Last modified: 23 Jul 2024 11:03
This course gives students an introduction and overview of energy transition, by focussing on the three key areas of demand, technology and economics. It begins with an introduction to the current energy system and the motivation for an energy transition. There follows a characterisation of the key drivers that underpin our social and economic reliance on energy. Subsequently, behavioural measures and technologies to enable the energy transition are examined and assessed according to diverse technical, economic and environmental criteria.
| Study Type | Postgraduate | Level | 5 |
|---|---|---|---|
| Term | First Term | Credit Points | 15 credits (7.5 ECTS credits) |
| Campus | Aberdeen | Sustained Study | No |
| Co-ordinators |
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This course covers the subject of energy transition from an engineering-economic perspective. It starts by way of introduction with an overview of the current energy system, with some prominent international examples. The course then moves on to explore the underlying drivers that influence our demand for energy, or energy service demands (ESD). ESDs are the services that energy fulfils for consumers, for example travelling 100 km or heating a home to a comfortable temperature. Only by understanding ESDs is it possible to understand the possibilities to increase the sustainability and/or efficiency of the energy system.
After this introduction, the core of the course is devoted to the measures and technologies to enable an energy transition, from today’s unsustainable system to a future sustainable one. Firstly different types of measures such as demand reduction/energy efficiency and renewable energy are assessed in a framework of priority according to their relative cost and feasibility. Subsequently, the individual measures and technologies are presented in detail, involving an explanation of their technical characteristics as well as economic and environmental characterisation.
Once the individual technologies and measures have been introduced, they are evaluated and compared to one another based on multiple criteria. This provides students with an understanding of the respective advantages and disadvantages of these technologies. This also includes a classification according to Technology Readiness Level (TRL) and an outlook for future developments.
The final part of the course is devoted to the system perspective and addresses some of the engineering, economic and policy challenges associated with the energy transition. Examples include the integration of fluctuating renewable energies, the requirement to subsidize nascent technologies and the often-encountered barriers that lead to the so called “energy efficiency gap” – the gap between what is economically feasible and the level of uptake seen in practice.
Overall, this course is intended as in an introduction and overview to the whole MSc Programme, introducing many of the topics and methods from the later courses, and preparing students for these courses and their coursework assignments
| Assessment Type | Summative | Weighting | 80 | |
|---|---|---|---|---|
| Assessment Weeks | 19,20 | Feedback Weeks | 23,24,25 | |
| Feedback | ||||
| Knowledge Level | Thinking Skill | Outcome |
|---|---|---|
| Conceptual | Understand | Students should understand the concept of energy transition the diverse motivation for it and the complex nature of the challenge. |
| Factual | Remember | Students should know how todays energy system is structured, what contribution it makes to local and global emissions, and the link this has to the energy transition. |
| Procedural | Analyse | Students should analyse the potential contribution of different technologies towards emissions abatement and/or energy saving/generation in the context of the energy transition |
| Procedural | Apply | Students should apply the concepts of levelized costs of energy (LCOE), emissions abatement costs and related metrics in order assess different emissions abatement measures and technologies. |
| Reflection | Evaluate | Students should evaluate a realistic energy system in the context of the energy transition and prioritize measures and technologies based on technical feasibility and cost. |
| Assessment Type | Summative | Weighting | 20 | |
|---|---|---|---|---|
| Assessment Weeks | Feedback Weeks | |||
| Feedback | ||||
| Knowledge Level | Thinking Skill | Outcome |
|---|---|---|
| Conceptual | Understand | Students should understand the concept of energy transition the diverse motivation for it and the complex nature of the challenge. |
| Factual | Remember | Students should know how todays energy system is structured, what contribution it makes to local and global emissions, and the link this has to the energy transition. |
| Procedural | Analyse | Students should analyse the potential contribution of different technologies towards emissions abatement and/or energy saving/generation in the context of the energy transition |
| Procedural | Apply | Students should apply the concepts of levelized costs of energy (LCOE), emissions abatement costs and related metrics in order assess different emissions abatement measures and technologies. |
| Reflection | Evaluate | Students should evaluate a realistic energy system in the context of the energy transition and prioritize measures and technologies based on technical feasibility and cost. |
There are no assessments for this course.
| Assessment Type | Summative | Weighting | 100 | |
|---|---|---|---|---|
| Assessment Weeks | 48,49 | Feedback Weeks | 50,51,52 | |
| Feedback |
Written feedback to the group. Individual verbal feedback only upon request.
Online learning students can sit exam in Aberdeen, so a space should be allocated in the Aberdeen exam venue. However, students also sit exam at any other approved venue (i.e. British Council or another approved University) |
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| Knowledge Level | Thinking Skill | Outcome |
|---|---|---|
| Conceptual | Understand | Students should understand the concept of energy transition the diverse motivation for it and the complex nature of the challenge. |
| Factual | Remember | Students should know how todays energy system is structured, what contribution it makes to local and global emissions, and the link this has to the energy transition. |
| Procedural | Analyse | Students should analyse the potential contribution of different technologies towards emissions abatement and/or energy saving/generation in the context of the energy transition |
| Procedural | Apply | Students should apply the concepts of levelized costs of energy (LCOE), emissions abatement costs and related metrics in order assess different emissions abatement measures and technologies. |
| Reflection | Evaluate | Students should evaluate a realistic energy system in the context of the energy transition and prioritize measures and technologies based on technical feasibility and cost. |
| Knowledge Level | Thinking Skill | Outcome |
|---|---|---|
| Conceptual | Understand | Students should understand the concept of energy transition the diverse motivation for it and the complex nature of the challenge. |
| Procedural | Apply | Students should apply the concepts of levelized costs of energy (LCOE), emissions abatement costs and related metrics in order assess different emissions abatement measures and technologies. |
| Factual | Remember | Students should know how todays energy system is structured, what contribution it makes to local and global emissions, and the link this has to the energy transition. |
| Reflection | Evaluate | Students should evaluate a realistic energy system in the context of the energy transition and prioritize measures and technologies based on technical feasibility and cost. |
| Procedural | Analyse | Students should analyse the potential contribution of different technologies towards emissions abatement and/or energy saving/generation in the context of the energy transition |
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