## Hansruedi Maurer: Katalogdaten im Frühjahrssemester 2021 |

Name | Herr Prof. Dr. Hansruedi Maurer |

Lehrgebiet | Angewandte Geophysik |

Adresse | Institut für Geophysik ETH Zürich, NO H 46 Sonneggstrasse 5 8092 Zürich SWITZERLAND |

Telefon | +41 44 633 68 38 |

Fax | +41 44 633 10 65 |

hansruedi.maurer@erdw.ethz.ch | |

Departement | Erdwissenschaften |

Beziehung | Titularprofessor und Privatdozent |

Nummer | Titel | ECTS | Umfang | Dozierende | |
---|---|---|---|---|---|

651-1062-00L | Master's ThesisIn the last semester of the Joint MSc in Applied Geophysics, students write their Master’s Thesis at one of the three universities, other approved university or industry laboratories. | 30 KP | 64D | H. Maurer | |

Kurzbeschreibung | |||||

Lernziel | |||||

651-4087-00L | Case Studies in Exploration and Environmental Geophysics | 3 KP | 3G | H. Maurer, J. Robertsson, M. Hertrich, M. O. Saar, T. Spillmann | |

Kurzbeschreibung | This course focuses on benefits and limitations of geophysical methods applied to problems of high societal relevance. It is demonstrated, how seismics, ground-penetrating-radar and other electromagnetic methods can be employed in geothermics, the cryosphere, hydrocarbon exploration, natural hazard assessments and radioactive waste disposal problems. | ||||

Lernziel | This course is set up for both, geophysicists and non-geophysicists. The former will become familiar with applications of geophysical methods, for which they have learned the underlying theory in other courses. Non-geophysicists (i.e., potential users of geophysical technics, such as geologists and geotechnical engineers) will learn, which geophysical method or which combination of geophysical methods can be used to solve a particular in their realm. The main learning goal for both groups is to understand the benefits and limitations of geophysical techniques for important applications, such as exploration problems, waste disposal, or natural hazards. | ||||

Inhalt | During the first part of the course, various themes will be introduced, in which geophysical methods play a key role. Module 1 (25.2./4.3): Geothermal Energy (M. Saar) Module 2 (11.3.): Natural Hazards (H.R. Maurer) Module 3 (18.3.): Cryosphere Applications (H.R. Maurer) Module 4 (25.3./1.4.): Radioactive Waste Disposal (T. Spillmann) Module 5 (15.4.): Marine Seismics (J. Robertsson) Module 6 (22.4.): Hydrocarbon Exploration (Fons ten Kroode) During the second part of the course, we will focus on Deep Underground Laboratories. They offer exciting opportunities for research associated with many themes covered in Modules 1 to 6. This block starts with an introductory lecture (29.4.), followed by visits of the three main Deep Underground Laboratories in Switzerland: 6.5: Bedretto Laboratory 20.5 .: Mont Terri Laboratory 27.5.: Grimsel Test Site The laboratory visits will occupy the full afternoons of the respective days. Of course, the visits will only be possible, when the COVID-19 situation will be appropriate. Otherwise, virtual laboratory tours are planned. For earning the credit points, at least two out of the three laboratory visits are mandatory, but the students are encouraged, to join all visits. Active participation of the students will be required. Prior to the laboratory visits, the students must familiarize themselves with one experiment (in total, not per laboratory), and they will introduce this experiment during the visit to their fellow students. Finally, a short report on the experiment assigned will have to be written. Presentation and report will contribute 50% to the final grade. The remaining 50% of the final grade will be earned during a project work on June 3. The students will receive a small project out of the themes of Modules 1 to 6. During a few hours, they will work independently on the project, and they have to summarize their results in a short report. | ||||

Skript | Course material will be provided in the teaching repository associated with this course. | ||||

Literatur | Provided during the course | ||||

Voraussetzungen / Besonderes | Basic knowledge of geophysical methods is required. Students registering for the course confirm having read and accepted the terms and conditions for excursions and field courses of D-ERDW https://www.ethz.ch/content/dam/ethz/special-interest/erdw/department/dokumente/studium/exkursionen/AGB_ERDW_Exkursionen_en.pdf | ||||

651-4094-00L | Numerical Modelling for Applied Geophysics | 5 KP | 2G | J. Robertsson, H. Maurer | |

Kurzbeschreibung | Numerical modelling in environmental and exploration geophysics. The course covers different numerical methods such as finite difference and finite element methods applied to solve PDE’s for instance governing seismic wave propagation and geoelectric problems. Prerequisites include basic knowledge of (i) signal processing and applied mathematics such as Fourier analysis and (ii) Matlab. | ||||

Lernziel | After this course students should have a good overview of numerical modelling techniques commonly used in environmental and exploration geophysics. Students should be familiar with the basic principles of the methods and how they are used to solve real problems. They should know advantages and disadvantages as well as the limitations of the individual approaches. The course includes exercises in Matlab where the stduents both should lear, understand and use existing scripts as well as carrying out some coding in Matlab themselves. | ||||

Inhalt | During the first part of the course, the following topics are covered: - Applications of modelling - Physics of acoustic, elastic, viscoelastic wave equations as well as Maxwell's equations for electromagnetic wave propagation and diffusive problems - Recap of basic techniques in signal processing and applied mathematics - Potential field modelling - Solving PDE's, boundary conditions and initial conditions - Acoustic/elastic wave propagation I, explicit time-domain finite-difference methods - Acoustic/elastic wave propagation II, Viscoelastic, pseudospectral - Acoustic/elastic wave propagation III, spectral accuracy in time, frequency domain FD, Eikonal - Implicit finite-difference methods (geoelectric) - Finite element methods, 1D/2D (heat equation) - Finite element methods, 3D (geoelectric) - Acoustic/elastic wave propagation IV, Finite element and spectral element methods - HPC and current challenges in computational seismology - Seismic data imaging project Most of the lecture modules are accompanied by exercises Small projects will be assigned to the students. They either include a programming exercise or applications of existing modelling codes. | ||||

Skript | Presentation slides and some background material will be provided. | ||||

Literatur | Igel, H., 2017. Computational seismology: a practical introduction. Oxford University Press. | ||||

Voraussetzungen / Besonderes | This course is offered as a full semester course. During the second part of the semester some lecture slots will be dedicated towards working on exercises and course projects. | ||||

651-4104-00L | Geophysical Field Work and Processing: Methods | 2 KP | 3V | C. Schmelzbach, H. Maurer | |

Kurzbeschreibung | The 'Methods' part of 'Geophysical Fieldwork and Processing' provides an overview over the most common methods used in Applied Geophysics. Theoretical and conceptual aspects as well as data acquisition and processing of the methods used in the other two parts of the course are introduced. | ||||

Lernziel | Students should (1) acquire a basis knowledge on theory and working principles of the most common techniques in Applied Geophysics and (2) acquire the necessary knowledge to plan, conduct, process and document a near-surface geophysics survey. | ||||

Inhalt | The course is divided into four parts: 1. Introduction to the course held in the lecture hall (first lecture) 2. Online lectures and quizzes covering short reviews of the theory, techniques, acquisition and processing of: - Ground Penetrating Radar (GPR) - Electrical Resistivity Tomography (ERT) - Magnetic Surveying - Electromagnetic Induction Surveying - Seismic Refraction Tomography There will be a questions-and-answers session before the exam. 3. Practical exercise and field equipment demonstration (outdoor; location and date will be communicated during the introduction lecture). Participation in the practical exercise is a REQUIREMENT. 4. Written examination during the last lecture. A pass in this exam is a REQUIREMENT to continue with the second part of the course 651-4106-03L Geophysical Field Work and Processing: Preparation and Field Work. | ||||

Skript | Available over the ETH online lecture Moodle page. Link will be given during the first lecture. | ||||

Literatur | Recommended literature: An introduction to geophysical exploration Third Edition Kearey, Brooks, and Hill 2002, WILEY-BLACKWELL ISBN: 978-0-632-04929-5 Further recommended literature: Environmental Geology Handbook of Field Methods and Case Studies Knödel, Klaus, Lange, Gerhard, Voigt, Hans-Jürgen Bundesanstalt für Geowissenschaften (Ed.) 2007, XXVI, 1358 p. 501 illus., 243 in color., Hardcover ISBN: 978-3-540-74669-0 Fundamentals of Geophysics William Lowrie 2nd Edition Cambridge University Press ISBN: 9780521675963 Good overview literature: An Introduction to Applied and Environmental Geophysics John M, Reynolds WILEY-BLACKWELL ISBN: 978-0-471-48535-3 More detailed and specific: Near-Surface Geophysics Edited by Dwain K. Butler Society of Exploration Geophysicists (SEG) ISBN: 9781560801306 (13); 1560801301 (10) | ||||

Voraussetzungen / Besonderes | Joint Master students must attend all three parts of 'Geophysical Fieldwork and Processing': 'Methods', 'Preparation', and 'Fieldwork'. A "pass" (Swiss grade 4.0 or higher) in the 'Methods' written examination is an absolute REQUIREMENT to participate in the 'Preparation' and 'Fieldwork' part. Students registering for the course confirm having read and accepted the terms and conditions for excursions and field courses of D-ERDW https://www.ethz.ch/content/dam/ethz/special-interest/erdw/department/dokumente/studium/exkursionen/AGB_ERDW_Exkursionen_en.pdf |