- UCAS course code
- HHH6
- UCAS institution code
- M20
Master of Engineering (MEng)
MEng Mechatronic Engineering
Explore the world of robotics and gain the UK's top engineering undergraduate award, securing the base for chartered status.
- Typical A-level offer: AAA including specific subjects
- Typical contextual A-level offer: AAB including specific subjects
- Refugee/care-experienced offer: ABB including specific subjects
- Typical International Baccalaureate offer: 36 points overall with 6,6,6 at HL, including specific requirements
Fees and funding
Fees
Tuition fees for home students commencing their studies in September 2025 will be £9,535 per annum (subject to Parliamentary approval). Tuition fees for international students will be £34,000 per annum. For general information please see the undergraduate finance pages.
Policy on additional costs
All students should normally be able to complete their programme of study without incurring additional study costs over and above the tuition fee for that programme. Any unavoidable additional compulsory costs totalling more than 1% of the annual home undergraduate fee per annum, regardless of whether the programme in question is undergraduate or postgraduate taught, will be made clear to you at the point of application. Further information can be found in the University's Policy on additional costs incurred by students on undergraduate and postgraduate taught programmes (PDF document, 91KB).
Scholarships/sponsorships
For information about scholarships and bursaries please visit our undergraduate student finance pages and our Department funding pages .
Course unit details:
Solar Energy Technologies
Unit code | EEEN40421 |
---|---|
Credit rating | 15 |
Unit level | Level 4 |
Teaching period(s) | Semester 1 |
Available as a free choice unit? | No |
Overview
This unit deals with the renewable energy systems which directly exploit the solar radiation received by the earth viz. solar photovoltaics (PV), solar thermal technologies. Solar PV devices are broadly divided into three types: type I crystalline semiconductor based cells (including concentrator cells); type III device based on large area, low cost thin films and type III structures which aim to exploit fundamental physics in order to overcome the various energy loss mechanisms suffered in type I and type II devices. PV devices yield electrical energy directly whereas solar thermal technologies involve the direct absorption of sunlight and its conversion to heat or for electrical power generation. The unit describes the fundamental mechanisms of solar energy conversion on solar cells, identifying the device properties that lead to that solar absorption and charge separation which delivers the electrical energy. This establishes the key criteria for cell design and improvement. Underpinning all of these device structures is the need to ramp up efficiency and so the routes to extracting optimal power and the factors which limit PV cell efficiency are covered. The optical and thermal parameters for solar thermal technologies are considered and the approaches for generating electrical power are reviewed. The exploitation of these renewable energy systems in both large scale power plants and in the urban, built infrastructure is considered.
Aims
The unit aims to:
Provide understanding of the science and engineering issues related to the design and development of renewable energy devices and systems for generating electricity from solar resources.
Learning outcomes
On the successful completion of the course, students will be able to:
ILO 1 - Describe and quantify the solar energy resource available for electricity generation using both PV and solar thermal systems
ILO 2 - Describe the fundamental material and device characteristics which enable all PV cells to convert solar energy into electrical energy
ILO 3 - Describe the manufacturing and processing issues which impact upon the final performance and durability of PV cells
ILO 4 - Describe the fundamental properties and design characteristics of Concentrated Solar (thermal) Power (CSP) plants
ILO 5 - Apply scientific and mathematical analysis to the design and optimisation of materials and devices for PV and solar thermal systems.
ILO 6 - Conduct laboratory experiments to realise a solar cell and measure its electrical output characteristics to determine the power conversion efficiency.
Teaching and learning methods
Traditional lectures, laboratory session (assessed via technical report), in-class practical session (not assessed) and tutorial session(s)
Assessment methods
Method | Weight |
---|---|
Other | 20% |
Written exam | 80% |
Coursework 1: Online multiple choice quiz (10%)
Duration: 1 hour
Coursework 2: Individual Report (10%)
15 pages (max)
Coursework feedback is provided online in Blackboard
Study hours
Scheduled activity hours | |
---|---|
Lectures | 30 |
Practical classes & workshops | 9 |
Tutorials | 6 |
Independent study hours | |
---|---|
Independent study | 105 |
Teaching staff
Staff member | Role |
---|---|
Matthew Halsall | Unit coordinator |