Lecturer(s)
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Kalinová Klára, doc. Ing. Ph.D.
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Kolek Ondřej, Ing. Ph.D.
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Hrůza Jakub, Ing. Ph.D.
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Komárek Michal, Ing. Ph.D.
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Course content
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Lectures: 1. Introduction, the methods overview with respect to physical principles; spectres and energy levels of atoms. 2. Electron microanalysis and spectroscopy (SEM, EPMA, EDS, WDS, TEM, SAED, EELS). 3. Microscopy with microprobe (STM, AFM). Optical microscopy. Methods of particle size determination and size distribution. 4. X-ray diffraction (XRD, SAXS), X-ray absorption spectroscopy (XAS, EXAFS-XANES-NEXAFS). Electron diffraction (LEED, RHEED). 5. Photoelectron spectroscopy (XPS, AES). Spectroscopic methods (FTIR, RS, SERS). 6. Special methods (zeta-potential, CLM), ion detection (SIMS) and nuclear methods (RBS, ERDA, PIXE). 7. Methods of thermic analysis and calorimetry (DTA/DSC, dissolving calorimetry). 8. Surface and interfacial energy determination (goniometry). 9. Electrochemical methods: Basic methods of electro-chemical cells, impedance measurements and battery lifetime. Evaluation of the conversion efficiency of solar cells. 10. Characterization of air filters: Basic filtration characteristics and methods of their calculations and interpretation. Methods of measurement regarding to application. Evaluation of catalytic processes. 11. Characterization of liquids filtration: Basic filtration characteristics and methods of their calculations and interpretation. Methods of measurement regarding to application. 12. Antimicrobial properties of filtration nanomaterials: Testing of the antimicrobial properties in flowing medium (liquid, gas). Testing of the antibacterial properties of surfaces and surface treatments. 13. Acoustic measurement: sound absorption coefficient, transmission loss, damping, optical methods, noise map.
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Learning activities and teaching methods
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Monological explanation (lecture, presentation,briefing), Dialogue metods(conversation,discussion,brainstorming), Self-study (text study, reading, problematic tasks, practical tasks, experiments, research, written assignments)
- Class attendance
- 56 hours per semester
- Home preparation for classes
- 74 hours per semester
- Preparation for exam
- 20 hours per semester
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Learning outcomes
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Student gains a detailed knowledge about methods of study and characterization of nanomaterials. The intended nanomaterials are: nanoparticles, nanofibres, nano-surfaces and nanopores. The individual scopes of the measurement techniques are focused on standard analytical methods for nanomaterial analysis in the first part while focused on other methods with respect to the research topics studied at Technical University of Liberec. Students prepare a nanomaterial at the initial seminar, which will be then characterized during the other seminars. Moreover the laboratories with top-class devices will be visited.
Obtaining of nanomaterials characterization summary, knowledge of measuring methods
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Prerequisites
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Knowledge of high school chemistry, physics, mathematics
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Assessment methods and criteria
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Combined examination
Combined exam; 10 - 14 laboratory protocols.
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Recommended literature
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Bhushan, B. Springer handbook of nanotechnology. Berlin: Springer, c2004.. Springer-Verlag Berlin Heidelberg, 2010. ISBN 978-3-642-02524-2.
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Černohorský T., Jandera P. Atomová spektrometrie; Univerzita Pardubice, 1997..
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G. Cao. Nanostructures & Nanomaterials: Synthesis, Properties & Applications, Chapter 8. Characterization and Properties of Nanomaterials. Imperial College Press, London, 2004. ISBN 1-86094-4159.
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G.L. Hornyak a kol. Introduction to Nanoscience. Chapter 3. Characterization Methods.. CRC Press, 2008. ISBN 978-4200-4805-6.
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Lajunen L. H. J., Perämäki P. Spectrochemical Analysis by Atomic Absorption and Emission, 2nd Edition; Royal Society of Chemistry: Cambridge, UK, 2004, ISBN 0-85404-624-0..
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Šulc, J., Šinták, J. Právní problematika a ochrana životního prostředí. Skripta VŠST Liberec, 1990. ISBN 80-7083-027-1.
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