Technology of Surfaces and Interfaces
Susana Isabel Santos Silva Sério Venceslau
Weekly - 3
Total - 42
-“Physical vapor deposition of thin films ” – John E. Mahan
-“Introduction to plasma physics” – Gurnett and Bhattacharjee
-“Physics of thin films ” – Maurice H. Francombe and John L. Vossen
-“Physical chemistry of surfaces” – Arthur W. Adamson, Alice P. Cast.
-“Physics at surfaces”- Andrew Zangwill.
-“An Introduction to ultrathin organic Films from Langmuir to Self-assembly”-Abraham Ulman.
-“Multilayer Thin Films- Sequential assembly of nanocomposite Materials”- Gero decher, Joseph B. Schlenoff, Jean-Marie Lehn.
The teaching-learning process includes classroom and laboratorial classes moments as follows:
Lectures of 1 hour, supported by presentations in video projector, simulations and demonstrations..Some classes will be reserved for the presentation of topics of the syllabus for the students.
Individual presentations by the students and laboratorial classes in group, lasting for two hours.
According to Dispatch No. 04/2020, the assessment will be in the following format:
• The continuous evaluation system is maintained.
• Two evaluation tests at distance: Zoom Platform for monitoring.
• There will be no minimum grade in any of the tests (T1 and T2).
• The tests dates will be established at the beginning of the semester.
• The evaluation of the practical component is carried out at distance, and in person (when possible) with the delivery of monographs and presentation, maintaining the delivery dates, according to the initial schedule established for the practical component.
• The final average obtained by the results of the 2 tests together with the results of the evaluation of the practical component will be integrated in Season 1.
• In case of np approval in the continuous assessment (Season 1) - there will be an exam in Season 2.
Two tests. This component, corresponds to the average of the 2 tests and a classification, NT, will be assigned. The average of the tests must be greater than or equal to ten values for approval of the discipline.
1. Mandatory the realization of 2 experimental laboratory works in a group of 2 students about production techniques and characterization of thin films, in person format if the conditions permit.
2. Individual monograph on a topic to be defined. This component will be assigned a grade, NM.
3. Individual presentation of the monograph (at person or at distance, according to the present conditions). This component will be assigned a grade, NA.
4. The classification of the practical component NP is obtained by the following expression, with the result rounded to the nearest integer:
NP = 0,6 x NM + 0,4 x NA
This grade must be greater than or equal to ten values for the student to be admitted to the exam or to pass the discipline.
Approval of the discipline:
Students who obtain frequency in this academic year: minimum grade of 10, out of 20, in the theoretical component T and in the practical component P.
Final grade: NF = 0.5 x NT + 0.5 x NP
Students with frequency of previous years: minimum grade of 10 in the theoretical component
Final grade: NF = NT
1. Introduction to Physics of Surfaces
1.1. Definitions and physical properties of surfaces
1.2. Thermodynamics of surfaces (2D)
1.3. Surface tension, contact angle and capillary
1.4. Mechanical, Electrical and Optical properties
1.5. Processing surfaces and changes its properties
2. Thin films and coatings
2.1. Technology and vacuum evaporation
2.2. Deposition of thin films by chemical and physical methods
2.3. Introduction to Physics of Plasmas and magnetron discharges
2.4. Use of sputtering in thin film
2.5. Preparation of surfaces (substrates)
2.6. Application of plasmas to surface treatments
2.7. Obtaining patterns in thin films
3. Nature of thin films and coatings
3.1. Condensation, nucleation and growth of thin films
3.2. Structures in thin films
3.3. Thickness, composition, mechanical, electrical and optical properties of thin films
4. Technological applications of thin films and coatings
4.1. Resistors, capacitors and electronic active components
4.2. Devices magnetic and superconducting thin films
4.3. Thin films in integrated devices (Microelectronics)
4.4. Decorative thin films
4.5. Hard films and mechanical applications
4.6. Biocompatible Films
4.7. Physical Properties of Graphene and Applications
4.8. Hydrophobic and hydrophilic surfaces
4.9. Atomic Manipulation and formation of nanostructures
5. Methods of Organic Thin Films
5.1. Molecular monolayers
5.1.2. chemical adsorption
5.1.3. physical adsorption
5.2. Molecular Heterostructures
5.2.1. Filmes de Langmuir Blodgett
5.2.3. "Spray" method
5.2.4. Molecular encapsulation
5.2.6. Dedicated lithography
Programs where the course is taught: