study programme

Chemistry and technology of environmental protection

Original title in Czech: Chemie a technologie ochrany životního prostředíFaculty: FCHAbbreviation: DPCP_CHTOZP_NAcad. year: 2022/2023

Type of study programme: Doctoral

Study programme code: P0712D130001

Degree awarded: Ph.D.

Language of instruction: Czech

Accreditation: 26.4.2018 - 26.4.2028

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. Application of Advanced Wastewater Treatment Technologies for industrial Wastewater Treatment

    Doctoral thesis deals with the topic of Advanced Wastewater Treatment Technologies Application for Industrial Wastewater Treatment. In theoretical part, there will be a literature review with the focus on Advanced Industrial Wastewater Treatment Technologies such as Advanced Oxidation Processes, Membrane Processes, Advanced Biological Processes etc. Each type of technology will be described in detail with emphasis on its applicability and compatibility with other industrial wastewater treatment technologies. Industrial wastewater technology design and a pilot-scale prototype development will be held in experimental part. Prototype development will include mathematical modelling and use of software simulations. The prototype will involve use of multiple types of Advanced Wastewater Treatment Technologies. Data obtained during laboratory and pilot semi-controlled experiments will be evaluated for prototype operation optimalisation, improvement and scale-up for full scale operation.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  2. Application of Advanced Wastewater Treatment Technologies for industrial Wastewater Treatment

    Doctoral thesis deals with the topic of Advanced Wastewater Treatment Technologies Application for Industrial Wastewater Treatment. In theoretical part, there will be a literature review with the focus on Advanced Industrial Wastewater Treatment Technologies such as Advanced Oxidation Processes, Membrane Processes, Advanced Biological Processes etc. Each type of technology will be described in detail with emphasis on its applicability and compatibility with other industrial wastewater treatment technologies. Industrial wastewater technology design and a pilot-scale prototype development will be held in experimental part. Prototype development will include mathematical modelling and use of software simulations. The prototype will involve use of multiple types of Advanced Wastewater Treatment Technologies. Data obtained during laboratory and pilot semi-controlled experiments will be evaluated for prototype operation optimalisation, improvement and scale-up for full scale operation.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  3. Application of Advanced Wastewater Treatment Technologies for industrial Wastewater Treatment

    Doctoral thesis deals with the topic of Advanced Wastewater Treatment Technologies Application for Industrial Wastewater Treatment. In theoretical part, there will be a literature review with the focus on Advanced Industrial Wastewater Treatment Technologies such as Advanced Oxidation Processes, Membrane Processes, Advanced Biological Processes etc. Each type of technology will be described in detail with emphasis on its applicability and compatibility with other industrial wastewater treatment technologies. Industrial wastewater technology design and a pilot-scale prototype development will be held in experimental part. Prototype development will include mathematical modelling and use of software simulations. The prototype will involve use of multiple types of Advanced Wastewater Treatment Technologies. Data obtained during laboratory and pilot semi-controlled experiments will be evaluated for prototype operation optimalisation, improvement and scale-up for full scale operation.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  4. Development and application of membrane distillation

    Membrane distillation is one of the promising methods of separation and purification of chemical substances. Despite the big boom in recent years, this method still suffers from technical and application shortcomings. This work aims to develop laboratory and pilot plant distillation equipment, some applications in the separation of thermally unstable substances, and industrial wastewater treatment from the chemical, biochemical and pharmaceutical industries. The work will take place in cooperation with the Faculty of Mechanical Engineering.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  5. Development and application of membrane distillation

    Membrane distillation is one of the promising methods of separation and purification of chemical substances. Despite the big boom in recent years, this method still suffers from technical and application shortcomings. This work aims to develop laboratory and pilot plant distillation equipment, some applications in the separation of thermally unstable substances, and industrial wastewater treatment from the chemical, biochemical and pharmaceutical industries. The work will take place in cooperation with the Faculty of Mechanical Engineering.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  6. Development of techniques for fast assessment of soil quality and properties

    Thermogravimetry appeared as a promising techniques for fast assessment of soil properties and showed a potential to replace currently used techniques. These techniques are often costly and require long experimental time, while thermogravimetry experiments require only several hours. The aim of this work is searching for new relationships between thermo-oxidative stability of soil determined using thermogravimetry and soil chemical properties (pH, content of biogenic elements including P, S and different forms of N, metals including Al and Fe), physical properties (texture and volume density) and biological indicators (microbial biomass, potentially mineralizable N, glomalin and phospholipids contents and microbial emissions of carbon dioxide and nitrous oxide). These properties are known as indicators of soil quality, and therefore, the found correlations will be used for development of a complex soil quality index and models for prediction of soil organic carbon stability.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  7. Development of techniques for fast assessment of soil quality and properties

    Thermogravimetry appeared as a promising techniques for fast assessment of soil properties and showed a potential to replace currently used techniques. These techniques are often costly and require long experimental time, while thermogravimetry experiments require only several hours. The aim of this work is searching for new relationships between thermo-oxidative stability of soil determined using thermogravimetry and soil chemical properties (pH, content of biogenic elements including P, S and different forms of N, metals including Al and Fe), physical properties (texture and volume density) and biological indicators (microbial biomass, potentially mineralizable N, glomalin and phospholipids contents and microbial emissions of carbon dioxide and nitrous oxide). These properties are known as indicators of soil quality, and therefore, the found correlations will be used for development of a complex soil quality index and models for prediction of soil organic carbon stability.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  8. Development of techniques for fast assessment of soil quality and properties

    Thermogravimetry appeared as a promising techniques for fast assessment of soil properties and showed a potential to replace currently used techniques. These techniques are often costly and require long experimental time, while thermogravimetry experiments require only several hours. The aim of this work is searching for new relationships between thermo-oxidative stability of soil determined using thermogravimetry and soil chemical properties (pH, content of biogenic elements including P, S and different forms of N, metals including Al and Fe), physical properties (texture and volume density) and biological indicators (microbial biomass, potentially mineralizable N, glomalin and phospholipids contents and microbial emissions of carbon dioxide and nitrous oxide). These properties are known as indicators of soil quality, and therefore, the found correlations will be used for development of a complex soil quality index and models for prediction of soil organic carbon stability.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  9. Phytotoxicity and phytoremediation of nickel

    Nickel (Ni) is the 24th most common element of the Earth’s crust. Its annual production is about 2 mil. tons with various use in industry. Due to the Ni content in the ores ca. 1 – 2%, it is evident that its processing generates considerable amounts of waste with various residual Ni content. Nickel has also long been known as a carcinogen. The aim of this work is a complex processing of the literature data focused on the toxicity of nickel in plants and their use for phytoremediation of this element. The practical part will be focused on i) study of nickel toxicity using model plant species under hydroponic conditions (influence of salts, pH etc.) and ii) selection of species suitable for phytoremediation of nickel using waste from the former Nickel smelter heaps in the city Sered. Particular attention will be paid to the impact of environmentally harmless additives (biochar, humic substances, exogenous application of endogenous plant substances) on nickel uptake by plants.

    Tutor: Kučerík Jiří, prof. Ing., Ph.D.

  10. Plant bioindicators – a tool for assessing environmental contamination inorganic pollutants

    This thesis will focus on the use of plant material, which is located in the exposed areas, to the assessment of environmental pollution. The aim will be to develop a detailed literature review current bio-monitoring and environmental contamination by inorganic pollutants. After selection will be performed reliable bioindicators and methods for their use regard to the environmental studies; also will be made "optimization" of their use under laboratory conditions. In conclusion, these techniques will be applied to assess the real state of contamination of the environment, particularly the evaluation and comparison of contamination in large urban areas and rural areas.

    Tutor: Komendová Renata, doc. Mgr., Ph.D.

  11. Study of contaminants and nutrition elements in plants and soils using ICP mass spectrometry

    The thesis will be devoted to bulk analysis and distribution of elements considered to be contaminants as well as their interactions with nutritional elements in plant samples using ICP mass spectrometry. The work includes solution analysis as well as sampling of solid samples to trace elemental distribution in specific compartments of plant samples. The suitable quantification procedure will be developed. The outcomes will be supplemented with soil sample analyses.

    Tutor: Vašinová Galiová Michaela, doc. Mgr., Ph.D.

  12. Study of interaction of metallocenes with cells by ICP mass spectrometry

    The work will be focused on solution analysis of cells treated with various organometallic compounds as a new potential anti-cancer therapeutics. Beside SN analysis, in situ single cell analysis will be performed in order to determine the distribution of selected elements and cytotoxicity of compounds. The work will be realized in cooperation with Masaryk Memorial Cancer Institute where cells will be treated with cytotoxic drugs as well as specific inhibitors.

    Tutor: Vašinová Galiová Michaela, doc. Mgr., Ph.D.

  13. Use of ecotoxicity tests to assess the effects of the presence of selected groups of pharmaceuticals on ecosystem components

    The dissertation will focus on the use of ecotoxicity tests at the organismal and suborganismal levels in evaluating the impact of selected groups of pharmaceuticals on the biota of aquatic and soil ecosystems. The aim will be to elaborate a detailed literature search on the current situation of the occurrence of pharmaceuticals in the ecosystem. In present the WWTPs are not able to completely degrade these substances, they can enter the ecosystem and may have impacts on the biota of the relevant ecosystems due to their physiological functions. Through ecotoxicity tests, these effects will be predicted and the risks associated with the presence of these substances in the ecosystem will be assessed.

    Tutor: Zlámalová Gargošová Helena, doc. MVDr., Ph.D.

  14. Use of tandem techniques for the assessment of recovered building materials

    Recycling and reuse of various materials is currently a very actuall issue. There is also an effort to follow this trend in construction. The aim of this work will be to develop a detailed current rewiev dealing with the reuse of building materials (rubble, asphalt mixtures…) and the requirements for these mixtures, which must meet in order to become a by-product and not to be waste. Therefore, the main goal of the work will be the development and optimization of the analytical method for monitoring the sum of specified organic substances according to the requirements of legislation, but also substances that are not mentioned in the current legislation. At the same time, the procedures for obtaining an analytical sample will be modified and these will be discussed with regard to potential environmental risks.

    Tutor: Zlámalová Gargošová Helena, doc. MVDr., Ph.D.

  15. Use of tandem techniques for the assessment of recovered building materials

    Recycling and reuse of various materials is currently a very actuall issue. There is also an effort to follow this trend in construction. The aim of this work will be to develop a detailed current rewiev dealing with the reuse of building materials (rubble, asphalt mixtures…) and the requirements for these mixtures, which must meet in order to become a by-product and not to be waste. Therefore, the main goal of the work will be the development and optimization of the analytical method for monitoring the sum of specified organic substances according to the requirements of legislation, but also substances that are not mentioned in the current legislation. At the same time, the procedures for obtaining an analytical sample will be modified and these will be discussed with regard to potential environmental risks.

    Tutor: Zlámalová Gargošová Helena, doc. MVDr., Ph.D.

Course structure diagram with ECTS credits

1. year of study, both semester
AbbreviationTitleL.Cr.Com.Compl.Hr. rangeGr.Op.
DC_MAEcs0CompulsoryDrExyes
DC_AZEcs0Compulsory-optionalDrExyes
DC_ETJcs0Compulsory-optionalDrExyes
DC_METMetrology and experimental data processingcs2Compulsory-optionalDrExyes
DC_NVDNew trends in water management technologiescs0Compulsory-optionalDrExyes
DC_ENAAdvanced Environmental Analytical Chemistrycs0Compulsory-optionalDrExyes
DC_OCHAdvanced Organic Chemistrycs2Compulsory-optionalDrExyes
DC_TNPcs0Compulsory-optionalDrExyes