Estudo do comportamento térmico dos antibióticos aminoglicosí­deos estreptomicina e tobramicina / The study of the thermal behavior of the aminoglycoside antibiotics streptomycin and tobramycin

Micalli, Caroline Bevilacqua

10 August 2018

Este trabalho propõe estudos sobre a caracterização do comportamento térmico dos aminoglicosídeos estreptomicina e tobramicina, que são antibióticos bactericidas, utilizados no combate a microorganismos patogênicos, que agem interrompendo a síntese de proteínas. Após a caracterização espectroscópica dos analitos, foram realizadas medidas termogravimétricas, em atmosfera de ar e nitrogênio, que possibilitaram a determinação da estabilidade térmica do fármaco e o reconhecimento das etapas de decomposição. A calorimetria exploratória diferencial forneceu informações a respeito de processos físicos com variação de entalpia. Os gases envolvidos foram analisados usando termogravimetria acoplada à espectroscopia vibracional na região do infravermelho (TG-FTIR), possibilitando a proposta de um mecanismo para sua decomposição térmica. Intermediários de decomposição térmica foram caracterizados por CG-MS e o conjunto de todas essas informações forneceu um possível mecanismo para o comportamento térmico dessas drogas. Também foi sintetizado, caracterizado e analisado por TG, DSC e TG-FTIR, o complexo de tobramicina com o íon Cu+2. / A study regarding the thermal behavior characterization of the aminoglycosides streptomycin and tobramycin which are bactericidal antibiotics is presented. These antibiotics are widely against pathogenic microorganisms and act by interrupting the synthesis of proteins. Thermogravimetric measurements were performed under air and nitrogen conditions. To evaluate thermal stability of the drugs and their decomposition steps. A differential scanning calorimetry provided information on physical processes with enthalpy change. Evolved gas analysis was performed using thermogravimetry coupled to infrared spectroscopy (TG-FTIR), and was used to characterize the gases released during the thermal heating of the samples. Decomposition intermediates were characterized by CG-MS and the set of all these resultsallowed the proposition of a mechanism for the thermal behavior of drugs. The complex of tobramycin with the Cu+2 ion was also synthesized, characterized and analyzed by TG, DSC and TG-FTIR.

aminoglicosídeos

aminoglycosides

análise térmica

decomposition mechanism

estreptomicina

mecanismo de composição

streptomycin

thermal analysis

tobramicina

tobramycin

Estudo do comportamento térmico dos antibióticos aminoglicosí­deos estreptomicina e tobramicina / The study of the thermal behavior of the aminoglycoside antibiotics streptomycin and tobramycin

Caroline Bevilacqua Micalli

10 August 2018

Este trabalho propõe estudos sobre a caracterização do comportamento térmico dos aminoglicosídeos estreptomicina e tobramicina, que são antibióticos bactericidas, utilizados no combate a microorganismos patogênicos, que agem interrompendo a síntese de proteínas. Após a caracterização espectroscópica dos analitos, foram realizadas medidas termogravimétricas, em atmosfera de ar e nitrogênio, que possibilitaram a determinação da estabilidade térmica do fármaco e o reconhecimento das etapas de decomposição. A calorimetria exploratória diferencial forneceu informações a respeito de processos físicos com variação de entalpia. Os gases envolvidos foram analisados usando termogravimetria acoplada à espectroscopia vibracional na região do infravermelho (TG-FTIR), possibilitando a proposta de um mecanismo para sua decomposição térmica. Intermediários de decomposição térmica foram caracterizados por CG-MS e o conjunto de todas essas informações forneceu um possível mecanismo para o comportamento térmico dessas drogas. Também foi sintetizado, caracterizado e analisado por TG, DSC e TG-FTIR, o complexo de tobramicina com o íon Cu+2. / A study regarding the thermal behavior characterization of the aminoglycosides streptomycin and tobramycin which are bactericidal antibiotics is presented. These antibiotics are widely against pathogenic microorganisms and act by interrupting the synthesis of proteins. Thermogravimetric measurements were performed under air and nitrogen conditions. To evaluate thermal stability of the drugs and their decomposition steps. A differential scanning calorimetry provided information on physical processes with enthalpy change. Evolved gas analysis was performed using thermogravimetry coupled to infrared spectroscopy (TG-FTIR), and was used to characterize the gases released during the thermal heating of the samples. Decomposition intermediates were characterized by CG-MS and the set of all these resultsallowed the proposition of a mechanism for the thermal behavior of drugs. The complex of tobramycin with the Cu+2 ion was also synthesized, characterized and analyzed by TG, DSC and TG-FTIR.

aminoglicosídeos

análise térmica

estreptomicina

mecanismo de composição

tobramicina

aminoglycosides

decomposition mechanism

streptomycin

thermal analysis

tobramycin

Chemical vapor deposition of ruthenium-based layers by a single-source approach

Jeschke, Janine, Möckel, Stefan, Korb, Marcus, Rüffer, Tobias, Assim, Khaybar, Melzer, Marcel, Herwig, Gordon, Georgi, Colin, Schulz, Stefan E., Lang, Heinrich

06 March 2017

A series of ruthenium complexes of the general type Ru(CO)2(P(n-Bu)3)2(O2CR)2 (4a, R = Me; 4b, R = Et; 4c, R = i-Pr; 4d, R = t-Bu; 4e, R = CH2OCH3; 4f, R = CF3; 4g, R = CF2CF3) was synthesized by a single-step reaction of Ru3(CO)12 with P(n-Bu)3 and the respective carboxylic acid. The molecular structures of 4b, 4c and 4e–g in the solid state are discussed. All ruthenium complexes are stable against air and moisture and possess low melting points. The physical properties including the vapor pressure can be adjusted by modification of the carboxylate ligands. The chemical vapor deposition of ruthenium precursors 4a–f was carried out in a vertical cold-wall CVD reactor at substrate temperatures between 350 and 400 °C in a nitrogen atmosphere. These experiments show that all precursors are well suited for the deposition of phosphorus-doped ruthenium layers without addition of any reactive gas or an additional phosphorus source. In the films, phosphorus contents between 11 and 16 mol% were determined by XPS analysis. The obtained layers possess thicknesses between 25 and 65 nm and are highly conformal and dense as proven by SEM and AFM studies. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Ruthenium(II) Carbonyl Compounds

Phosphorus

Chemical Vapour Deposition

Thermal decomposition Behaviour

Decomposition Mechanism

ddc:540

Phosphor

Ruthenium

CVD-Verfahren

Chemical vapor deposition of ruthenium-based layers by a single-source approach

Jeschke, Janine, Möckel, Stefan, Korb, Marcus, Rüffer, Tobias, Assim, Khaybar, Melzer, Marcel, Herwig, Gordon, Georgi, Colin, Schulz, Stefan E., Lang, Heinrich

06 March 2017

A series of ruthenium complexes of the general type Ru(CO)2(P(n-Bu)3)2(O2CR)2 (4a, R = Me; 4b, R = Et; 4c, R = i-Pr; 4d, R = t-Bu; 4e, R = CH2OCH3; 4f, R = CF3; 4g, R = CF2CF3) was synthesized by a single-step reaction of Ru3(CO)12 with P(n-Bu)3 and the respective carboxylic acid. The molecular structures of 4b, 4c and 4e–g in the solid state are discussed. All ruthenium complexes are stable against air and moisture and possess low melting points. The physical properties including the vapor pressure can be adjusted by modification of the carboxylate ligands. The chemical vapor deposition of ruthenium precursors 4a–f was carried out in a vertical cold-wall CVD reactor at substrate temperatures between 350 and 400 °C in a nitrogen atmosphere. These experiments show that all precursors are well suited for the deposition of phosphorus-doped ruthenium layers without addition of any reactive gas or an additional phosphorus source. In the films, phosphorus contents between 11 and 16 mol% were determined by XPS analysis. The obtained layers possess thicknesses between 25 and 65 nm and are highly conformal and dense as proven by SEM and AFM studies. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/540

ddc:540

Phosphor; Ruthenium; CVD-Verfahren

Relation between surface structural and chemical properties of platinum nanoparticles and their catalytic activity in the decomposition of hydrogen peroxide

Serra Maia, Rui Filipe

26 September 2018

The disproportionation of H₂O₂ to H₂O and molecular O₂ catalyzed by platinum nanocatalysts is technologically very important in several energy conversion technologies, such as steam propellant thrust applications and hydrogen fuel cells. However, the mechanism of H₂O₂ decomposition on platinum has been unresolved for more than 100 years and the kinetics of this reaction were poorly understood. Our goal was to quantify the effect of reaction conditions and catalyst properties on the decomposition of H₂O₂ by platinum nanocatalysts and determine the mechanism and rate-limiting step of the reaction. To this end, we have characterized two commercial platinum nanocatalysts, known as platinum black and platinum nanopowder, and studied the effect of different reaction conditions on their rates of H₂O₂ decomposition. These samples have different particle size and surface chemisorbed oxygen abundance, which were varied further by pretreating both samples at variable conditions. The rate of H₂O₂ decomposition was studied systematically as a function of H₂O₂ concentration, pH, temperature, particle size and surface chemisorbed oxygen abundance. The mechanism of H₂O₂ decomposition on platinum proceeds via two cyclic oxidation-reduction steps. Step 1 is the rate limiting step of the reaction. Step 1: Pt + H₂O₂ → H₂O + Pt(O). Step 2: Pt(O) + H₂O₂ → Pt + O₂ + H₂O. Overall: 2 H₂O₂ → O₂ + 2 H₂O. The decomposition of H₂O₂ on platinum follows 1st order kinetics in terms of H₂O₂ concentration. The effect of pH is small, yet statistically significant. The rate constant of step 2 is 13 times higher than that of step 1. Incorporation of chemisorbed oxygen at the nanocatalyst surface resulted in higher initial rate of H₂O₂ decomposition because more sites initiate their cyclic process in the faster step of the reaction. Particle size does not affect the kinetics of the reaction. This new molecular-scale understanding of the decomposition of H₂O₂ by platinum is expected to help advance many energy technologies that depend on the rate of H₂O₂ decomposition on nanocatalysts of platinum and other metals. / Ph. D. / Platinum nanomaterials are indispensable to catalyze a variety of industrial and technological processes ranging from catalytic conversion of carbon monoxide (CO), hydrocarbons, and nitrogen oxides (NO_x) in modern automobiles to energy production by hydrogen fuel cells and thrust generation in steam propellers. These technological innovations have a tremendous impact in modern society, including the areas of transportation, energy supply, soil and water quality, environmental remediation and global climate change. The decomposition of hydrogen peroxide (H₂O₂) to water (H₂O) and oxygen (O₂) on platinum nanomaterials is of particular importance because it affects the efficacy of many technological applications, such as hydrogen peroxide steam propellers and hydrogen fuel cells. However, the reaction pathway and kinetics of H₂O₂ decomposition on platinum were only partly understood. My goal was to understand how the reaction conditions and the nanocatalyst properties control the mechanism and kinetics of platinum-catalyzed hydrogen peroxide decomposition. To do that we characterized the atomic scale structural and chemical properties of two different platinum nanocatalysts, known as platinum black and platinum nanopowder and evaluated the effect of their properties in their catalytic activity. Our characterization studies were used to understand the reactivity of these two platinum nanocatalysts in the decomposition of H₂O₂, which we evaluated separately in laboratory studies. Establishing relationships between the catalyst properties and their activity, as we have done in this work for platinum nanocatalysts in the decomposition of hydrogen peroxide, has the potential to improve nanocatalyst design and performance for those applications.

Catalysis

Hydrogen Peroxide Decomposition

Metal Nanoparticles

Metal Nanocatalysts

Crystal Structure

Surface Chemistry

H2O2 decomposition Mechanism

H2O2 Decomposition Kinetics

Catalytic Activity of Platinum

Zeitaufgelöste inelastische Neutronenstreuung an entmischenden Silber-Natriumchlorid-Einkristallen / Time-resolved inelastic neutron scattering from demixing silver-sodium-chloride single crystals

Caspary, Dirk

31 October 2002

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Neutronenstreuung

inelastische Neutronenstreuung

Phononen

zeitaufgelöste Streumethoden

stroboskopische Messungen

spinodale Entmischung

Silberchlorid-Natriumchlorid

AgCl-NaCl

Entmischungsmechanismen

Phasentrennung

neutron scattering

inelastic neutron scattering

time-resolved scattering

stroboscopic technique

spinodal decomposition

silver chloride

sodium chloride

AgCl-NaCl

mixed crystals

demixing processes

decomposition processes

demixing mechanism

decomposition mechanism

phase separation

35.10

33.64

SD 000: Physikalische Chemie