Geodynamics and Basin Modelling
Postgraduate course
- ECTS credits
- 10
- Teaching semesters
- Autumn
- Course code
- GEOV254
- Number of semesters
- 1
- Teaching language
- English
- Resources
- Schedule
Course description
Objectives and Content
Objectives:
The course gives an introduction to quantitative geodynamics. The overall goal of this course is to provide the students with a good understanding of geodynamics and surface processes. A first sub-goal of this course is to provide the students with an intermediate level of understanding of geodynamic processes of the solid earth plus programming skills in computational methods. A second sub-goal of this course is for the students to learn how to do a literature study on a topic in geodynamics and/or surface processes.
Content:
In the first part, a brief overview of plate tectonic processes is given. The equation for thermal energy balance for the lithosphere is developed, and it is shown how the equation may be applied on various geological models and processes. Vertical movements expressed as uplift or exhumation and the concept of isostasy and flexural strength are then examined. The mechanics of the crust and lithosphere deformation is covered including a discussion of plate driving forces, the rheology of the lithosphere, elastic, brittle and viscous deformation processes. The response of rocks to applied forces is discussed and modelled. Dynamic processes including lithosphere extension, basin formation, and continental collision are discussed. Lastly the course gives an introduction to quantitative geomorphology, erosion models for orogenic scale landscape evolution including both short and long range transport mechanisms. The course uses Matlab to calculate and visualise the evolution of temperature, strength, basin subsidence, and surface erosion for simple cases.
Learning Outcomes
n completion of the course the student should have the following learning outcomes defined in terms of knowledge, skills and general competence:
Knowledge
The student can
- solve the heat equation for simple geologic problems
- create Matlab programs to calculate temperature and heat flow for various geological scenarios and to calculate dependent strength within the lithosphere
- explain Eulerian and Lagrangian reference frames
- explain the concepts of uplift, subsidence, burial, exhumation, denudation
- explain local and regional isostasy, and solve simple isostatic problems related to erosion and sedimentation
- describe the basis for the equation showing depth of the oceans as function of age
- describe the McKenzie rift model, and explain the concepts crust and mantle stretching factors, backstripping, tectonic, thermal, and isostatic subsidence
- explain fundamentals of stress and strain
- explain what controls the rheology of the oceanic and continental lithosphere
- explain erosion models at an orogenic scale, and short and long term transport mechanisms
- know how to conduct a literature study on a topic on computational geophysics and/or a small research project
- use tools from the library as well as online tools for this project in computational geophysics
Skills
The student can
- write computer programs in Matlab to illustrate and solve scientific problems in geodynamics and surface processes
- write a short scientific paper on a topic of relevance in computational geodynamics and/or surface processes
- give a presentation on this topic in computational geodynamics and/or surface processes to peers and experts
General competence
The student can
- write computer programs of relevance in geodynamics and surface processes
- do an independent literature study and/or research project in the area of computational geodynamics and surface processes
- participate in a discussion on a research topic in computational geodynamics and surface processes
Semester of Instruction
Required Previous Knowledge
Access to the Course
Teaching and learning methods
Total teaching of 12 weeks
First 10 weeks: Teaching using active learning techniques: 3 hours/week,
Last 2 weeks: research or literature project
Compulsory Assignments and Attendance
Forms of Assessment
The course uses the following assessment:
Portfolio assessment:
- Assessment of a written report for each of the compulsory exercises after each lecture
- Oral presentation of one topic from the course material
- Individual written assignment to be delivered by the end of the course
- Oral discussion on written assignment and other course content
It is not possible to appeal the grade of this portfolio assessment. This is because a large part of the assessment in this course takes place orally in the classroom and would not be possible to reevaluate