Chemistry
This doctoral study programme is organized by the Faculty of Science in English and the studies are subject to tuition. There is an alternative option for the international applicants to be accepted in the free programme administered in Czech with the possibility of receiving a scholarship. The study language of the programme is still English (Czech is the administrative language). Before officially applying, please contact us at admission@sci.muni.cz to find all the necessary information related to the scholarship and see our FAQ’s.
International applicants for doctoral study (Czech and Slovak Republics applicants NOT included)
Submission deadline until midnight 15 December 2024.
What will you learn?
The doctoral study program of Chemistry aims at training highly skilled specialists in five specialization fields of study - analytical, inorganic, physical, materials, and organic chemistry. Training of doctoral students is carried out at the Department of Chemistry, Faculty of Science and is based on scientific research and independent creative activity in selected fields and areas of research or development. Major research topics in individual specialization fields are:
“Chemistry is a powerful charm”
Analytical Chemistry
Development of methodology and instrumentation in the field of spectrometry and analytical
Instrumental analysis of inorganic, organic and biological samples.
Analytical applications and characterization of nanomaterials.
Inorganic Chemistry
Synthesis and characterization of metal complexes and coordination polymers
Synthesis of organometallic compounds and studies of their structure and properties
Synthesis of molecular compounds as precursors to new materials
Physical Chemistry
Physical-chemical characterization of compounds and materials - studies of their properties by modern research methods
Application of quantum chemical methods to problems in structure, reactivity, and molecular spectroscopy
Characterization and study of biomolecules by modern spectral and electrochemical methods
Materials Chemistry
Chemical synthesis of nanoparticles of metals and oxides
Phase equilibria and transformations of materials
Quantum chemistry computations in materials chemistry
Organic Chemistry
Modern approaches in synthetic and medicinal chemistry directed toward the preparation of novel organic compounds with targeted biological activity
Mechanistic organic chemistry and photochemistry
Synthesis of macrocyclic compounds and investigation of their supramolecular properties
The work of doctoral students under the supervision of their tutors is focused either on independent and creative experimental activity or theoretical pursuits. The study is based on a thorough theoretical knowledge of the whole discipline of chemistry. The student acquires this knowledge by completing compulsory optional courses, which are supplemented by the latest information in the given area, and through optional courses gaining experimental technique skills, as well as learning new methods. In addition, the programme contributes to developing the abilities of students to critically evaluate findings gained from literature and pass on these as well as their own findings to the public by means of seminars. Teaching experience is gained by assisting in selected courses for students of bachelor and master programs. An important goal of doctoral studies is also gaining a broad scientific view of the discipline, international experience and language skills, which is facilitated by research stays at domestic and foreign partner institutions and by active participation at national and international scientific conferences. During their studies, student will learn to prepare manuscripts in English. The ultimate goal of this study is to obtain significant scientific results that can be published in prestigious journals and finally summarize them in a doctoral dissertation thesis.
Practical training
A minimum stay abroad must last for one month at minimum.
A one-semester stay at a foreign research institution is recommended in this programme.
Further information
http://ustavchemie.sci.muni.cz/
The Office for Doctoral Studies, Quality, Academic Affairs and Internationalization takes care of doctoral students SCI MU
https://www.sci.muni.cz/en/students/phd
On the department's website, you can find the following information:
- Forms (application forms for state examinations and defences, various applications, etc. )
- Legislation (links to: MU Study and Examination Regulations, Scholarship Regulations of MU, Terms of Scholarship Programmes of the Faculty of Science)
- Dissertations (Guidelines for dissertations, templates)
- Manuals (guidelines for Individual Study Plans, study and research obligations in DSP, etc.)
- Doctoral study programmes (recommended study plans, examination committees, overview of accredited programmes)
- Deadlines for the doctoral state examinations and defences
- Enrolment (information needed for the enrolment to the next semester)
- Graduation
but also office hours, contacts, news, information on skills development and scholarships.
Detailed information on stays abroad can be found on this website:
https://www.sci.muni.cz/en/students/phd/develop-your-skills/stay-abroad
Career opportunities
Graduates of the Chemistry program according to their specialization field find employment at university departments, at institutes of Academy of Sciences, at various research institutes and control laboratories in private firms and government institutions. Further opportunities are found in chemical, pharmaceutical, electronic, and food industries, laboratories in the fields of environmental protection, health care, agriculture and biotechnology. They also find employment in areas of development and production of instrumentation and also in qualified sale and service. Graduates are flexible and easily adapt to various requirements of chemistry oriented companies and they are trained not only for professional careers in their specialization, but their wide-ranging education allows them to adjust easily for careers in other fields as well. By their work in research teams and by their educational work in bachelor and master degree programs, the doctoral students also cultivate their ability to lead younger colleagues. By that they acquire further essential experience for their expected professional role as the executives. Language skills, international contacts, and study stays abroad allows graduates to find employment also at foreign leading institutions.
Admission requirements
The admission interview is usually in an online form and consists of two parts:
1) expert interview – checking expertise background and motivation (max. 100 points),
2) Language part – check of communication skills in English, interview and expert discussion is in English (max. 100 points)
More information about admission process for international applicants in general can be found in the section Admission Process.
Date of the entrance exam
The applicants will receive information about the entrance exam by e-mail usually at least 10 days before the exam.
Please, always check your e-mails, including spam folders.
Conditions of admission
To be admitted, a candidate must obtain a total of at least 120 points out of 200, with at least 60 points in both parts.
Successful applicants are informed of their acceptance by e-mail and subsequently receive an invitation to the enrolment.
Programme capacity
The capacity of a given programme is not fixed; students are admitted based on a decision by the Doctoral Board after assessing their aptitude for study and motivation.
Deadlines
Submit your application during this period
Study options
Single-subject studies with specialization
In the single-subject studies, the student deepens knowledge in the concrete focus of the degree programme and chooses one specialization. The specialization is stated in the university diploma.
Dissertation topics
Specialization: Analytical Chemistry
Acoustic Spectroscopy of Laser-Induced Plasma
Supervisor: doc. Mgr. Karel Novotný, Ph.D.
The acoustic signal associated with the plasma formation during the Laser-Induced Breakdown Spectroscopy (LIBS) will be studied. Investigation of the frequency spectrum of the acoustic signal during ablation of various materials as well as study concerning the shot-to-shot evolution of the laser-induced crater morphology and plasma emission lines will be the main topic of this work. The previous results confirm that the acoustic signal is well correlated with the target hardness/density and also can be used as an ablation rate indicator. Acoustic signal provides new information relative to the ablation process that is independent of the LIBS spectrum.
Supervisor
Application of a quadrupole analyzer in frequency mode for the detection of large molecules
Supervisor: prof. Mgr. Jan Preisler, Ph.D.
Doctoral project:
Náplní doktorské práce bude návrh, konstrukce a aplikace tohoto laboratorního prototypu.
Notes
Literatura: D. L. Shinholt, S. N. Anthony, A. W. Alexander, B. E. Draper, and M. F. Jarrold, A Frequency and Amplitude Scanned Quadrupole Mass Filter for the Analysis of High m/z Ions, Review of Scientific Instruments 2014, 85, 11309. Landais, B.; Beaugrand, C.; Capron-Dukan, L.; Sablier, M.; Simonneau, G.; Rolando, C., Varying the radio frequency: a new scanning mode for quadrupole analyzers. Rapid Commun Mass Sp 1998, 12 (6), 302-306.
Supervisor
Application of nanoparticles in analytical chemistry
Supervisor: prof. RNDr. Přemysl Lubal, Ph.D.
EXAMPLES of doctoral projects:
* Surface enhanced molecular spectroscopy (e.g. Raman/fluorescence/CD spectroscopy) of NP’s modified for determination of chosen analytes
* Development of new optical sensors and sensor arrays based on NP’s
Supervisor
Applications of nanoparticles in mass spectrometry
Supervisor: prof. Mgr. Jan Preisler, Ph.D.
EXAMPLES of doctoral projects:
- Development of sample preparation protocol for specific detection of selected markers on sections of 3D cell aggregates, other tissues and substrates.
- Optimization of specific labelling with nanoparticles. The specificity will be based on antibody-antigen and avidin-biotin interactions, aptamer bindings, nucleic acid pairing etc.
- Development of nanoparticle detection schemes using inductively coupled plasma (ICP) and laser desorption/ionization (LDI) techniques.
- Study of nanoparticle transport efficiency in ICP MS. Confocal fluorescence and electron microscopy will be used as reference methods.
MORE INFORMATION: bart.chemi.muni.cz
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Applied separation methods
Supervisor: prof. RNDr. Přemysl Lubal, Ph.D.
EXAMPLES of doctoral projects:
* ITP/CZE/IC analysis of organic compounds after their derivatization
* ITP/CZE/IC analysis of chiral compounds
* ITP/CZE/IC analysis of drugs and their metabolites
* Supramolecular chemistry in separation methods
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Biorecognition tools for imaging of specific proteins in soft tissues
Supervisor: doc. Mgr. Tomáš Vaculovič, Ph.D.
During this thesis the research will be focused on the development of methods based on labelling of antibodies by nanoparticles and preparation of molecularly imprinted polymers and their application for imaging of proteins and elements in soft tissues. Moreover, improving of lateral resolution and calibration processes will be optimized with respect to reach sufficient limit of detection and lateral resolution.
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Development of analytical methods in clinical diagnostics
Supervisor: doc. RNDr. Petr Kubáň, Ph.D.
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Development of laser-induced plasma spectroscopy methods for detection of nanoparticle-tagged biomolecules
Supervisor: doc. Mgr. Karel Novotný, Ph.D.
Vývoj technik umožňující selektivní detekci biomolekul značených kovovými nanočásticemi pomocí spektroskopie laserem buzeného plazmatu. Vývoj metod pro rychlou detekci biomolekul s vysokým prostorovým rozlišením a citlivostí.
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Developments and applications of novel microextraction techniques in analyses of complex samples
Supervisor: RNDr. Pavel Kubáň, DSc.
Experimentální část práce bude zahrnovat vývoj nových mikroextrakčních technik, které jsou založeny na selektivních přechodech analytů přes semi-permeabilní fázová rozhraní [1,2]. Při přechodu analytů bude využito difuze [1] nebo bude přechod urychlen účinkem elektrického pole [2]. Výsledné mikroextrakční techniky budou spojeny off-line nebo in-line s vhodnými analytickými metodami (primárně s kapilární elektroforézou) a adekvátnost takového spojení bude demonstrována analýzami biologicky, klinicky a toxikologicky významných analytů v reálných komplexních vzorcích jako je moč, krevní sérum/plasma a plná krev. [1] Kubáň, P., Boček, P., J. Chromatogr. A 1234 (2012) 2-8. [2] Kubáň, P., Šlampová, A., Boček, P., Electrophoresis 31 (2010) 768-785.
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High separation efficiency + high sensitivity = CE-ICP-MS
Supervisor: doc. Mgr. Tomáš Vaculovič, Ph.D.
Development of conection of capillary electrophoresis with ICP. Application for analysis of nanoparticles.
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Laser induced brekdown spectroscopy - development of fast elemental mapping methods
Supervisor: doc. Mgr. Karel Novotný, Ph.D.
Vývoj metod pro sledování prostorové distribuce prvků v různých materiálech na principu spektroskopie laserem buzeného plazmatu. Vývoj a optimalizace konfigurace a experimentálních parametrů sestavy na signál. Použití pokročilých chemmometrických postupů pro vyhodnocení naměřených dat.
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Mass spectrometry imaging
Supervisor: prof. Mgr. Jan Preisler, Ph.D.
EXAMPLES of doctoral projects:
- Development of sample preparation protocols for MALDI MSI. Samples may include 3D cell aggregates or other biological tissues.
- MALDI MSI of perifosine and other antitumor agents in 3D cell aggregates.
- Optimization of reactions on tissue sections. The aim will be, e.g., determination of double bond position in fatty acid chains in lipids.
MORE INFORMATION: bart.chemi.muni.cz
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Metal complexes of macrocyclic ligands
Supervisor: prof. RNDr. Přemysl Lubal, Ph.D.
EXAMPLES of doctoral projects:
* Thermodynamic and kinetic study of new macrocyclic ligands with chosen metal ions as models for radioisotope labelling
* Metal complexes mimicking enzyme activity
* Metal complexes as chemical sensors
* Development of new analytical methods for analysis of new chelating ligands and their metal complexes - collaboration with industrial partners
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Monolithic stationary phases in proteomics analysis
Supervisor: doc. RNDr. Jiří Urban, Ph.D.
Preparation of hypercrosslinked polymer-based monolithic stationary phases allowing size-based separation of proteins and separation of peptides in gradient elution liquid chromatography.
Supervisor
Study of the of laser beam interaction with a sample for LA-ICP-MS and LIBS methods.
Supervisor: Mgr. Markéta Holá, Ph.D.
Práce se bude věnovat metodám LA-ICP-MS a LIBS, které využívají pro analýzu působení laserového pulzu na povrch vzorku. Bude studováno mikropazma, jehož vlastnosti jsou zásadní pro metodu LIBS (teplota, rozpínání, časový průběh, hustota částic...) a vznikající aerosol, jehož kvalita určuje správnost a přesnost metody LA-ICP-MS (velikostní distribuce čístic, koncentrace částic, složení částic, účinnost transportu...). Bude sestrojena komora pro simultánní provoz obou metod za použití jednoho laseru. Studovány budou různé parametry laseru a různá úprava povrchu vzorků (hrubost, plazmové napařování, nanočástice).
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Synthesis and application of composite nanoparticles in bioanalytical chemistry
Supervisor: doc. RNDr. Petr Kubáň, Ph.D.
Nanočástice přináší řadu unikátních vlastností, které nacházejí uplatnění v řadě inovativních metod a protokolů. Není tak náhodou, že využití nanomateriálů patří mezi Národní priority orientovaného výzkumu, experimentálního vývoje a inovací (VaVaI).
Nanočástice mají nezastupitelné místo i v analytické chemii. Jednotlivé analytické aplikace pak kladnou specifické nároky na konkrétní vlastnosti potřebných nanočástic. Těchto vlastností je někdy náročné dosáhnout při použití jediného typu materiálu (tj. prvku či sloučeniny). Tato dizertační práce směřuje na přípravu nanočástic z plasmonických kovů v kombinaci s dalšími materiály tak, aby byly připraveny částice maximálně vhodné pro danou analytickou aplikaci.
Jedním z cílů dizertační práce tak bude příprava nanočástic umožňující selektivní a citlivou detekci peptidických látek pomocí povrchem zesílené Ramanovy spektrometrie. Zde budou připravované částice složené ze stříbra a sorbentu. Druhá část práce bude směřovat na selektivní detekci thiolovaných látek. Zlaté nanočástice (AuNP) nebo konjugované částice AuNP-Fe3O4 s magnetickými vlastnostmi mají obzvláště silnou afinitu k biomolekulám obsahujícím thiol, které se spontánně adsorbují na povrch Au nanočástic. Aplikace AuNP a AuNP-Fe3O4 bude využita pro selektivní extrakci a prekoncentraci biologických thiolů z neinvazivních biologických tekutin (EBC, sliny, pot) s možností automatizace celého procesu.
Supervisor
Use of LA-ICP-MS for analysis of geological sampples.
Supervisor: Mgr. Markéta Holá, Ph.D.
Práce se týká následujích témat:
- bodová lokální analýza minerálů
- plošné mapování vzorků pro zjištění distribuce prvků
- datování minerálů
- využití instrumentace LA 193 nm a 213 nm, kvadrupólový ICP-MS a sektorový ICP-MS
Supervisor
Specialization: Inorganic Chemistry
A DFT study of hybrid silicophosphates reactivity
Supervisor: doc. Mgr. Markéta Munzarová, Dr. rer. nat.
Předložený projekt navazuje na diplomovou práci Mgr. Jakuba Nagyho "Teoretické studium hybridních fosfosilikátových materiálů" obhájenou na Ústavu chemie PřF MU v lednu 2022. Výpočty, které byly v práci provedeny, vedly k vytvoření sady cyklických modelů silikofosfátů s křemíkem v koordinaci 4, 5, nebo 6 s postupnou náhradou několika fosfátových skupin acetáty. Dále ukázaly souvislosti mezi chemickým stíněním centrálního atomu křemíku, úhly mezi vazbami, jichž se centrální křemík účastní, a chemickou identitou substituentů. Hlavní otázkou experimentalistů na počátku celého projektu však bylo pochopení snížené reaktivity silikofosfátů vzhledem k tvorbě hypervalentních struktur, jsou-li některé z fosfátových skupin v reaktantu v koordinaci 4 nahrazeny acetáty. Studium mechanismu reakce čtyřkoordinovaného "čistého" vs. hybridního silikofosfátu s vazebným partnerem bude hlavní náplní předkládaného doktorského projektu. Pro vybranou sadu čtyřkoordinovaných čistých a hybridních silikofosfátů bude metodou DFT modelován povrch reakční potenciální energie, identifikovány tranzitní stavy s dostatečně nízkou energií a jim příslušející produkty. Konečným výstupem předpokládaných publikací bude pochopení zákonitostí mezi identitiou a konformací reaktantu a výškou aktivační bariéry pro příslušnou kondenzační reakci.
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Functional metal organic frameworks and supramolecular assemblies
Supervisor: doc. Mgr. Marek Nečas, Ph.D.
The research is focused on the synthesis of new polytopic ligands and their utilization in the construction of functional coordination polymers (porous, luminescent). The attention is given to robust architectures of MOFs, which can be exploited as matrices for crystallization of small molecules (crystalline sponges). Another line of research includes the search for a functional connection between metal complexes and organic macrocycles and molecular clips. Using a rotating anode dual-wavelength X-ray diffractometer, we are able to determine structures even of very tiny crystals and of very complex systems with large unit cells.
Supervisor
Charged silicon phosphates and phosphonates and their application in heterogeneous catalysis.
Supervisor: Mgr. Aleš Stýskalík, Ph.D.
1. Prepare a literature survey on charged molecular silicon phosphates and phosphonates.
2. Synthesize new charged compounds containing Si-O-P bonds.
3. Characterize the molecular compounds by appropriate methods.
4. Apply the prepared molecules in heterogeneous catalysis with a special focus on reaction between carbon dioxide and epoxides.
Supervisor
Molecular silicon phosphates and phosphonates and their application in porous materials synthesis
Supervisor: Mgr. Aleš Stýskalík, Ph.D.
1. Prepare a literature survey on molecular silicon phosphates and phosphonates.
2. Synthesize new molecular compounds containing Si-O-P bonds.
3. Characterize the prepared molecules with appropriate methods.
4. Apply the molecular compounds in the synthesis of porous silicophosphate and silicophosphonate materials.
Supervisor
Ruthenium and platinum coordination compounds for novel antitumor therapies
Supervisor: prof. RNDr. Radek Marek, Ph.D.
This project includes the synthesis of a series of mono and multinuclear, homo and heteroleptic metallocomplexes containing mono or polydentate ligands possessing hard or soft donor atoms. The molecular and supramolecular structures of compounds are characterized by using modern methods of NMR spectroscopy, ESI-MS, and ITC. Automatic crystallization robotics together with advanced crystallization techniques are employed to grow monocrystals and to reveal further structural details of complexes in the solid state by X-ray diffraction.
References:
1) Sojka, M.; Fojtu, M.; Fialova, J.; Masarik, M.; Necas, M.; Marek, R. Locked and Loaded: Ruthenium(II)-Capped Cucurbit[n]Uril-Based Rotaxanes with Antimetastatic Properties. Inorg. Chem. 2019, 58 (16), 10861-10870. https://doi.org/10.1021/acs.inorgchem.9b01203.
2) Chyba, J.; Novák, M.; Munzarová, P.; Novotný, J.; Marek, R. Through-Space Paramagnetic NMR Effects in Host-Guest Complexes: Potential Ruthenium(III) Metallodrugs with Macrocyclic Carriers. Inorg. Chem. 2018, 57 (15), 8735-8747. https://doi.org/10.1021/acs.inorgchem.7b03233.
3) Szymański, M.; Wierzbicki, M.; Gilski, M.; Jędrzejewska, H.; Sztylko, M.; Cmoch, P.; Shkurenko, A.; Jaskólski, M.; Szumna, A. Mechanochemical Encapsulation of Fullerenes in Peptidic Containers Prepared by Dynamic Chiral Self-Sorting and Self-Assembly. Chemistry - A European Journal 2016, 22 (9), 3148-3155. https://doi.org/10.1002/chem.201504451.
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Synthesis of new molecular systems
Supervisor: prof. RNDr. Jiří Pinkas, Ph.D.
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Specialization: Materials Chemistry
Experimental and theoretical study of advanced functional metal materials
Supervisor: doc. RNDr. Pavel Brož, Ph.D.
EXAMPLES of possible research student projects:
OTHER useful information:
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Investigation of advanced and nanostructured materials
Supervisor: prof. RNDr. Jiří Sopoušek, CSc.
EXAMPLES of student doctoral projects:
More about research can be found on the websites:
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Materials containing bambusurils macrocycles
Supervisor: prof. Ing. Vladimír Šindelář, Ph.D.
Tato disertační práce se bude zabývat přípravou materiálů nesoucích makrocykly bambusurilu. Práce se bude skládat ze syntézy derivátů bambusurilu obsahujících funkční skupiny a jejich připojení k různým materiálům prostřednictvím kovalentních vazeb. Bude testována schopnost připravených materiálů odstraňovat anionty roztoků.
This doctoral thesis will deal with the preparation of materials bearing bambusuril macrocycles. This thesis will consist of the synthesis of bambusuril derivatives containing functional groups and their attachment to different materials through covalent bonds. The resulting materials will be tested for their potency to remove anions from their solutions.
Supervisor
Porous metallosilicates (M = Al, Sn, Zr, Ta) and their catalytic activity
Supervisor: Mgr. Aleš Stýskalík, Ph.D.
OBJECTIVES: These dissertation projects will explore new routes to porous materials based on metallosilicates. The synthetic procedures will be based on non-hydrolytic sol-gel reactions. Developed procedures will be optimized with respect to maximizing surface area and pore volume and controlling chemical composition and catalytic activity in topical catalytic reactions (e.g. ethanol dehydration, ethanol to butadiene conversion, etc.).
EXAMPLES of potential student doctoral projects:
- Synthesis of aluminosilicates for ethanol dehydration
- Synthesis of metallosilicates for conversion of ethanol to 1,3-butadiene
- Synthesis of metal nanoparticles deposited on porous supports for ethanol dehydrogenation
- Synthesis of silicophosphates for ethanol dehydration
Further information at:
https://matchem.sci.muni.cz/laboratore/laborator-syntezy-materialu-a-jejich-prekurzoru-lamps
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Quantum-mechanical and/or thermodynamic modelling in metallic materials
Supervisor: doc. Mgr. Jana Pavlů, Ph.D.
Kromě kvantově mechanického modelování je též možné se zabývat semiempirickým termodynamickým modelování fázových rovnovah a fázových diagramů pomocí metody CALPHAD (Computer Coupling of Phase Diagrams and Thermochemistry). Toto studium je zaměřeno na systémy obsahující intermetalické fáze, neboť tyto struktury vykazují specifické vlastnosti, které významným způsobem ovlivňují chování technologicky významných materiálů. Na základě znalosti stability intermetalických fází v závislosti na teplotě a složení bude možné předvídat chování studovaných systémů.
Informace o tvorných teplech vybraných fází vzhledem k standardním stavům čistých složek potřebné pro modelování pomocí metody CALPHAD je možné získat z kvantově-mechanických výpočtů, a proto je možné se v disertační práci věnovat oběma typům výpočtů.
Pro studium bude vybrána modelová kovová soustava.
Supervisor
Synthesis of porous materials by non-hydrolytic sol-gel methods
Supervisor: prof. RNDr. Jiří Pinkas, Ph.D.
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Specialization: Organic Chemistry
Development of Smart Molecular Capsules
Supervisor: prof. RNDr. Radek Marek, Ph.D.
Low solubility, biostability, and inefficient targeting of otherwise highly promising active pharmaceutical ingredients are often the limiting factors for their final approval for clinical use. We are developing a methodology to suppress these deficiencies by introducing a novel family of biocompatible macrocyclic carriers. The work consists of three main tasks: 1) the synthesis of covalent molecular capsules, 2) using these in analytical studies of their supramolecular host-guest interactions with selected drug candidates, and 3) carrying out further synthetic modifications of the capsules in order to fine-tune their affinity, activity, targeting, and release of drugs, which are based on results of complementary biological studies.
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Chemical synthesis and biological studies of natural products
Supervisor: Mgr. Jakub Švenda, PhD.
For highlights of our current research, please visit http://orgsyn.sci.muni.cz/
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Identification of inhibitors of selected protein kinases
Supervisor: doc. Mgr. Kamil Paruch, Ph.D.
Student navrhne a provede syntézu nových organických sloučenin - potenciálních inhibitorů vybraných proteinových kináz. Nově připravené sloučeniny budou následně testovány ve spolupráci s interními a externími biologickými pracovišti.
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Photochemical tools for targeted release and diagnostics of biologically relevant molecules
Supervisor: prof. RNDr. Petr Klán, Ph.D.
Our group focuses on the development and photophysical studies of novel photochemically active compounds and fluorophores, emphasizing the use of photochemistry to solve some interdisciplinary problems in chemistry, biology, physics, and environmental sciences. The prospective student will use organic synthesis and physico-chemical tools in the course of his/her studies. The (photo)reaction mechanisms will be investigated using state-of-the-art techniques, such as nanosecond laser flash or femtosecond pump-and-probe spectroscopies.
Web page: https://photochem.sci.muni.cz/
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Synthesis of macrocyclic anion receptors and their applications in supramolecular chemistry
Supervisor: prof. Ing. Vladimír Šindelář, Ph.D.
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Synthesis of new analogs of forskolin
Supervisor: doc. Mgr. Kamil Paruch, Ph.D.
Student připraví pomocí organické syntézy (sestávající z více než 15 lineárních kroků) nové syntetické analogy přírodní sloučeniny forskolinu. Tyto nově připravené sloučeniny budou následně testovány - zejména na jejich schopnost (selektivně) aktivovat jednotlivé isoformy adenylylcykláz.
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Specialization: Physical Chemistry
A Quantum Chemical Study of Diels-Alder Reactions
Supervisor: doc. Mgr. Markéta Munzarová, Dr. rer. nat.
Úkolem doktoranda bude prozkoumat povrch potenciální energie vybraných organických elektrocyklizačních reakcí metodou funkcionálu hustoty. Konečným cílem tohoto tématu je - na základě strutur a energií nalezených lokálních minim a tranzitních stavů - pochopit vlivy substituentů na stereochemické chování Diels-Alderových reakcí, vedoucích ke vzniku vybraných enedionů. Téma bude vedeno ve spolupráci s experimentální skupinou organické syntézy na Ústavu chemie PřF (Doc. Kamil Paruch, Dr. Jakub Švenda a Dr. Lukáš Maier).
Supervisor
Coupling of thermal analysis and Knudsen effusion mass spectrometry for study of solid matters
Supervisor: doc. RNDr. Pavel Brož, Ph.D.
EXAMPLES of possible research student projects:
OTHER useful information:
Supervisor
Paramagnetic NMR spectroscopy assisted by DFT calculations: Supramolecular metallocomplexes
Supervisor: prof. RNDr. Radek Marek, Ph.D.
The presence of heavy metal atoms, open-shell character, conformational flexibility, and supramolecular interactions with binding partner must be carefully considered. Thus, the interpretation of NMR experiments requires synergy with various computational tools of quantum chemistry and molecular modelling. The general goal of this study is to apply developed methodology for the structure characterization of new metallocomplexes associated with various cavitands.
Selected references:
1) Novotny, J; Sojka, M; Komorovsky, S; Necas, M; Marek, R, 2016: Interpreting the Paramagnetic NMR Spectra of Potential Ru(III) Metallodrugs: Synergy between Experiment and Relativistic DFT Calculations. JOURNAL OF THE AMERICAN CHEMICAL SOCIETY 138(27), p. 8432-8445, DOI: 10.1021/jacs.6b02749.
2) Chyba, J; Novak, M; Munzarova, P; Novotny, J; Marek, R, 2018: Through-Space Paramagnetic NMR Effects in Host-Guest Complexes: Potential Ruthenium(III) Metallodrugs with Macrocyclic Carriers. INORGANIC CHEMISTRY 57(15), p. 8735-8747, DOI: 10.1021/acs.inorgchem.7b03233.
3) Novotny, J; Prichystal, D; Sojka, M; Komorovsky, S; Necas, M; Marek, R, 2018: Hyperfine Effects in Ligand NMR: Paramagnetic Ru(III) Complexes with 3-Substituted Pyridines. INORGANIC CHEMISTRY 57(2), p. 641-652, DOI: 10.1021/acs.inorgchem.7b02440.
4) Jeremias, L; Novotny, J; Repisky, M; Komorovsky, S; Marek, R, 2018: Interplay of Through-Bond Hyperfine and Substituent Effects on the NMR Chemical Shifts in Ru(III) Complexes. INORGANIC CHEMISTRY 57(15), p. 8748-8759, DOI: 10.1021/acs.inorgchem.8b00073.
5) Bora, PL; Novotny, J; Ruud, K; Komorovsky, S; Marek, R, 2019: Electron-Spin Structure and Metal-Ligand Bonding in Open-Shell Systems from Relativistic EPR and NMR: A Case Study of Square-Planar Iridium Catalysts. JOURNAL OF CHEMICAL THEORY AND COMPUTATION 15(1), p. 201-214, DOI: 10.1021/acs.jctc.8b00914.
Supervisor
Quantum-mechanical analysis of the influence of crystal lattice defects on the properties of materials
Supervisor: doc. Mgr. Jana Pavlů, Ph.D.
Pro získání relevantních fyzikálních charakteristik intermetalických fází a jejich rozhraní (atomová konfigurace, magnetické momenty v oblastech rozhraní, energie tvorby rozhraní atd.) bude použit pseudopotenciálový kód VASP (Vienna Ab initio Simulation Package).
Supervisor
Quantum-mechanical and/or thermodynamic modelling in metallic materials
Supervisor: doc. Mgr. Jana Pavlů, Ph.D.
Kromě kvantově mechanického modelování je též možné se zabývat semiempirickým termodynamickým modelování fázových rovnovah a fázových diagramů pomocí metody CALPHAD (Computer Coupling of Phase Diagrams and Thermochemistry). Toto studium je zaměřeno na systémy obsahující intermetalické fáze, neboť tyto struktury vykazují specifické vlastnosti, které významným způsobem ovlivňují chování technologicky významných materiálů. Na základě znalosti stability intermetalických fází v závislosti na teplotě a složení bude možné předvídat chování studovaných systémů.
Informace o tvorných teplech vybraných fází vzhledem k standardním stavům čistých složek potřebné pro modelování pomocí metody CALPHAD je možné získat z kvantově-mechanických výpočtů, a proto je možné se v disertační práci věnovat oběma typům výpočtů.
Pro studium bude vybrána modelová kovová soustava.
Supervisor
Quantum-mechanical calculations of surface-induced magnetism
Supervisor: doc. Mgr. Jana Pavlů, Ph.D.
Literatura:
[1] M. Friák, V. Buršíková, N. Pizúrová, J. Pavlů, Y. Jirásková, V. Homola, I. Miháliková, A. Slávik, D. Holec, M. Všianská, N. Koutná, J. Fikar, D. Janičkovič, M. Šob, J. Neugebauer, Elasticity of phases in Fe-Al-Ti superalloys: Impact of atomic order and anti-phase boundaries, Crystals 9 (2019) 299.
[2] M. Venkatesan, C. B. Fitzgerald, and J. M. D. Coey, Unexpected magnetism in a dielectric oxide, Nature 430 (2004) 630.
[3] F.-S. Meng, M. Všianská, M. Friák, M. Šob, Surface-induced magnetism in intermetallics: Ni3Ge compound as a case study, Journal of Magnetism and Magnetic Materials 474 (2019) 273.
[4] N. H. Hong, J. Sakai, N. Poirot, and V. Brizé: Room-temperature ferromagnetism observed in undoped semiconducting and insulating oxide thin films, Phys. Rev. B 73 (2006) 132404.
Supervisor
The Spectroscopy and Microscopy of Chemical Compounds in Ice within the Environmental and Pharmaceutical Domains
Supervisor: doc. Mgr. Dominik Heger, Ph.D.
Compounds on ice: Ice and snow, the solid forms of water, are very interesting reaction media. Organic compounds are mostly expelled from the inside to the surface of ice and to the veins between ice crystals. We study the compounds in these compartments by absorption, emission, microscopy, and reactivity. These compartments differ from the original solution: the concentration of impurities increases, and the amount of available protons changes. Electrical potential is created on the interface between ice and the solution during freezing. The above facts strongly affect the frozen compounds, whether in natural or human-induced freezing. We investigate the spectroscopy, speciation and compartmentation of compounds on ice to describe ice - compounds interactions.
Supervisor
Supervisors
- doc. RNDr. Pavel Brož, Ph.D.
- prof. RNDr. Ing. Jaroslav Burda, DrSc.
- Ing. František Foret, DSc.
- prof. RNDr. Josef Havel, DrSc.
- doc. Mgr. Jan Havliš, Dr.
- doc. Mgr. Dominik Heger, Ph.D.
- prof. RNDr. Jan Hrbáč, Ph.D.
- Mgr. Aleš Hrdlička, Ph.D.
- Pia Yasmine Jurček, Ph.D.
- prof. RNDr. Viktor Kanický, DrSc.
- prof. RNDr. Petr Klán, Ph.D.
- Ing. Karel Klepárník, CSc.
- prof. RNDr. Josef Komárek, DrSc.
- RNDr. Pavel Kubáň, DSc.
- doc. RNDr. Petr Kubáň, Ph.D.
- Mgr. Karel Lacina, Ph.D.
- Mgr. Jana Lavická, Ph.D.
- prof. RNDr. Přemysl Lubal, Ph.D.
- prof. RNDr. Radek Marek, Ph.D.
- doc. RNDr. Ctibor Mazal, CSc.
- Mgr. Zdeněk Moravec, Ph.D.
- doc. Mgr. Markéta Munzarová, Dr. rer. nat.
- doc. Mgr. Marek Nečas, Ph.D.
- doc. Mgr. Karel Novotný, Ph.D.
- doc. Mgr. Kamil Paruch, Ph.D.
- doc. Mgr. Jana Pavlů, Ph.D.
- prof. RNDr. Jiří Pinkas, Ph.D.
- prof. Mgr. Jan Preisler, Ph.D.
- prof. RNDr. Jiří Sopoušek, CSc.
- Mgr. Aleš Stýskalík, Ph.D.
- prof. Ing. Vladimír Šindelář, Ph.D.
- prof. RNDr. Mojmír Šob, DrSc.
- Mgr. Jakub Švenda, PhD.
- doc. Mgr. Petr Táborský, Ph.D.
- prof. RNDr. Libuše Trnková, CSc.
- doc. RNDr. Jiří Urban, Ph.D.
- doc. Mgr. Tomáš Vaculovič, Ph.D.
- doc. RNDr. Petr Vaňhara, Ph.D.
- Mgr. Michaela Vašinová Galiová, Ph.D.
Study information
Provided by | Faculty of Science | |
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Type of studies | Doctoral | |
Mode | full-time | Yes |
combined | Yes | |
distance | No | |
Study options | single-subject studies | No |
single-subject studies with specialization | Yes | |
major/minor studies | No | |
Standard length of studies | 4 years | |
Language of instruction | English | |
Collaborating institutions |
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Doctoral board and doctoral committees | ||
Tuition fees
The studies are subject to tuition, fees are paid per academic year |
€3,000 Find out more |