Derek Vance: Catalogue data in Autumn Semester 2018

Award: The Golden Owl
Name Prof. Dr. Derek Vance
FieldGeochemistry
Address
Inst. für Geochemie und Petrologie
ETH Zürich, NW D 81.4
Clausiusstrasse 25
8092 Zürich
SWITZERLAND
Telephone+41 44 632 68 81
Fax+41 44 632 11 79
E-mailderek.vance@eaps.ethz.ch
URLhttp://www.erdw.ethz.ch/en/people/profile.html?persid=85257
DepartmentEarth and Planetary Sciences
RelationshipFull Professor

NumberTitleECTSHoursLecturers
651-0254-00LSeminar Geochemistry and Petrology0 credits2SO. Bachmann, M. Schönbächler, C. A. Heinrich, M. W. Schmidt, D. Vance
AbstractSeminar series with external and occasional internal speakers addressing current research topics. Changing programs announced via D-ERDW homepage (Veranstaltungskalender)
Learning objectivePresentations on isotope geochemistry, cosmochemistry, fluid processes, economic geology, petrology, mineralogy and experimental studies. Mostly international speakers provide students, department members and interested guests with insight into current research topics in these fields.
ContentWöchentliches Seminar mit Fachvorträgen eingeladener oder interner Wissenschafter, vornehmlich zu Themen der Geochemie, Isotogengeologie, Hydrothermalgeochemie, Lagerstättenbildung, Petrologie, Mineralogie und experimentelle Studien.
651-1091-00LColloquium Department Earth Sciences0 credits1KH. Stoll, D. Vance
AbstractInvited speakers from the entire range of Earth Sciences.
Learning objectiveSelected themes in sedimentology, tectonics, paläontology, geophysics, mineralogy, paleoclimate and engineering geology on a regional and global scale.
ContentAccording to variable program.
Lecture notesNo
LiteratureNo
651-3400-00LGeochemistry I Information
The course replaces 651-3400-00 Geochemie. Students who completed 651-3400-00 Geochemie are not eligible to Geochemie I.
4 credits3GM. Schönbächler, D. Vance
AbstractIntroduction to geochemistry and its application to the study of the origin and evolution of the Earth and planets.
Learning objectiveGain an overview of geochemical methods used in various fields of Earth Sciences and how they can be applied to study geological processes in the Earth’s mantle, crust, oceans and atmosphere.
ContentThis course is an introduction into geochemistry with a special focus on the basic concepts used in this rapidly evolving field. The course deals with the geochemist's toolbox: the basic chemical and nuclear properties of elements from the periodic table and how these elements can be used to ask fundamental questions in Earth Sciences. The important concepts used in solid-solution-gas equilibria are introduced. The concepts of chemical reservoirs and geochemical cycles are discussed with examples from the carbon cycle in the Earth. The course also addresses geological applications in low- and high-temperature geochemistry, including the formation of continents, the differentiation of the Earth, the geochemistry of ocean and continental waters.
Lecture notesThe slides are available online.
LiteratureH. Y. McSween et al.: Geochemistry - Pathways and Processes,
2nd ed. Columbia Univ. Press (2003)

William White: Geochemistry, Wiley-Blackwell Chichester (2013)
Prerequisites / NoticePrerequisite: chemical thermodynamics, basic inorganic chemistry and physics.
651-3507-00LIntroduction to Oceanography and Hydrogeology3 credits2VD. Vance, M. O. Saar
AbstractThe course provides an introduction to hydrogeology and oceanography for all Earth Science students at ETH. It provides an overview of the physical controls on water flow in streams, aquifers, and the oceans. It also deals with the basics of groundwater chemistry, biogeochemical cycling in the oceans, the role of the oceans as carbon reservoirs and their dynamic redox state.
Learning objectiveTo understand and describe the basic principles of the hydrologic cycle and water flow in streams and aquifers.

To conduct simple calculations of water transfer in streams and aquifers as well as of flood frequencies and magnitudes.

To discuss surface and groundwater as a water resource.

To interpret different ion distributions in aquifers in terms of bacic water chemistry, fluid-mineral reactions, water contamination, and water origin.

To understand the major features of ocean basins and the tectonic controls on their structure.

To identify the major controls on the temperature, salinity and density structure of the oceans.

To describe how these controls interact to drive surface and interior ocean circulation.

To interpret different kinds of element distribution in the oceans in terms of basic chemistry, sinks, sources and internal biogeochemical cycling.

To discuss the cycles of carbon and oxygen in the ocean, with a view to the critical analysis of how the oceans respond to, cause and record the dynamics of these cycles in Earth history.
ContentThis course provides an introduction to oceanography and hydrogeology, with a special focus on the basic physicochemical concepts that control the properties and behaviour of two major reservoirs of water on Earth.

The hydrogeology component will: 1) describe the hydrologic cycle, with a focus on the importance of groundwater to society; introduce the basic physical aspects of groundwater flow, including Darcy's law, hydraulic head, hydraulic conductivity, aquifers; 2) describe the basics of groundwater chemistry, including major ions and mean meteoric water line, basics of groundwater contamination; 3) introduce the interface with the oceans, including hydrothermal circulation at mid-ocean ridges, ocean-water intrusion into groundwater at coasts.

The oceanography component will: 1) provide an overview of the physical circulation of the oceans, including its importance for heat transfer around the surface of the Earth and for climate; 2) describe the basic processes that control the chemistry of the oceans, including its temporal and spatial variability; 3) introduce some simple concepts in biological oceanography, including the dependence of ocean ecology on nutrient distributions. There will be a specific focus on how the physics, chemistry and biology of the ocean might have changed through Earth history, and the impact of oceanic processes on Earth's climate.
Lecture notesAvailable
LiteratureTalley, L.D., Pickard, G.L., Emery, W.J. and Swift, J.H. Descriptive Physical Oceanography, an Introduction. (2011) Online textbook, available at http://www.sciencedirect.com/science/book/9780750645522.

Libes, S.M. (2009) Introduction to marine biogeochemistry. 2nd edition. Academic Press
Prerequisites / NoticeChemie I and II, Physik I and II, Mathematik I and II.
651-4049-00LConceptual and Quantitative Methods in Geochemistry
For this course the successful completion of the BSc-course "Geochemistry" (651-3400-00L) is a condition.
3 credits2GO. Bachmann, D. Vance, G. De Souza, A. Hunt, J. Leuthold
AbstractThis course will introduce some of the main quantitative methods available for the quantitative treatment of geochemical data, as well as the main modelling tools. Emphasis will both be on conceptual understanding of these methods as well as on their practical application, using key software packages to analyse real geochemical datasets.
Learning objectiveDevelopment of a basic knowledge and understanding of the main tools available for the quantitative analysis of geochemical data.
ContentThe following approaches will be discussed in detail: major and trace element modelling of magmas, with application to igneous systems; methods and statistics for calculation of isochrons and model ages; reservoir dynamics and one-dimensional modelling of ocean chemistry; modelling speciation in aqueous (hydrothermal, fresh water sea water) fluids.

We will discuss how these methods are applied in a range of Earth Science fields, from cosmochemistry, through mantle and crustal geochemistry, volcanology and igneous petrology, to chemical oceanography.

A special emphasis will be put on dealing with geochemical problems through modeling. Where relevant, software packages will be introduced and applied to real geochemical data.
Lecture notesSlides of lectures will be available.
Prerequisites / NoticePre-requisite: Geochemie I and II
651-4180-02LIntegrated Earth Systems II Restricted registration - show details
Only for Earth Sciences BSc, Programme Regulations 2016.
5 credits4G + 1UD. Vance, H. Stoll, S. Willett
AbstractThe surface Earth is often thought of as a set of interacting systems, often with feedbacks between them. These interacting systems control the tectonics, geomorphology, climate, and biology of the surface Earth. To fully understand the nature of the Earth System, including the controls on its past evolution, its present state, and its future, an integrated perspective is required.
Learning objectiveTo introduce students to an integrated view of the surface Earth, uniting perspectives from different disciplines of the earth sciences.

To encourage students in the critical analysis of data and models in Earth Science.
ContentPlanet Earth has had a complex history since its formation ~4.6 billion years ago. The surface Earth is often thought of as a set of interacting systems, often with positive and negative feedbacks between them. These interacting systems control the tectonics, geomorphology, climate, and biology of the surface Earth. To fully understand the nature of the Earth System, including the controls on its past evolution, its present state, and its future, an integrated perspective is required. This is a subject that pulls in observations and models from many areas of the Earth Sciences, including geochemistry, geophysics, geology and biology. The main goal of the course is to convey this integrated view of the surface of our planet.

We will achieve this integrated view through a series of lectures, exercises, and tutorials. We take as our framework some of the key events in Earth history, encouraging understanding of the controlling processes through integrated observations, ideas and models from disciplines across science.