Module manager: Dr Gavin Burnell
Email: G.Burnell@leeds.ac.uk
Taught: Semesters 1 & 2 (Sep to Jun) View Timetable
Year running 2024/25
| PHYS3001 | Advanced Techniques in Experimental Physics |
| PHYS3003 | Advanced Techniques in Theoretical Physics |
| PHYS3004 | Advanced Techniques in Physics (Joint Honours) |
| PHYS3152 | Project |
| PHYS3160 | Physics Project (Jh) |
This would replace PHYS3777 on the above programmes.
This module is not approved as a discovery module
The ability to apply physical understanding and higher level problem solving skills to the processes in designing and carrying out experimental studies is essential for both higher level academic study in applied and experimental sciences and to many professional careers for astrophysicists. This module forms the bridge between the first and second year laboratory physics and astrophysics courses and the research focussed, open-ended projects of the 4th year Astrophysics programmes. In this module, students carry out extended, open-ended studies using techniques common place in the Astrophysics research group’s research programmes to hone skills in data handling and analysis. An optional opportunity for observational fieldwork will be provided where feasible.
This module will give the students and increased awareness of skills required in preparing, conducting, analysing and interpreting of a wide range of advanced astronomical observational techniques and data sets through the use of appropriate measurement, data analysis and statistical approaches and to communicate and defend their work in a variety of professional contexts.
On successful completion of the module students will be able to:
1. Perform or evaluate advanced astrophysical experiments using high-tech experimental and analytical techniques.
2. Explain and apply a range of experimental, statistical and computational analytical techniques to data.
3. Develop problem solving skills and practical approaches to troubleshooting calculations and simulations and time management, planning and delivering work to deadlines.
4. Deliver presentations including scientific concepts, results and methodology s and answer related questions.
5. Present scientific concepts, results and methodology in extended formal scientific English with illustrations and figures and references to literature sources as necessary
6. Communicate complex concepts succinctly and coherently, defend results and methodology and answer related questions in one-to-one situations.
Each student undertakes 3 "mini-projects" of 3 weeks from a list of appropriate techniques to astrophysics. When available, students may choose to substitute one mini-poroject studied during semester time with an approved fieldwork experiment normally taken prior to semester 1.
The list of potential projects reflects the research activity in the Astrophysics Research Group in the School of Physics and Astronomy, a typical list would include the following: Nebular Spectroscopy, Stellar Clusters, Radio Interferometry.
| Delivery type | Number | Length hours | Student hours |
|---|---|---|---|
| Lecture | 4 | 2 | 8 |
| Practical | 2 | 48 | 144 |
| Private study hours | 148 | ||
| Total Contact hours | 152 | ||
| Total hours (100hr per 10 credits) | 300 | ||
Regular meetings with mini-project supervisors and demonstrators and discussion of interim results.
| Assessment type | Notes | % of formal assessment |
|---|---|---|
| Report | Formal Report | 25 |
| Presentation | Presentations | 15 |
| Practical | Mini-projects | 45 |
| Viva | Viva | 15 |
| Total percentage (Assessment Coursework) | 100 | |
Students must submit a serious attempt at all assessments, in order to pass the module overall.
There is no reading list for this module
Last updated: 4/29/2024
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