The course is taught in English.
Aim of the course is to provide the theoretical and the experimental tools concerning materials and characterization techniques involved in micro and nanotechnological processes.
The role of this course is central for the development of the professional profile of a Materials Engineer, as it develops several skills required for learning the other courses in Master's Degree.
The course is divided into two parts: in the first, the student learns the fundamental aspects of the physical and chemical properties of functional materials involved in micro and nanotechnological processes. In the second part, the student learns basic notions about the main characterization techniques dealing with materials (homogeneous and nanostructured) and synthesis processes.
The course is taught in English.
Aim of the course is to provide the theoretical and the experimental tools concerning materials and characterization techniques involved in micro and nanotechnological processes.
The role of this course is central for the development of the professional profile of a Materials Engineer, as it develops several skills required for learning the other courses in Master's Degree.
The course is divided into two parts: in the first, the student learns the fundamental aspects of the physical and chemical properties of functional materials involved in micro and nanotechnological processes. In the second part, the student learns basic notions about the main characterization techniques dealing with materials (homogeneous and nanostructured) and synthesis processes.
The knowledge transmitted by the course to students involves:
- Physical and chemical properties of functional materials involved in micro and nanotechnologies.
- Characterization methods devoted to materials, micro/nanostructures and technological processes
The knowledge transmitted by the course to students involves:
- Physical and chemical properties of functional materials involved in micro and nanotechnologies.
- Characterization methods devoted to materials, micro/nanostructures and technological processes
- Basic physics (mechanics, thermodynamics, electromagnetism, wave optics, elements of condensed matter physics)
- Quantum mechanics.
- Elements of statistical mechanics and quantum statistics for fermions and bosons.
- Elements of electronics and electrotechnics.
- Basic physics (mechanics, thermodynamics, electromagnetism, wave optics, elements of condensed matter physics)
- Quantum mechanics.
- Elements of statistical mechanics and quantum statistics for fermions and bosons.
- Elements of electronics and electrotechnics.
Materials (3 credits)
- Fundamentals of materials bonding and structure; materials properties inferred from chemical bonding; crystal defects.
- Metals and Ceramics: Thermo-/Ferro-/Pyro-electrical properties, Piezoelectricity, Piezoresistivity
- Materials for harsh environments
- Shape memory materials
- Nanostructured materials
- Polymers
Characterizations (3,5 credits)
- Introduction to Materials Characterization: Composition, Structure and Morphology through fundamental interactions (photons-matter, electrons-matter, ions/particles-matter)
- Optical microscopy (conventional [wide field], confocal/laser scanning)
- Electron microscopies (SEM and TEM with Electron Probe Microanalysis) and e-beam lithography
- Ionic microscopy (Focus Ion Beam) and related lithography
- Optical Spectroscopy: Photodetectors/Optical Spectrometers, Reflectance/Transmittance spectroscopy, Photoluminescence spectroscopy, Raman spectroscopy
Experimental Lab (1,5 credits)
- Experimental demonstration of: optical spectroscopies (Raman and Photoluminescence), technological processes in Clean Room, synthesis of metal nanoparticles.
Materials (3 credits)
- Fundamentals of materials bonding and structure; materials properties inferred from chemical bonding; crystal defects.
- Metals and Ceramics: Thermo-/Ferro-/Pyro-electrical properties, Piezoelectricity, Piezoresistivity
- Materials for harsh environments
- Shape memory materials
- Nanostructured materials
- Polymers
Characterizations (3,5 credits)
- Introduction to Materials Characterization: Composition, Structure and Morphology through fundamental interactions (photons-matter, electrons-matter, ions/particles-matter)
- Optical microscopy (conventional [wide field], confocal/laser scanning)
- Electron microscopies (SEM and TEM with Electron Probe Microanalysis) and e-beam lithography
- Ionic microscopy (Focus Ion Beam) and related lithography
- Optical Spectroscopy: Photodetectors/Optical Spectrometers, Reflectance/Transmittance spectroscopy, Photoluminescence spectroscopy, Raman spectroscopy
Experimental Lab (1,5 credits)
- Experimental demonstration of: optical spectroscopies (Raman and Photoluminescence), technological processes in Clean Room, synthesis of metal nanoparticles.
The course concerns theoretical lectures with the discussion of several application case studies and experimental demonstrations performed in research laboratories.
The theoretical lectures will be performed in class or online or blended, depending on sanitary emergency conditions.
The exp. demonstrations will be filmed and made available to students
The course concerns theoretical lectures with the discussion of several application case studies and experimental demonstrations performed in research laboratories.
The theoretical lectures will be performed in class or online or blended, depending on sanitary emergency conditions.
The exp. demonstrations will be filmed and made available to students
Selected chapters from the following texts:
- Materials Science and Engineering: An Introduction, by William D. Callister, Ed. Wiley
- Foundations of Materials Science and Engineering, by William F. Smith and Javad Hashem, Ed. McGraw-Hill
- Solid State Chemistry and its Applications, by Anthony R. West, Ed. Wiley
- Structural and chemical analysis of materials, by J. P. Eberhart, Ed. Wiley
- Surfaces and interfaces of solid materials, by H. Luth, Ed. Springer
- A guide to scanning microscope observation, by JEOL Inc.
- Optical processes in semiconductors, by J. I. Pankove, Ed. Dover Publ. Inc.
- Optical diagnostics for thin film processing, by I. P. Herman, Ed. Academic Press
- Fundamentals of photonics, by B.E.A. Saleh and M. C. Teich, Ed. Wiley
Learning material provided by teachers
Selected chapters from the following texts:
- Materials Science and Engineering: An Introduction, by William D. Callister, Ed. Wiley
- Foundations of Materials Science and Engineering, by William F. Smith and Javad Hashem, Ed. McGraw-Hill
- Solid State Chemistry and its Applications, by Anthony R. West, Ed. Wiley
- Structural and chemical analysis of materials, by J. P. Eberhart, Ed. Wiley
- Surfaces and interfaces of solid materials, by H. Luth, Ed. Springer
- A guide to scanning microscope observation, by JEOL Inc.
- Optical processes in semiconductors, by J. I. Pankove, Ed. Dover Publ. Inc.
- Optical diagnostics for thin film processing, by I. P. Herman, Ed. Academic Press
- Fundamentals of photonics, by B.E.A. Saleh and M. C. Teich, Ed. Wiley
Learning material provided by teachers
Modalità di esame: Prova scritta tramite PC con l'utilizzo della piattaforma di ateneo;
The exam concerns a written test dealing with open questions on the developed theory and the experiments performed within the laboratory demonstrations, with a scheduled time of 1,5 hours. Such exam will be organized by PC (4 open questions) with PoliTo Exam platform and integrated proctoring (Respondus).
Smarphones, book, pocket calculator, slides, notes are not allowed.
Exam: Computer-based written test using the PoliTo platform;
The exam concerns a written test dealing with open questions on the developed theory and the experiments performed within the laboratory demonstrations, with a scheduled time of 1,5 hours. Such exam will be organized by PC (4 open questions) with PoliTo Exam platform and integrated proctoring (Respondus).
Smarphones, book, pocket calculator, slides, notes are not allowed.
Modalità di esame: Prova scritta tramite PC con l'utilizzo della piattaforma di ateneo;
Each question will be corrected and a mark will be assigned by the teacher. The final mark is the average of the marks concerning the 4 questions.
Exam: Computer-based written test using the PoliTo platform;
Each question will be corrected and a mark will be assigned by the teacher. The final mark is the average of the marks concerning the 4 questions.