CODE 108099 ACADEMIC YEAR 2024/2025 CREDITS 6 cfu anno 2 SCIENZA E TECNOLOGIA DEI MATERIALI 11430 (LM SC.MAT.) - GENOVA 5 cfu anno 2 INGEGNERIA CHIMICA E DI PROCESSO 10376 (LM-22) - GENOVA 6 cfu anno 1 SCIENZA E TECNOLOGIA DEI MATERIALI 11430 (LM SC.MAT.) - GENOVA SCIENTIFIC DISCIPLINARY SECTOR ING-IND/23 LANGUAGE Italian TEACHING LOCATION GENOVA SEMESTER 1° Semester TEACHING MATERIALS AULAWEB OVERVIEW The course is proposed as particularly suitable for the "Materials Scientist: Technology Specialist" profile or in the framework of the training of Chemical and Process Engineering. AIMS AND CONTENT LEARNING OUTCOMES The course aims to introduce students to the issues of the current context of energy transition. In this scenario, attention will be focused on "power to gas" and "gas to power" electrochemical technologies studied through chemical-physical models applied on different phenomenological scales, highlighting the relevance of microscopic properties on macroscopic performance in a scale- industrial up. AIMS AND LEARNING OUTCOMES Participation in the proposed training activities (lectures, exercises, visits, seminars), individual study and group discussion will allow the student to: - orient himself in the current context of energy transition (environmental constraints, green technologies, renewable resources, hydrogen carrier, state of the art and potential developments, ...) - know the main types of electrochemical cells, their potential and the related optimization margins both for the production of energy and for its storage in the form of hydrogen or syngas; - know the fundamentals of operation of electrochemical cells by discriminating processes, properties and chemical-physical constraints that govern them (electrochemical kinetics, material and energy transport phenomena, material characteristics, ...). - learn how to set up simulation models of electrochemical cells by discriminating the phenomenological scale of interest and the relative correlations with the other scales (from the cell components up to the plant) - gain experience in computer simulation, using commercial or open-source software integrated with ad hoc written codes, for design, predictive, diagnostic or control purposes - learn how to manage experimental data and design a preliminary design of experiment for the validation of models and the identification of chemical-physical parameters - apply the acquired skills to specific contexts of environmental engineering, discussing the advantages and disadvantages of the applicable solutions and estimating the main performance indexes and environmental impact. PREREQUISITES For successful learning, basic knowledge of mathematical analysis, chemistry and physics is required. No formal propaedeutics are envisaged. TEACHING METHODS The teaching includes face-to-face lessons in the classroom. The presentation of theoretical contents is alternated with lessons with computer exercises to encourage learning and discussion of specific application examples. Supplementary activities such as educational visits or seminars may also be proposed. Transversal skills in terms of communication and independent judgment will be acquired through the discussion of concrete examples of complex problems. SYLLABUS/CONTENT The program of the teaching includes the presentation and discussion of the following topics: 1. Contextualizing the energy transition - The environmental problem - Sources and technologies for energy production - The hydrogen carrier - Role of chemical-physical models 2. Types of electrochemical cells - Characteristics: materials, reactions, configurations, performances. - Applications: in "Gas to Power" and "Power to Gas" modes (fuel cells and electrolysers) - State of art 3. Operation of electrochemical cells - Thermodynamics and kinetics (Nernst, Butler Volmer, Faraday, polarization contributions, …) - Macroscopic and local balances of material and energy - Key Performance Parameters and Environmental Impact Indicators 3. Modelling - Setting up of the equations describing the processes of interest on different phenomenological scales (from the cell components to the plant system) - Main simulation tools: programming logics and software - Computer exercises 4. Model validation - Processing and interpretation of experimental data - Identification of chemical-physical parameters - Design of experiments 6. Supplementary activities - Visit to the CapLab - Electrochemical Cells for Carbon Capture and Energy Transistion laboratory (joint laboratory of the University of Genoa - EcoSpray Technologies) - Seminar by insdustry experts or professors of other universities - Educational visits to related research or industrial realities. RECOMMENDED READING/BIBLIOGRAPHY The teaching material used during the lessons will be available on Aulaweb. The notes taken during the lessons and the material in Aulaweb are sufficient for the preparation of the exam. Some texts will be suggested in class for further study. TEACHERS AND EXAM BOARD BARBARA BOSIO Ricevimento: On request, by email appointment (barbara.bosio@unige.it) Exam Board BARBARA BOSIO (President) CRISTINA ELIA MOLINER ESTOPIÑAN ELISABETTA ARATO (President Substitute) LESSONS LESSONS START Lessons will start in accordance with the calendar proposed by the School of Mathematical, Physical and Natural Sciences https://corsi.unige.it/corsi/10375/studenti-orario Class schedule The timetable for this course is available here: Portale EasyAcademy EXAMS EXAM DESCRIPTION During the course, students will be asked to prepare a paper relating to a specific application to be presented at the final exam which will consist of an oral test. There will be 2 exam sessions available for the 'winter' session (January and February) and 3 exam sessions for the 'summer' session (June, July, September). Furthermore, the test can also be taken during any teaching breaks scheduled in autumn and spring. ASSESSMENT METHODS The oral exam includes the discussion of the prepared report and a couple of questions that may concern the entire program presented in class, formulated in terms of theoretical questions or in the form of application problems. The exam aims to ascertain the specific skills acquired and above all the ability to use them combined together to orient themselves in concrete applicative cases. The quality of the presentation, the correct use of technical terminology and the ability to critical reasoning will also be evaluated. Exam schedule Data appello Orario Luogo Degree type Note 15/01/2025 09:00 GENOVA Orale Aula B6 31/01/2025 09:00 GENOVA Orale 07/02/2025 09:00 GENOVA Orale Aula B16 04/06/2025 09:00 GENOVA Orale 16/06/2025 09:00 GENOVA Orale 19/06/2025 09:00 GENOVA Orale 14/07/2025 09:00 GENOVA Orale 17/07/2025 09:00 GENOVA Orale 12/09/2025 09:00 GENOVA Orale 19/09/2025 09:00 GENOVA Orale FURTHER INFORMATION Students who have valid certification of physical or learning disabilities on file with the University and who wish to discuss possible accommodations or other circumstances regarding lectures, coursework and exams, should speak both with the instructor and with Professor Sergio Di Domizio (sergio.didomizio@unige.it), the Department’s disability liaison. Agenda 2030 - Sustainable Development Goals Affordable and clean energy Industry, innovation and infrastructure Responbile consumption and production Climate action