Last modified: 23 Jul 2024 10:43
Data sets derived from remote sensing, meteorites and samples retrieved from the Lunar surface will be integrated to inform understanding of geological processes that play within and upon the surface of terrestrial planets. This course will develop essential geologically based reasoning skills through diverse data sets, building upon and contributing to the students’ wider understanding of Planetary Sciences.
Study Type | Postgraduate | Level | 5 |
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Term | Second Term | Credit Points | 15 credits (7.5 ECTS credits) |
Campus | Aberdeen | Sustained Study | No |
Co-ordinators |
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This course will concentrate on the Terrestrial planets and their satellites (Earth’s Moon, Mars, Venus & Mercury) and their meteorite record. The internal structure of planets is best interrogated by geophysical processes, although the geophysical record is sketchy for the Terrestrial planets. However, the composition age and distribution of volcanic and associated rocks act as a probe for our understanding of internal planetary processes as well as providing and insight into surface processes. For Earth’s Moon there are significant observational and analytical data sets derived from the Apollo landings of the 1960s and 1970s and more recent lunar probes. Whilst it is 50 years since materials were collected during the Apollo missions, our understanding of the evolution of the Earth and Moon has improved dramatically largely because new analytical technologies allow non-destructive, very high-precision chemical and mineralogical analysis. The surface rocks of Mars have been interrogated by in situ mineralogical analysis. For the other terrestrial planets, we rely mainly on meteorite samples and remote sensing technologies to understand their internal and surface geology respectively.
Information on contact teaching time is available from the course guide.
Assessment Type | Summative | Weighting | 40 | |
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Assessment Weeks | Feedback Weeks | |||
Feedback |
Assessment component C Students will be directed to, or choose their own primary sources of data. From these data they will be expected to make their own interpretations and conclusions. Students will be expected to find their own examples of comparative materials from primary sources and document them, taking advantage of a wealth of remote sensing tools online that make this possible. These findings will then be put into context of the published literature. Feedback will be provided following the format used in reviews of paper as per International Journal. Assessment- End of course, so after feedback on first two exercises, whichever is earlier. Feedback - End of course |
Knowledge Level | Thinking Skill | Outcome |
---|---|---|
Procedural | Create | Enhance visual presentation skills. |
Procedural | Create | Development of integrated geological histories linked to internal and surficial earth processes. |
Reflection | Create | Enhancement of critical thinking and reasoning skills. |
Reflection | Create | Challenging published geological investigations and interpretations against one’s own observations and deductions. |
Assessment Type | Summative | Weighting | 20 | |
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Assessment Weeks | Feedback Weeks | |||
Feedback |
Assessment component A Examination and interrogation of geochemical data on lunar rocks and integration with remote sensing data. The exercises include plotting and interpreting geochemical data in order to make conclusions about the petrogenesis of Lunar rocks. Lab book with exercises submitted online. Individual feedback online, general in tutorials. Examination and interrogation of geochemical data on lunar rocks and integration with remote sensing data. The exercises include plotting and interpreting geochemical data in order to make conclusions about the petrogenesis of Lunar rocks.
Assessment - week 3 of 2nd sub-session Feedback - week 4 of 2nd sub-session |
Knowledge Level | Thinking Skill | Outcome |
---|---|---|
Conceptual | Apply | Planning and executing focused investigation of geological outcrops and regions |
Conceptual | Apply | Enhance knowledge of geological concepts |
Conceptual | Evaluate | Integration of diverse earth science information. |
Factual | Understand | Consolidation of geological field and laboratory skills. |
Reflection | Create | Enhancement of critical thinking and reasoning skills. |
Assessment Type | Formative | Weighting | 40 | |
---|---|---|---|---|
Assessment Weeks | Feedback Weeks | |||
Feedback |
Assessment component B Students will be directed to, or choose their own primary sources of data. From these data they will be expected to make their own interpretations and conclusions. It is expected that students will make use of the data that is provided in component A, but to expand the interpretations from the simple exercises into a publishable format. Feedback will follow format of a review of paper as per International Journal. Assessment - week 5 of 2nd sub-session Feedback - week 7 of 2nd sub-session |
Knowledge Level | Thinking Skill | Outcome |
---|---|---|
Conceptual | Apply | Planning and executing focused investigation of geological outcrops and regions |
Conceptual | Apply | Enhance knowledge of geological concepts |
Conceptual | Evaluate | Integration of diverse earth science information. |
Factual | Understand | Consolidation of geological field and laboratory skills. |
Reflection | Create | Enhancement of critical thinking and reasoning skills. |
Assessment Type | Summative | Weighting | 100 | |
---|---|---|---|---|
Assessment Weeks | Feedback Weeks | |||
Feedback |
Original element weighting |
Knowledge Level | Thinking Skill | Outcome |
---|---|---|
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Knowledge Level | Thinking Skill | Outcome |
---|---|---|
Factual | Understand | Consolidation of geological field and laboratory skills. |
Reflection | Create | Enhancement of critical thinking and reasoning skills. |
Conceptual | Apply | Planning and executing focused investigation of geological outcrops and regions |
Reflection | Create | Challenging published geological investigations and interpretations against one’s own observations and deductions. |
Procedural | Create | Development of integrated geological histories linked to internal and surficial earth processes. |
Conceptual | Apply | Enhance knowledge of geological concepts |
Procedural | Create | Enhance visual presentation skills. |
Conceptual | Evaluate | Integration of diverse earth science information. |
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