Materials for coatings
Doctoral study programme Materials
Objectives and competences
The primary goal of this course is to give students the knowledge of modern coatings from self-assembeled monolayers, over sol-gel coatings, to thicker anticorrosion coatings for marine environment. Students get to know foundations of raw coating materials i.e. binders, pigments, fillers, solvents and interactions among them, which are finished after curing. In greater detail they realize terms i.e. surface free energy, hydrophobicity and oleophobicity, self-cleaning. Extensively they become familiar with the coatings for energy harvesting.
Students gain necessary competences to prepare competitive scientific project to obtain coatings for off shore objects, to prepare and perform experiments with corrosion stability in lab, and to quantitatively analyse measurements and interpret the results.
• modern techniques for surface modification
• surface treatment (chemical modification, flame treatment, corona discharge or plasma)
• Surface modification
• Surface free energy
• self-assembled monolayers
• sol-gel coatings
• Polymers for coatings
• Coatings curing
• Rheological additives
• Graphene as additive
• Surface irregularities
• Corrosion inhibition
• Car coatings
• Coatings for solar energy harvesting
• Self-cleaning coatings
• Coating analytics
• Electrochemical measurements
• Lifetime assessment
• The influence of coatings on environment
Intended learning outcomes
Knowledge and understanding:
The students learn about the principles of various modern surface modification techniques. They also learn about methods for preparing surfaces to increase wetting and adhesion. They learn about the basic components of coatings, their interactions and their purpose in coatings. They learn to use different binders for different environments and learn to distinguish between solvent based coatings and water-based coatings. They get acquainted with sol-gel coatings that allow the preparation of inorganic coatings. They learn the basic principles for the preparation of self-sealing monopoles and their use. They learn about essential analytical methods for the characterization of coatings from self-assembled monolayers to thick anti-corrosion coatings to protect offshore objects. They learn to choose which combination of electrochemical methods is optimal for analysing the protection effectiveness against corrosion of the coatings and properties of materials associated with them. They acquire the knowledge necessary for independent performance of measurements at measuring stations in various electrochemical laboratories and skills in writing proposals for designing and testing coatings.
• A., K. (2008). High-Performance Organic Coatings, Elsevier. Paint coatings remain the most widely used way of protecting steel structures from corrosion. This important book reviews the range of organic paint coatings and how their performance can be enhanced to provide effective and lasting protection.
• Wilke, G. and S. Jacob (2008). Automotive Paints and Coatings, Wiley-VCH Verlag GmbH & Co. KGaA. E-version
• Gutowski, W., et al. (2014). "Recent advances in adhesion science and technology
• Brinker, C. J. and G. W. Scherer (1990). Sol-Gel Science. San Diego, Academic Press Catalogue E-gradivo
• Jerman, I., et al. (2012). Paint Coatings for Polymeric Solar Absorbers and Their Applications. Polymeric Materials for Solar Thermal Applications, Wiley-VCH Verlag GmbH & Co https://doi.org/10.1002/9783527659609.ch10
• Jerman, I., et al. (2012). Application of POSS Compounds for Modification of the Wetting Properties of TISS Paint Coatings. Polymeric Materials for Solar Thermal Applications, Wiley-VCH Verlag GmbH & Co. https://doi.org/10.1002/9783527659609.ch16
• Orel, B., et al. (2013). Advances in the Development of Cool Materials for the Built Environment. Advances in the development of cool materials for the built environment. M. S. a. H. A. Dionysia-Denia Kolokotsa. [S. l.], Bentham Science Publishers: 120-173 (154). https://doi.org/10.2174/9781608054718113010009
• Simončič, B., et al. (2010). BIODEGRADATION OF CELLULOSE FIBERS AND ITS INHIBITION BY CHEMICAL MODIFICATION. Handbook of carbohydrate polymers : development, properties and applications. R. Ito and Y. Matsuo. New York, Nova Science Publishers: 237-277.
During the course students prepare individual projects on coatings and on quantitative electrochemical analysis on real data from research practice. At the end of the course they prepare a final project on selected topic. All projects are prepared in a written form and defended orally in an open discussion with professor and students. 50/50%
Doc. dr. Ivan Jerman (h index = 18) He received Ph.D. degree at the University of Ljubljana, Faculty of Chemistry and Chemical Technology in 2009. Currently he is a head of Coating development laboratory, part of Department of Materials Chemistry, at National Institute of Chemistry. He participated in several EU projects: APOLON B, INNOSHADE, MULTIFUNCOAT, BONACO, NECSO, NANORESTART, Wabaselcoat, national project and projects with the industry. His main research filed is connected with coatings for renewable energy harvesting, especially solar energy. He is using different molecules for modification of pigments, metallic surfaces, textiles as a tool for preparation of surfaces with high solar absorptance, low thermal emittance, electrical conductivity, water and oil repellence and self-cleaning property and synthesis of flame retardant additives for polymeric materials.
He published over 100 publications including over 45 refereed scientific papers in the international journals with impact factor. He is co-author of 7 patents (two of them sold to industry).
For inventions, research achievements and the use of scientific research in implementing innovation in economic practice he received in 2010 prestigious Puh Distinction.
Since 2011, he has been lecturing at the Faculty of Technologies and Systems Novo mesto (Chemical technology), Slovenia, and was promoted the second time to assistant professor in 2017.
• NOČ, Luka, ŠEST, Ervin, KAPUN, Gregor, RUIZ-ZEPEDA, Francisco, BINYAMIN, Yaniv, MERZEL, Franci, JERMAN, Ivan. High-solar-absorptance CSP coating characterization and reliability testing with isothermal and cyclic loads for service-life prediction. Energy & environmental science, ISSN 1754-5706, 1 May 2019, vol. 12, iss. 5, str. 1679-1694, [COBISS.SI-ID 6620186].
IF = 33,25
• VILČNIK, Aljaž, JERMAN, Ivan, SURCA, Angelja Kjara, KOŽELJ, Matjaž, OREL, Boris, TOMŠIČ, Brigita, SIMONČIČ, Barbara, KOVAČ, Janez. Structural properties and antibacterial effects of hydrophobic and oleophobic sol?gel coatings for cotton fabrics. Langmuir, ISSN 0743-7463, 2009, vol. 25, issue 10, str. 5869-80. [COBISS.SI-ID 4133146]
• JERMAN, Ivan, KOŽELJ, Matjaž, OREL, Boris. The effect of polyhedral oligomeric silsesquioxane dispersant and low surface energy additives on spectrally selective paint coatings with self-cleaning properties. Solar energy materials and solar cells, ISSN 0927-0248. [Print ed.], 2010, vol. 94, no. 2, str. 232-245. [COBISS.SI-ID 4304154]
• JERMAN, Ivan, MIHELČIČ, Mohor, VERHOVŠEK, Dejan, KOVAČ, Janez, OREL, Boris. Polyhedral oligomeric silsesquioxane trisilanols as pigment surface modifiers for fluoropolymer based Thickness Sensitive Spectrally Selective (TSSS) paint coatings. Solar energy materials and solar cells, ISSN 0927-0248. [Print ed.], 2011, vol. 95, iss. 2, str. 423-431, [COBISS.SI-ID 4603162]
• ŠTULAR, Danaja, JERMAN, Ivan, NAGLIČ, Iztok, SIMONČIČ, Barbara, TOMŠIČ, Brigita. Embedment of silver into temperature- and pH-responsive microgel for the development of smart textiles with simultaneous moisture management and controlled antimicrobial activities. Carbohydrate polymers, ISSN 0144-8617. [Print ed.], Mar. 2017, vol. 159, str. 161-170. [COBISS.SI-ID 3350384]
• ŠEST, Ervin, DRAŽIĆ, Goran, GENORIO, Boštjan, JERMAN, Ivan. Graphene nanoplatelets as an anticorrosion additive for solar absorber coatings. Solar energy materials and solar cells, ISSN 0927-0248. [Print ed.], Mar. 2018, vol. 176, str. 19-29. doi: 10.1016/j.solmat.2017.11.016. [COBISS.SI-ID 6294810]
University course code: 3MAi09
Year of study: 2. year
- Lectures: 30 hours
- Exercises: 30 hours
- Individual work: 210 hours
Course kind: elective
Languages: english/ slovene
Learning and teaching methods:
• lectures • exercises on state of the art software for the corrosion analysis by electrochemistry on real data from research practice, under supervision of the the lecturer responsible for the course. • individual project work under supervision of the lecturer responsible for the course • presentation and interpreation of project results to other students in open discussion under supervision of the lecturer responsible for the course • journal club – discussion of published research articles on the selected corrosion electrochemical topics