak, A. Reservoir and civil engineering geophysics. McCann, D. Modern geophysics in engineering geology Geological society engineering geology special publication, The Geological Society.
McDowell, P. Geophysics in engineering investigations. Construction Industry Research. Reynolds, J. An introduction to applied and environmental geophysics. Sharma, P. Environmental and engineering geophysics. Vogelsang, D. Environmental geophysics: A practical guide Environmental engineering. In this course students will understand the essentials of airborne geophysics so that they can evaluate the usefulness and application potential of the methods and results in their projects.
Airborne geophysical methods to be taught include: aeromagnetic method; airborne electromagnetic method; airborne gamma-ray spectrometry; airborne gravity method; and remote sensing methods. All aspects of these methods will be discussed, including theoretical considerations, data acquisition, and data processing and interpretation, with the objective of locating concentrations of natural resources and defining their extent.
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Practical sessions will involve the interpretation of raw airborne geophysical data. Airborne geophysics and precise positioning: Scientific issues and future directions. National Academies Press. Field geophysics Geological Field Guide.
Mwano, J. Applied geophysics: Integrated interpretation of airborne geophysical data and satellite image for geological mapping. Telford, W. Applied geophysics.
Airborne measurements for environmental research: Methods and instruments Wiley series in atmospheric physics and remote sensing Wiley-VCH. The course presents and discusses recent findings on the physics of earthquakes. Topics to be covered include seismicity studies from pre-historic periods to the most modern studies on a global scale, deep earthquakes, nucleation, stress transfer, triggering, hydrological processes, and recently discovered slow slips at plate boundaries.
Practical understanding of the most commonly used processing techniques in earthquake seismology will also be treated. Each topic will be introduced with the basic theory followed by practical examples and exercises from both manually printed materials and computer exercises based on public domain software. There will be field visits to earthquake observatories, seismograph stations and seismometer sites. Guidoboni, E. Earthquakes and tsunamis in the past: A guide to techniques in historical seismology.
Havskov, J. Routine data processing in earthquake seismology: With sample data, exercises and software.
Kanamori, H. Earthquake seismology: Treatise on geophysics. Lee, W. Stein, S. An introduction to seismology, earthquakes and earth structure. The course consists of a series of lectures on the application of trace element geochemistry to the understanding of trace element partitioning during partial melting and fractional crystallization.
The emphasis of the course is on the use of trace element geochemistry to understand the origin and evolution of igneous rocks. The approach is to discuss the parameters that control partitioning of trace elements between phases and to develop models for the partitioning of trace elements between phases in igneous systems, especially between minerals and melt.
Throughout the course, lectures are interspersed with papers that are to be read by students and discussed during class.
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