Nonhydrolytic sol-gel syntheses of nanoporous metal oxides, phosphates, and silicates. Synthesis and assembly of molecular building blocks into new materials. Sonochemical methods of nanoparticle synthesis, synthesis of alloy nanoparticles, synthesis of inorganic-organic complex materials, coordination and modified polymers and supramolecular entities. Surface mounted functional molecules. All the methods developed will be utilized directly for the fabrication of nanostructures, advanced materials and devices.
Characterization and optimization of the functional properties of nanostructures for catalysis, nanoelectronics, nanophotonics and (bio)sensing; and their correlation with compositional, morphological, and structural parameters. Theoretical ab initio electronic structure calculations of structural, magnetic, and thermodynamic properties of materials. Novel and unique properties of nanostructures not observable in conventional materials and microstructures open ways to qualitatively new applications.
Development of methods and techniques into higher functional integrated systems, optimized nanocatalysts, soldering formulation based on nanoalloy particles, nano- and micro-analytical systems and sensors and advanced materials for them. Nanostructures implemented into these systems will enhance the performance and efficiency of devices and systems and widen the areas for their applications e.g. in catalysis, separation, soldering, mapping and imaging, biosensing, biorecognition.
Development of the techniques and methodologies for analysis of nanomaterials/nanostructures and for diagnostics of their properties – new techniques of elemental mapping, microanalysis, MS surface imaging, medical diagnostics, and biosensing. This will be used to meet the other objectives of the Advanced Nanotechnologies and Microtechnologies Research Programme and characterization of nano- and micro-structures in general.
The preparation of nanomaterials by means of ultrasound and thermolytic methods – synthesis of nanoscopic metals, alloys, and metal oxides from newly designed precursors. The study of the mechanisms of sonochemical and thermolytic transformations of molecular precursors to solid-state products and ways to control these reactions. Emphasis on gaining control over the chemical constitution, phase composition, and morphology of the synthesized nanoparticles.
HRTEM image of the nanoalloy particles Cu20Ni
Synthesis of inorganic-organic materials – complexes, coordination polymers, modified polymers and supramolecular systems.
The development of methods for the preparation of molecular building blocks for the construction of new functional materials using the bottom-up approach. The complete characterization of the structure of new molecular species suitable for forming higher molecular, supramolecular, polymeric, and nanostructured systems. Studies of molecular features providing functionalities for binding or cross-linking leading to porous materials, metallo-organic, coordination and organic polymers. Studies of chemical properties including intermolecular interactions and self-organization properties. Tuning physico-chemical properties and experimental conditions influencing precursor reactivity for kinetic control of reactions. The expected applications are mainly aimed at catalysis, opto-electronics, nano-solders, gas storage, sensors in bio-analytical chemistry, self-assembled monolayers, the development of molecular machines, etc.
The development of methods and methodologies for the analysis of nanomaterials, nanostructures, for measuring their properties and the development of new analytical/diagnostic equipment and components. To surpass the limits of individual methods and the ambiguities of their results on the local characterization of individual nanoobjects the combinations of more analytical techniques and procedures will be developed.
Methods, such as desorption mass spectrometry with nanoparticle matrix (MALDI/SALDI TOF MS), high–throughput off-line analysis of microcolumn fractions (CE/HPLC – MALDI TOF MS), simultaneous detection: MALDI/ICP MS, fluorescence, capillary electrophoresis with laser-induced fluorescence detection (CE-LIF) will be developed.
Mass spectrometry imaging and laser ablation-ICP-MS and Laser Induced Breakdown Spectroscopy (LIBS) elemental mapping will be applied to many diverse types of samples, such as corroded layers for structural materials of molten salt reactors (MSR), geological and archaeological samples, biominerals and biological samples.
Nonhydrolytic sol-gel syntheses of nanoporous metal oxides, phosphates, and silicates. Synthesis and assembly of molecular building blocks into new materials. Sonochemical methods of nanoparticle synthesis, synthesis of alloy nanoparticles, synthesis of inorganic-organic complex materials, coordination and modified polymers and supramolecular entities. Surface mounted functional molecules. All the methods developed will be utilized directly for the fabrication of nanostructures, advanced materials and devices.
Characterization and optimization of the functional properties of nanostructures for catalysis, nanoelectronics, nanophotonics and (bio)sensing; and their correlation with compositional, morphological, and structural parameters. Theoretical ab initio electronic structure calculations of structural, magnetic, and thermodynamic properties of materials. Novel and unique properties of nanostructures not observable in conventional materials and microstructures open ways to qualitatively new applications.
Development of methods and techniques into higher functional integrated systems, optimized nanocatalysts, soldering formulation based on nanoalloy particles, nano- and micro-analytical systems and sensors and advanced materials for them. Nanostructures implemented into these systems will enhance the performance and efficiency of devices and systems and widen the areas for their applications e.g. in catalysis, separation, soldering, mapping and imaging, biosensing, biorecognition.
Development of the techniques and methodologies for analysis of nanomaterials/nanostructures and for diagnostics of their properties – new techniques of elemental mapping, microanalysis, MS surface imaging, medical diagnostics, and biosensing. This will be used to meet the other objectives of the Advanced Nanotechnologies and Microtechnologies Research Programme and characterization of nano- and micro-structures in general.
The preparation of nanomaterials by means of ultrasound and thermolytic methods – synthesis of nanoscopic metals, alloys, and metal oxides from newly designed precursors. The study of the mechanisms of sonochemical and thermolytic transformations of molecular precursors to solid-state products and ways to control these reactions. Emphasis on gaining control over the chemical constitution, phase composition, and morphology of the synthesized nanoparticles.
HRTEM image of the nanoalloy particles Cu20Ni
Synthesis of inorganic-organic materials – complexes, coordination polymers, modified polymers and supramolecular systems.
The development of methods for the preparation of molecular building blocks for the construction of new functional materials using the bottom-up approach. The complete characterization of the structure of new molecular species suitable for forming higher molecular, supramolecular, polymeric, and nanostructured systems. Studies of molecular features providing functionalities for binding or cross-linking leading to porous materials, metallo-organic, coordination and organic polymers. Studies of chemical properties including intermolecular interactions and self-organization properties. Tuning physico-chemical properties and experimental conditions influencing precursor reactivity for kinetic control of reactions. The expected applications are mainly aimed at catalysis, opto-electronics, nano-solders, gas storage, sensors in bio-analytical chemistry, self-assembled monolayers, the development of molecular machines, etc.
The development of methods and methodologies for the analysis of nanomaterials, nanostructures, for measuring their properties and the development of new analytical/diagnostic equipment and components. To surpass the limits of individual methods and the ambiguities of their results on the local characterization of individual nanoobjects the combinations of more analytical techniques and procedures will be developed.
Methods, such as desorption mass spectrometry with nanoparticle matrix (MALDI/SALDI TOF MS), high–throughput off-line analysis of microcolumn fractions (CE/HPLC – MALDI TOF MS), simultaneous detection: MALDI/ICP MS, fluorescence, capillary electrophoresis with laser-induced fluorescence detection (CE-LIF) will be developed.
Mass spectrometry imaging and laser ablation-ICP-MS and Laser Induced Breakdown Spectroscopy (LIBS) elemental mapping will be applied to many diverse types of samples, such as corroded layers for structural materials of molten salt reactors (MSR), geological and archaeological samples, biominerals and biological samples.
list / cards
Material synthesis (glove box, ultrasonic processor, tube furnaces, high-pressure autoclaves, microwave reactors); diffraction techniques (single-crystal X-ray diffractometer at variable temperatures); elemental analyses (ICP/OES spectrometer, ICP/MS spectrometer); mass spectrometry (TOF and quadrupole mass spectrometers); vibrational spectroscopy (FT-IR spectrometer, FT-Raman spectrometer); laser ablation systems; molecular spectroscopy (UV/Vis spectrometers, spectrofluorimeter); nuclear magnetic resonance (solution and solid-state NMR spectroscopy), computer cluster consisting of ten linked computers, WIEN2K, VASP and ABINIT codes; thermal analysis (DSC/DTA), high-temperature Knudsen effusion mass spectrometry (KEMS).
Supervisor: prof. Mgr. Jan Preisler, Ph.D.
Consultants: Mgr. Antonín Bednařík, Ph.D.
Mass spectrometry imaging (MSI) exploits the ability of mass spectrometry to identify molecules according to their specific mass and image their distribution across the sample. The method allows direct visualization of endogenous compounds (lipids, proteins, saccharides) as well as exogenous drugs and their metabolites. The aim of the research will be development of a suitable matrix-assisted laser desorption/ionization (MALDI) MSI method for the study of distribution and the effect of chosen drug selected tissues and cell lines. Special attention will be devoted to sample preparation and matrix deposition (spray, sublimation, piezoelectric dispenser). The samples will be supplied by cooperating institutions (e.g. the Department of Experimental Biology, Experimental and Applied Neuropsychopharmacology, Centre for Neuroscience, the Department of Pharmacology, the Regional Centre for Applied Molecular Oncology). The analyzed compounds include endogenous compounds (lipids, glycans) as well as selected drugs.
Keywords: mass spectrometry imaging, MSI, matrix-assisted laser desorption/ionization,MALDI, analysis development
29. ledna 2018 9:46
LECTURE: Dr. Ondrej Hovorka: Models of magnetic nanoparticles for biomedical applications
25. ledna 2018 18:21
WHEN: 30. 01. 2018 WHERE: CEITEC BUT, Purkynova 123, large meeting room SPEAKER: Dr Andriy Marko TALK: Advances in PELDOR…