Study programme competencies |
Code
|
Study programme competences / results
|
A12 |
Capacidad para la toma de decisiones en un entorno tecnológico donde los materiales se utilicen en aplicaciones de eficiencia |
B1 |
Que los estudiantes sepan aplicar los conocimientos adquiridos y su capacidad de resolución de problemas en entornos nuevos o poco conocidos dentro de contextos más amplios (o multidisciplinares) relacionados con su área de estudio. |
B3 |
Poseer y comprender conocimientos que aporten una base u oportunidad de ser originales en el desarrollo y/o aplicación de ideas, a menudo en un contexto de investigación. |
B9 |
Extraer, interpretar y procesar información, procedente de diferentes fuentes, para su empleo en el estudio y análisis. |
B14 |
Aplicar conocimientos de ciencias y tecnologías avanzadas a la práctica profesional o investigadora de la eficiencia |
B16 |
Valorar la aplicación de tecnologías emergentes en el ámbito de la energía y el medio ambiente. |
C1 |
Adquirir la terminología y nomenclatura científico-técnica para exponer argumentos y fundamentar conclusiones. |
C4 |
Desarrollar el pensamiento crítico |
Learning aims |
Learning outcomes |
Study programme competences / results |
Capacity for decision -making in a technological environment where materials are used in applications efficiency |
AJ12
|
|
|
That the students can apply their knowledge and their ability to solve problems in new or unfamiliar environments within broader (or multidisciplinary ) contexts related to their field of study . |
|
BC1
|
|
Knowledge and understanding that provide a basis or opportunity for originality in developing and / or applying ideas , often in a research context . |
|
BC3
|
|
Extract , interpret and process information from different sources , for use in the study and analysis . |
|
BC9
|
|
Apply knowledge of science and advanced technologies to professional practice or research efficiency |
|
BC14
|
|
Assess the application of emerging technologies in the field of energy and the environment . |
|
BC16
|
|
Acquire scientific and technical terminology and nomenclature to present arguments and justify conclusions. |
|
|
CC1
|
Develop critical thinking |
|
|
CC4
|
Contents |
Topic |
Sub-topic |
1. Introduction to conductive polymers |
1.1 . Concept
1.2 . Properties
1.3 . Preparation and characterization
1.4 . Conductive polymers and environment |
2. Conducting polymers in thermoelectric materials |
2.1 . Concept
2.2 . Properties
2.3 . Energy efficiency estimation
2.4 . Applications |
3. Conducting polymers in light emitting diodes and solar cells |
3.1 . Optoelectronic processes in conducting polymers
3.2 . Organic light emitting diodes: OLED
3.3 . Organic photovoltaic cells
3.4 . Processing of organic optoelectronic devices |
4. Conducting polymers in electrochromic devices |
4.1 . Electrochromic processes in conductive polymers
4.2 . Electrochromic materials
4.2 . Applications |
5. Conducting polymers in batteries |
5.1 . Fuel cells and ion conductive polymers |
Planning |
Methodologies / tests |
Competencies / Results |
Teaching hours (in-person & virtual) |
Student’s personal work hours |
Total hours |
Guest lecture / keynote speech |
B3 B14 C1 C4 |
9 |
0 |
9 |
Supervised projects |
A12 B3 B1 B9 B16 C1 C4 |
1 |
40 |
41 |
Laboratory practice |
B3 B1 B9 C1 C4 |
12 |
1 |
13 |
Objective test |
C1 C4 |
1 |
10 |
11 |
|
Personalized attention |
|
1 |
0 |
1 |
|
(*)The information in the planning table is for guidance only and does not take into account the heterogeneity of the students. |
Methodologies |
Methodologies |
Description |
Guest lecture / keynote speech |
Oral presentation supported by audiovisual media with the inclusion of some questions for students, to provide knowledge and to facilitate learning. |
Supervised projects |
Methodology is designed to promote autonomous learning of students in different environments (academic or more professional environment) under the guidance of a teacher. It refers mainly to learning "how to do things." In this option, students must assume the responsibility for their own learning. |
Laboratory practice |
This methodology allows that students learn effectively doing practical activities, such as demonstrations, exercises, lab work and researches |
Objective test |
This test will consist of a written exam with multiple choice questions. |
Personalized attention |
Methodologies
|
Laboratory practice |
Supervised projects |
|
Description |
Each student must perform autonomously a work. The teacher will guide them by individual tutoring.
The students will do three sessions of lab work where they will work concepts related to the energy efficiency in conducting polymers.
|
|
Assessment |
Methodologies
|
Competencies / Results |
Description
|
Qualification
|
Laboratory practice |
B3 B1 B9 C1 C4 |
The student will perform three laboratory practices related to energy efficiency of conductive polymers .The skills acquired in the laboratory and the report submitted will be evaluated . |
30 |
Supervised projects |
A12 B3 B1 B9 B16 C1 C4 |
Students will do individual work on a topic related to conductive polymers to be delivered and presented to other students . Both will be evaluated. |
40 |
Objective test |
C1 C4 |
It will perform a test on -line where the acquired concepts are evaluated. |
30 |
|
Assessment comments |
Students who accumulate more than 20% of unexcused absences are excluded from the process of continuous evaluation , so that evaluation does not correspond to the table above. For these students the evaluation will be conducted by an objective test with different types of questions (multiple, management , short resposta , discrimination , completing e / ou association ) and a working case study where it poses students a real situation of professional life . The rating is 50% objective and 50% test case study .
|
Sources of information |
Basic
|
Yasuhiko Shirota and Hiroshi Kageyama (). Charge Carrier Transporting Molecular Materials and Their Applications in Devices. Chem. Rev. 2007, 107, 953-1010
Pierre M. Beaujuge and John R. Reynolds (). Color Control in ?-Conjugated Organic Polymers for Use in Electrochromic Devices. Chem. Rev. 2010, 110, 268–320
Petr Novák; Klaus Müller; K. S. V. Santhanam and Otto Haas (). Electrochemically Active Polymers for Rechargeable Batteries. Chem. Rev. 1997, 97, 207-281
K. Walzer, B. Maennig, M. Pfeiffer, and K. Leo (). Highly Efficient Organic Devices Based on Electrically Doped Transport Layers. Chem. Rev. 2007, 107, 1233-1271
Javier Padilla Martínez; Rafael Garcia Valverde; Antonio Jesús Fernández Romero y Antonio Urbina Yer (). Polímeros conductores. Su papel en un desarrollo energético sostenible. Editorial Reverté
Sambhu Bhadraa; Dipak Khastgir; Nikhil K. Singhaa and Joong Hee Lee (). Progress in preparation, processing and applications of polyaniline. Progress in Polymer Science 34 (2009) 783–810
Yong Dua, Shirley Z. Shenb, Kefeng Caia, Philip S. Casey (). Research progress on polymer–inorganic thermoelectric nanocomposite materials. Progress in Polymer Science 37 (2012) 820– 841
Alan J. Heeger (). Semiconducting and Metallic Polymers: The Fourth Generation of Polymeric Materials. Angew. Chem. Int. Ed. 2001, 40, 2591 - 2611
Hideki Shirakawa (). The Discovery of Polyacetylene Film: The Dawning of an Era of Conducting Polymers. Angew. Chem. Int. Ed. 2001, 40, 2574 - 2580
Olga Bubnova and Xavier Crispin (). Towards polymer-based organic thermoelectric generators. Energy & Environmental Science 2012, 5, 9345-9362
Alan G. MacDiarmid (). ªSynthetic Metalsº: A Novel Role for Organic Polymers. Angew. Chem. Int. Ed. 2001, 40, 2581 - 2590 |
|
Complementary
|
|
|
Recommendations |
Subjects that it is recommended to have taken before |
|
Subjects that are recommended to be taken simultaneously |
|
Subjects that continue the syllabus |
|
|