study programme

Chemistry, Technology and Properties of Materials

Original title in Czech: Chemie, technologie a vlastnosti materiálůFaculty: FCHAbbreviation: DPCP_CHM_4_NAcad. year: 2022/2023

Type of study programme: Doctoral

Study programme code: P0531D130049

Degree awarded: Ph.D.

Language of instruction: Czech

Accreditation: 30.4.2020 - 30.4.2030

Mode of study

Full-time study

Standard study length

4 years

Programme supervisor

Doctoral Board

Fields of education

Area Topic Share [%]
Chemistry Without thematic area 100

Issued topics of Doctoral Study Program

  1. Advanced materials for organic and hybrid solar cells

    The work will deal with the preparation and characterization of materials - organic semiconductors, which are perspective for use in the field of organic and hybrid photovoltaics. Organic solar cells will be prepared and characterized by methods of material printing and other methods and their properties will be studied. Attention will be focused on characterization of optical and electrical properties of materials and solar cells. The aim is to optimize the properties of solar cells with respect to their specific application possibilities. It is expected that the PhD student will be involved in an international research project focusing on organic photovoltaics.

    Tutor: Weiter Martin, prof. Ing., Ph.D.

  2. Alternative construction binders cured by controlled carbonation

    The production of current high-volume building materials is associated with the release of large amounts of carbon dioxide into the atmosphere. Some, in particular, prefabricated building elements can be produced on the basis of alternative binders using secondary industrial products, such as steel slag. Curing of these binders can be significantly supported by controlled carbonation, where solidification and hardening takes place in an atmosphere with a high partial pressure of carbon monoxide. The result is a material with high strengths after only a few hours of curing and with a negative carbon footprint, because carbon dioxide is consumed in its production. It is most advantageous to include this technology as a utilization step of the CCS (Carbon Capture and Storage) technological system. The topic of the study is the development of binder systems from tactile alternative raw materials and the study of their curing by controlled carbonation.

    Tutor: Šoukal František, doc. Ing., Ph.D.

  3. Alternative construction binders cured by controlled carbonation

    The production of current high-volume building materials is associated with the release of large amounts of carbon dioxide into the atmosphere. Some, in particular, prefabricated building elements can be produced on the basis of alternative binders using secondary industrial products, such as steel slag. Curing of these binders can be significantly supported by controlled carbonation, where solidification and hardening takes place in an atmosphere with a high partial pressure of carbon monoxide. The result is a material with high strengths after only a few hours of curing and with a negative carbon footprint, because carbon dioxide is consumed in its production. It is most advantageous to include this technology as a utilization step of the CCS (Carbon Capture and Storage) technological system. The topic of the study is the development of binder systems from tactile alternative raw materials and the study of their curing by controlled carbonation.

    Tutor: Šoukal František, doc. Ing., Ph.D.

  4. Alternative construction binders cured by controlled carbonation

    The production of current high-volume building materials is associated with the release of large amounts of carbon dioxide into the atmosphere. Some, in particular, prefabricated building elements can be produced on the basis of alternative binders using secondary industrial products, such as steel slag. Curing of these binders can be significantly supported by controlled carbonation, where solidification and hardening takes place in an atmosphere with a high partial pressure of carbon monoxide. The result is a material with high strengths after only a few hours of curing and with a negative carbon footprint, because carbon dioxide is consumed in its production. It is most advantageous to include this technology as a utilization step of the CCS (Carbon Capture and Storage) technological system. The topic of the study is the development of binder systems from tactile alternative raw materials and the study of their curing by controlled carbonation.

    Tutor: Šoukal František, doc. Ing., Ph.D.

  5. Alternative construction binders cured by controlled carbonation

    The production of current high-volume building materials is associated with the release of large amounts of carbon dioxide into the atmosphere. Some, in particular, prefabricated building elements can be produced on the basis of alternative binders using secondary industrial products, such as steel slag. Curing of these binders can be significantly supported by controlled carbonation, where solidification and hardening takes place in an atmosphere with a high partial pressure of carbon monoxide. The result is a material with high strengths after only a few hours of curing and with a negative carbon footprint, because carbon dioxide is consumed in its production. It is most advantageous to include this technology as a utilization step of the CCS (Carbon Capture and Storage) technological system. The topic of the study is the development of binder systems from tactile alternative raw materials and the study of their curing by controlled carbonation.

    Tutor: Šoukal František, doc. Ing., Ph.D.

  6. Corrosion of low carbon steel and galvanized steel: the role of humic and fulvic acids

    Low carbon and galvanized steel are a conventional material that is commonly used for various applications. Steel components can be located in water and soil, where, besides inorganic species, there are also organic molecules that can have a significant impact on the corrosion process. The role of humic and fulvic acids (the most important fraction of natural organic matter) in the corrosion process is insufficiently elucidated unlike inorganic species. The effect of humic and fulvic acids on corrosion resistance and corrosion products (composition, morphology) of low carbon and galvanized steel in the environment of inorganic ions at various pH will be investigated. Attention will be paid to the interactions of organic molecules with the metal surface and in the solution. The aim of the work will be to determine the effect of humic and fulvic acids on the corrosion of low carbon and galvanized steel and to describe the mechanism of interactions with the metal surface and in solution. The use of humic and fulvic acids as green corrosion inhibitors will also be assessed.

    Tutor: Wasserbauer Jaromír, doc. Ing., Ph.D.

  7. Novel organic materials for applications in bioelectronics

    The work will deal with preparation and characterization of new organic materials, which are prospective for use in bioelectronics. Attention will be focused primarily on the characterization of the optical and electrical properties of materials prepared in the form of thin films. The possibilities of using materials in thin-film sensory systems to stimulate cells and study their response will be studied.

    Tutor: Weiter Martin, prof. Ing., Ph.D.

  8. Preparation of LDH layers on magnesium alloys to increase their corrosion resistance

    Based on the available literature, the dissertation thesis will use the knowledge for the preparation of LDH-based (Layered Double Hydroxide) layers. Successfully prepared layers on magnesium substrates will be analysed in terms of the microstructure, composition and corrosion behaviour. These LDH layers will be further suitably modified and functionalized to improve their corrosion and electrochemical properties.

    Tutor: Wasserbauer Jaromír, doc. Ing., Ph.D.

  9. Screen-printed films for the electronics

    The work is pointed out towards study and application of the material printing techniques in the field of printed electronics, mainly touch-screens and/or organic and bioelectronic applications. Screen-printing technology will be in-dept studied – design of structures, projection on the screen by photolithograpy, the technology of the printed pastes, screen-printing of samples. The printed films will be characterized and estimated by mechanical, optical and electrical measurements.

    Tutor: Zhivkov Ivaylo, doc. Mgr., Ph.D.

  10. Study of biodegradable barrier coatings properties for agrochemical applications

    The current legislation tightens the view of materials used for agrochemical applications, the requirement is fully biodegradable slow-release systems of fertilizers and pesticides. One of the few candidates recognized by the legislation as fully biodegradable polymers are polyhydroxyalkanoates, which have the potential for use in these applications. The topic deals with the study of the properties of these materials and their derivatives with respect to the required applications. The work should relate the chemical structure of PHA polymers, their copolymers and mixtures and the resulting properties, including their behavior in the environment.

    Tutor: Přikryl Radek, Mgr., Ph.D.

  11. Study of electric and dielectrical properties of materials of photovoltaic cells

    The work will be focused on the study of dielectric properties (complex permittivity) of materials used for the photovoltaic cells. To study methods will be used impedance spectroscopy and DC measurements

    Tutor: Zmeškal Oldřich, prof. Ing., CSc.

  12. Study of optical phenomena on thin-film structure whith perovskites layers

    Work will be focused on the study of surface properties of thin films used in the preparation of thin film structures with layers of perovskites

    Tutor: Zmeškal Oldřich, prof. Ing., CSc.

Course structure diagram with ECTS credits

1. year of study, both semester
AbbreviationTitleL.Cr.Com.Compl.Hr. rangeGr.Op.
DCO_FCHMPhysics and chemistry of materialscs0CompulsoryDrExyes
DC_EAPcs0Compulsory-optionalDrExyes
DCO_FPDPhotoinduced processes in molecular materialscs0Compulsory-optionalDrExyes
DC_CHIAcs0Compulsory-optionalExyes
DCO_KMCeramic materialscs0Compulsory-optionalDrExyes
DCO_KOVMetallic Materialscs0Compulsory-optionalDrExyes
DC_MIM cs0Compulsory-optionalDrExyes
DCO_MPMMaterials Science-Fundamentals and Advancescs0Compulsory-optionalDrExyes
DCO_MMMolecular materialscs0Compulsory-optionalDrExyes
DCO_PMTAdvanced Materials Technologies and Applicationscs0Compulsory-optionalExyes
DCO_PTVPreparation and properties of thin layers of materialscs0Compulsory-optionalDrExyes
DC_SMMcs0Compulsory-optionalDrExyes
DCO_VSDUtilisation of secondary productscs0Compulsory-optionalDrExyes