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- GEOL1001 Earth Materials
- GEOL1002 From Petrology to Petrogenesis
- GEOL1003 History of Life
- GEOL1004 Dynamic Earth
- GEOL1006 Foundations of Physical Geoscience
- GEOL1012 Surface Processes
- GEOL1013 The Earth
- GEOL1014 Geochemistry
- GEOL1015 Geology of Planetary Bodies
- GEOL2004 Chemistry of Earth Environments
- GEOL2008 Vertebrate Palaeontology and Evolution
- GEOL2009 Surface Processes & Structures
- GEOL2010 Igneous Petrology
- GEOL2012 Metamorphism
- GEOL2014 Global Geophysics
- GEOL2016 Atmosphere, Weather & Climate
- GEOL2010 Igneous Petrology
- GEOL2026 Maps, Images and Structures
- GEOL2027 Structural Geology and Tectonics
- GEOL3003 Geodynamics & Global Tectonics
- GEOL3011 Geosciences Report
- GEOL3030 Field Methods in Active Tectonics
- GEOL3036 Biodiversity and Macroevolutionary Patterns
- GEOL3038 Experimental Methods in Water-Rock Interaction
- GEOL3039 Physics of Oceans, Ice Sheets and Climate
- GEOL3040 Crustal Dynamics, Mountain Building & Basin Evolution
- GEOL3042 Geological/Environmental Mapping Project
- GEOL3043 Earth Resources & Sustainability
- GEOLM002 Earthquake Seismology & Earthquake Hazards
- GEOLM003 Earth & Planetary System Science
- GEOLM006 Earth & Planetary Materials
- GEOLM008 Physical Volcanology & Volcanic Hazard
- GEOLM010 Tectonic Geomorphology
- GEOLM012 Palaeoclimatology
- GEOLM018 Palaeoceanography
- GEOLM021 Melting and Volcanism
- GEOLM022 Hydrogeology and Groundwater Resources
- GEOLM037 Deep Earth & Planetary Modelling
- GEOLM905 Independent MSci Project
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GEOLM018 Palaeoceanography
AIMS
To introduce key principles of oceanography, the proxies used for palaeoceanography and the history and evolution of Cretaceous to Recent oceans, through case studies.
OUTCOMES
Knowledge of:
- temperature and productivity of the oceans;
- controls on biogenic sedimentation;
- the development and history of oceanic circulation;
- understanding of analytical techniques used to obtain that knowledge.
CONTENT
Ocean basin structure and marine sediments; General circulation of the oceans; wind driven and thermohaline circulation; Primary production, nutrients and the marine carbon cycle; Life in the oceans; Micropalaeontological and geochemical proxies for temperature, productivity, weathering and circulation; Pre-Cenozoic palaeoceanography, including 'oceanic anoxic events'; K/T boundary; Early Cenozoic warmth and hyperthermals; the transition from the Greenhouse to the Icehouse world,'; fluctuations in climate and ice volume in the Neogene; the glacial world.
| Title |
Palaeoceanography |
| UG Code |
GEOLM018 |
| Coordinator |
Dr Stuart Robinson |
| Other Contributors |
Various |
| Term |
1 |
| Credit | 0.5 CU |
| Written Exam |
60% |
| Coursework |
40% |
| Pre-Requisites |
None |
| Maths & Stats Content and Requirement | |
| Total Number of Hours of Student Work | 188 hours |
| Hours of Lectures/Seminars | 40 (4 hours per week) hours |
| Hours of Practicals/Problem Classes | 20 hours |
| Hours of Tutorials |
As needed to do the essay and practical assignments |
| Days of Fieldwork | 0 |
| Other | Occasional seminars by guest lecturers (Optional). Students also give 10-min oral presentations of their Essay topics |
 Annual Monitoring |
download pdf |
| Categorizing Student Performance Levels |
download pdf |
|
Moodle page |
Moodle page |
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