Climate Models and Observations
Course content
The course will comprise the following elements:
- What is a climate model?
- Observations of climate variations in the recent and deeper past
- Observations of present day climate change (Satellite data as well as ground/ocean based observations).
- Sea level rise (gauge + laser altimetry), measurements /estimates of mass balance of ice sheets.
- Observed and “hind casted” climate of the 20th century. Attribution of climate change.
- Climate projections for coming centuries.
- Future sea level change and its impacts on coasts
MSc Programme in Climate Change
MSc Programme in Physics
The aim of the course is (1) to introduce to the structure and functionality of climate models, (2) to provide an overview of observations of past (proxy) and recent instrumental climate variations, and (3) to give an overview of future climate changes as projected with state of the art climate models, and related changes in sea-level and their impacts. After completing the course the student should be able to
Skills
- Know how a typical climate simulation is performed, basic understanding of which methodologies are used to observe climate in the past and at present
Knowledge
- Understand the design, functionality, and purpose of different climate models
- Be able to describe, in general terms, the observed changes in the climate in the past and at present and be able to attribute these to different climate drivers and through which methods these results are obtained.
-
Be able to describe how ocean and ocean heat content and sea level have risen over the recent past and what methods have been applied to obtain these measures
-
Be able to describe the general future climate changes, globally as well as at regional scale (including sea level rise) as simulated with state of the art climate models
Competences
- Identify the potentials and limitations of climate models
- Be able to apply the relevant scientific terminologies correctly
- Present the results of an analysis or exercise in a well-structured, logical, coherent and scientifically correct form
- Bring together information from observations and models to provide a coherent picture of climate and climate change
- Provide qualified contributions to discussions on climate change mechanisms.
Lectures and theoretical exercises
Will be annouced in Absalon
Awareness of computational languages. The course introduces
programs coded in “R” and Matlab (or similar) to be run on your own
laptop
Academic qualifications equivalent to a BSc degree is
recommended.
- ECTS
- 7,5 ECTS
- Type of assessment
-
Oral examination, 25 minutes
- Type of assessment details
- 25 minutes oral examination in unknown question with 25 minutes preparation time.
- Aid
- All aids allowed
- Marking scale
- 7-point grading scale
- Censorship form
- No external censorship
Several internal examinators.
- Re-exam
-
25 minutes oral examination in unknown question with 25 minutes preparation time.
Criteria for exam assessment
see learning outcome
Single subject courses (day)
- Category
- Hours
- Lectures
- 35
- Preparation
- 128
- Theory exercises
- 42
- Exam
- 1
- English
- 206
Kursusinformation
- Language
- English
- Course number
- NFYK17002U
- ECTS
- 7,5 ECTS
- Programme level
- Full Degree Master
- Duration
-
1 block
- Placement
- Block 2
- Schedulegroup
-
A
- Capacity
- No limitation – unless you register in the late-registration period (BSc and MSc) or as a credit or single subject student.
- Studyboard
- Study Board of Geosciences and Management
Contracting department
- The Niels Bohr Institute
Contracting faculty
- Faculty of Science
Course Coordinator
- Jens Hesselbjerg Christensen (11-6b687676686f656d68756a4371656c316e7831676e)
Teacher
Jens Hesselberg Christensen, DMI, jhc@dmi.dk,
Martin Drews, DTU, mard@dtu.dk
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