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Chemical analysis of a-CSi:H and a-CSiO:H films
Olivová, Lucie ; Franta, Daniel (referee) ; Čech, Vladimír (advisor)
Plasma-enhanced chemical vapor deposition is a promising technology for the preparation of materials in the form of thin films with controlled physical-chemical properties, which can be affected by changing input precursors or deposition conditions as needed. In this thesis, plasma nanotechnology was used to synthesize thin films on silicon wafers. Tetravinylsilane was chosen as a precursor for the synthesis of the films. In addition to pure tetravinylsilane, mixtures of tetravinylsilane with argon and mixtures of tetravinylsilane with oxygen were also used as input precursors for film deposition, in different proportions of the individual component in the deposition mixture. Using chemical analyses, specifically infrared spectroscopy, photoelectron spectroscopy and selected ion techniques, the chemical structure of the prepared films was examined in detail and the dependence of this structure on deposition conditions and input precursors was studied. This thesis confirms, that by changing effective power supplied to the plasma discharge and selecting different input precursors, it is possible to control chemical structure, and thus the properties of the prepared nanolayers.
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DNA - topic for biology or chemistry?
Andělová, Denisa ; Drda Morávková, Alena (advisor) ; Rajsiglová, Jiřina (referee)
This work is focused in teaching DNA. The aim is to determine whether the subject matter of the nucleic acids rather biological in nature, or rather the nature of thechemical. The work is concerned with explaining the concept of nucleic acid and its types and functions, as well as view into the history of teaching about DNA and analyzing the current situation in the CR and abroad. Finally, the opinions of teachers are devoted to assessing and evaluating the results of some studies.
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Chemical analysis of a-CSi:H and a-CSiO:H films
Olivová, Lucie ; Franta, Daniel (referee) ; Čech, Vladimír (advisor)
Plasma-enhanced chemical vapor deposition is a promising technology for the preparation of materials in the form of thin films with controlled physical-chemical properties, which can be affected by changing input precursors or deposition conditions as needed. In this thesis, plasma nanotechnology was used to synthesize thin films on silicon wafers. Tetravinylsilane was chosen as a precursor for the synthesis of the films. In addition to pure tetravinylsilane, mixtures of tetravinylsilane with argon and mixtures of tetravinylsilane with oxygen were also used as input precursors for film deposition, in different proportions of the individual component in the deposition mixture. Using chemical analyses, specifically infrared spectroscopy, photoelectron spectroscopy and selected ion techniques, the chemical structure of the prepared films was examined in detail and the dependence of this structure on deposition conditions and input precursors was studied. This thesis confirms, that by changing effective power supplied to the plasma discharge and selecting different input precursors, it is possible to control chemical structure, and thus the properties of the prepared nanolayers.
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DNA - topic for biology or chemistry?
Andělová, Denisa ; Drda Morávková, Alena (advisor) ; Rajsiglová, Jiřina (referee)
This work is focused in teaching DNA. The aim is to determine whether the subject matter of the nucleic acids rather biological in nature, or rather the nature of thechemical. The work is concerned with explaining the concept of nucleic acid and its types and functions, as well as view into the history of teaching about DNA and analyzing the current situation in the CR and abroad. Finally, the opinions of teachers are devoted to assessing and evaluating the results of some studies.
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Modular System for Elemental Analysis using Laser Spectroscopy
Klempa, Tomáš ; Polach, Pavel (referee) ; Křupka, Ivan (advisor)
This diploma thesis is solved for AtomTrace Company and describes mechanical design of modular system for elemental analysis using laser spectroscopy. Object of this thesis is to create at once compact and modular system, with addition of liquid analysis module. System described in this work came out from current solution and is capable of interaction of new and previous modules. New solution is more economical both in budget and mass, whole system is fully functional and liquid analysis module with flat jet has 40 % stability, as described in experiments. The benefit of this work is possible future integration of system or separate modules into the AtomTrace portfolio and industry applications.
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