Language of instruction : English |
Sequentiality
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No sequentiality
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| Degree programme | | Study hours | Credits | P2 SBU | P2 SP | 2nd Chance Exam1 | Tolerance2 | Final grade3 | |
| 1st year Master of Materiomics | Compulsory | 108 | 4,0 | 108 | 4,0 | Yes | Yes | Numerical | |
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| Learning outcomes |
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| EC 2. The master of Materiomics can combine chemical and physical principles enabling the discovery of new material concepts based on an interdisciplinary approach. | | - DC
| DC2.5 The student has knowledge of physical concepts and methods. [learning pathway interdisciplinarity - identification: the students knows which phenomena are studied in the various disciplines and which methods and theories are used] | | - DC
| DC2.6 The student is able to relate chemical and physical concepts and methods to each other to understand materials. [learning pathway interdisciplinarity - coordination: the student is able to make connections between different perspectives] | | - DC
| DC2.3 The student is able to devise and examine a new materials concept, taking into account sustainability aspects. | - EC
| EC 4. The master of Materiomics is able to autonomously consult, summarize and critically interpret international scientific literature, reference it correctly and use it to explore and identify new domains relevant to the field. | | - DC
| DC4.3 The student is able to critically interpret, evaluate, compare, and/or summarize relevant scientific literature related to materials-related problems or research questions. | - EC
| EC 6. The master of Materiomics is able to communicate in both written and spoken form and to take a well-argued position in a scientific discussion, going from a general to a specialist level, adapted to the target audience. | | - DC
| DC6.2 The student is able to adapt to the purpose and target audience of the communication, i.e., can empathize with the target audience and make appropriate choices regarding language use and format. | - EC
| EC 8. The master of Materiomics is able to act with integrity and independently judge ethical and societal implications of scientific developments in one’s domain with particular attention to sustainability. | | - DC
| DC8.1 The student is able to explain the basic principles of sustainability. |
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| EC = learning outcomes DC = partial outcomes BC = evaluation criteria |
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The course 'Sustainable materials and energy' has the following learning objectives:
- the student is able to get insight into energy as a general concept and its relationship with atom efficiency in the context of sustainable materials and energy
- the student is able to understand how green and circular chemistry (based on 12 principles of green chemistry and 10 principles of circular chemistry) can contribute to novel developments in sustainable materials, devices, and energy conversion and storage processes
- the student is able to use standard methodology to evaluate the life cycle and sustainability of a material or energy process and is able to compare and interpret those results on a system level
- the student has the knowledge of methodologies to incorporate "end-of-life" concepts to be applied in sustainable materials
Module 1: introduction sustainability
- a general introduction starting from energy as a physical concept, energy conversion and energy requirement and supply in the context of the global sustainablility challenge and the circularity of materials
- sustainability as concept, sustainable development goals (SDG’s), 3P and genest 3P model, donut economy, definition of wicked problems
- 12 principles of green chemistry and 10 principles of circular economy and their applications
- system thinking and stakeholder analysis
Module 2: life cycle analysis (LCA)
- introduction LCA, with emphasis on different LCA methodologies and conditions
- the role of LCA in evaluation of sustainable materials and energy
Module 3: case studies and debate
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overview of energy technologies and renewable materials with emphasis on sustainability challenge
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state of the art
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emerging developments
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seminar series with the link to the 12 principles of green chemistry and 10 principles of circular economy
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Case session ✔
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Lecture ✔
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Response lecture ✔
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Self-study assignment ✔
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Small group session ✔
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Discussion/debate ✔
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Exercises ✔
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mini-essay ✔
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Seminar ✔
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Period 2 Credits 4,00
Evaluation method | |
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Written evaluaton during teaching periode | 30 % |
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Transfer of partial marks within the academic year | ✔ |
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Conditions transfer of partial marks within the academic year | The student obtains at least 10/20. |
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Oral evaluation during teaching period | 10 % |
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Transfer of partial marks within the academic year | ✔ |
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Written exam | 60 % |
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Transfer of partial marks within the academic year | ✔ |
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Conditions transfer of partial marks within the academic year | The student obtains at least 10/20. |
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Evaluation conditions (participation and/or pass) | ✔ |
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Conditions | The student is required to be present and to have actively contributed to the debate as evaluation is linked to this.The student is required to submit the mini-essay. |
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Consequences | If the student is unjustifiedly absent during the debate or did not submit the mini-essay, he/she will receive an 'N' for the entire course as a final result ('N' = evaluation not fully completed: unjustified absence for one or more components of the evaluation). |
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Second examination period
Evaluation second examination opportunity different from first examination opprt | |
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Explanation (English) | The mini-essay and written exam can be retaken. The debate cannot be retaken. |
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Prerequisites |
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The prerequisites that the student needs to have before choosing this course are:
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basic knowledge organic chemistry and polymer chemistry
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basic knowledge thermodynamics and chemical kinetics
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basic knowledge electrochemistry
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basis knowledge electronics
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basis knowledge solid state physics
The student has some experience with presentation and communication skills (basic level) |
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Compulsory course material |
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All slides, readers, papers and other supporting materials will be provided on blackboard. |
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Recommended reading |
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- Environmental Physics,Egbert Boeker, Rienk Van Grondelle,Wiley,9780470666753
- Fundamentals of Materials for Energy and Environmental Sustainability,David S. Ginley & David Cahen,Cambridge University Press,1107000238
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1 examination regulations art.1.3, section 4. |
2 examination regulations art.4.7, section 2. |
3 examination regulations art.2.2, section 3.
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Legend |
SBU : course load | SP : ECTS | N : Dutch | E : English |
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