Global ETD Search

191	Élaboration par ablation laser en milieu liquide de nanoparticules métalliques : caractérisation et modélisation des réponses plasmoniques des nanoparticules d’or et d’argent / Generation of metallic nanoparticles by Pulsed-Laser Ablation in Liquids : Characterization and modelling of the plasmonics responses of gold and silver nanoparticles Resano-Garcia, Amandine 30 November 2016 (has links) Les nanoparticules métalliques (NPs) présentent des propriétés optiques (PO) uniques provenant de l’oscillation collective de leurs électrons. Cet effet se traduit par l'émergence d'une bande plasmon dont les caractéristiques peuvent être modulées par la taille, la forme, la nature des NPs et le milieu hôte. Il existe de nombreuses méthodes pour la préparation de ces NPs, l'une d'entre elles est l'ablation laser en milieu liquide (ALML). Cette technique offre certains avantages comme la simplicité, l’adaptabilité et des NPs dépourvues de contamination. Ses principaux inconvénients sont la productivité et le contrôle de la taille et de la forme des NPs. Ce travail est consacré à l'élaboration de NPs d’Ag par l’ALML et à l'étude théorique de leurs PO. Nous donnons dans ce manuscrit, les résultats de l'optimisation des paramètres d'élaboration conduisant à l'obtention de distributions en NPs reproductibles et contrôlées. Les PO de ces NPs sont mesurées et comparées à des modèles physiques spécifiques basés sur la théorie des milieux effectifs (EMT). L'EMT, telle que le modèle de Maxwell-Garnett, permet de décrire les PO de NPs monodisperses. Cependant, les voies de préparation classiques conduisent inévitablement vers des NPs montrant une distribution de forme et de taille qui induit des changements drastiques sur leurs PO. Le modèle SDEMT est proposée pour le calcul de la fonction diélectrique effective et du coefficient d'absorption de solutions colloïdales de NPs métalliques. Contrairement à Maxwell-Garnett, ce modèle donne une meilleure description des spectres d'absorption et d’ellipsométrie mesurés sur des échantillons contenant des NPs d’Ag et d’Au / Metal nanoparticles (NPs) exhibit unique optical properties (OP) coming from the collective oscillations of their electrons. This effect is translated by the emergence of a band of plasmon, the characteristics which can be modulated by the size, the shape and the nature of the NPs as well as by the environment of the host. There are many methods for the preparation of NPs, and one of them is the pulsed-laser ablation in liquid (PLAL). This technique offers some advantages such as simplicity, versatility and surface NP without contamination (reducing agent residues and/or stabilizers). Its main drawbacks are the lacks of productivity and control of the NP size and shape. This work is devoted to elaboration of Ag NPs by PLAL and theoretical investigation of their OP. We give here the results about the optimization of elaboration parameters leading to obtaining reproducible and controlled distributions of Ag NPs. The OP of these NPs are measured and compared to specific physical models based on the effective medium theory (EMT). Classical EMT such as Maxwell Garnett approximation allows describing the OP of monodisperse NPs. However, conventional preparation routes unavoidably conduct to NPs showing a shape and a size distribution which induces drastic changes in the OP. A SDEMT model which considers the shape dispersion is proposed for the calculation of the effective dielectric function and absorption coefficient of colloidal solution of metal NPs in water. Contrary to the conventional theory, this model gives a better description of the measured absorption and ellispometry spectra of sample containing Ag and Au NPs Nanoparticules métalliques Ellipsométrie Plasmonique Ablation laser en milieu liquide Nanoparticules d’argent Nanoparticules d’or Metal nanoparticles Ellipsometry Plasmonic Pulsed-laser ablation in liquid Silver nanoparticles Gold nanoparticles 620.5 530.44
192	Selektiver Laserabtrag von transparenten Elektroden auf Barriereschichten für die organische Photovoltaik Friedrich-Schilling, Niels 19 March 2021 (has links) Der selektive Abtrag dünner Schichten findet für eine Vielzahl technischer Fertigungsverfahren Anwendung. Eine solche ist die Herstellung organischer Solarzellen, bei der mittels Laserabtrag die Funktionsschichten strukturiert werden, um eine monolithische Verschaltung zu erreichen. Aus Gründen der Lebensdauerverbesserung und zur Kostenreduktion gibt es Bestrebungen verschiedene Funktionalitäten wie Trägermaterial der Solarzellen und Wasserdampfbarriere zusammenzuführen. Im Rahmen der vorliegenden Dissertation wird der Abtrag von elektrisch leitfähigen, transpa-renten Schichten auf einer Wasserbarriereschicht aus Siliziumnitrid untersucht. Das Ziel ist ein vollständiger Abtrag der Elektrode zur elektrischen Separation, bei gleichzeitiger Erhaltung der Barriereeigenschaften der darunterliegenden Schicht. Die Untersuchungen zum Abtragsverhal-ten zeigen Schwankung in der Abtragsqualität der Elektrode. Mit Hilfe von Raman-Spektroskopie und der entwickelten Kontrastscan Methode kann gezeigt werden, dass diese Inhomogenität von Bereichen schwankender Brechzahl in der verwendeten Polyethylentereph-thalatfolie verursacht sind. Diese entstehen bei der Herstellung der Folie durch den Prozess des Verstreckens, um eine thermische Stabilisierung zu erreichen. Zur Entwicklung eines tieferen Verständnisses der Einflüsse auf die Abtragsqualität wird ein Simulationsmodell entwickelt. Es simuliert die optischen Gegebenheiten des gesamten Schichtverbunds und nutzt die ermittelten, lokal absorbierten Leistungen für die Berechnung der thermomechanischen Gegebenheiten in den Schichten nach dem Zwei-Temperatur-Modell. An Hand von Abtragsergebnissen zum Elektrodensystem Indiumzinnoxid (ITO) werden die Er-gebnisse des entwickelten Simulationsmodells mit dem bekannten Modell zur Absorption nach Lambert-Beer verglichen. Für ITO und einen weiteren Elektrodentyp, genannt Dielektrikum-Metall-Dielektrikum (DMD), wird die Übereinstimmung von Simulation und experimentellen Er-gebnissen zur Abtragsschwelle, der Breite des Elektrodenabtrags und zur Beeinflussung der Barriereschicht gegenübergestellt und diskutiert. Auf Basis der Erkenntnisse aus dem entwi-ckelten Simulationsmodell ist es gelungen prozesstechnische Anpassungen zu identifizieren, welche die Auswirkungen der lokalen Brechzahlschwankungen reduzieren. Durch Überführung der entwickelten Prozessabfolge auf eine Rolle-zu-Rolle-Bearbeitung wird schließlich die Ska-lierbarkeit nachgewiesen.:1 Einleitung 2 Stand der Technik 2.1 Herstellung organischer Solarzellen 2.2 Verkapselung organischer Elektronik 2.3 Flexible Barrieren 2.4 Laserprozessierung von funktionalen Schichten in der organischen Elektronik 2.5 Laserprozessierung auf flexiblen Barrieren 3 Motivation 4 Grundlagen 4.1 Physikalsiche Grundlagen 4.1.1 Verhalten elektromagnetischer Wellen an Grenzflächen 4.1.2 Lichtinterferenz und Transfermatrixmethode 4.1.3 Energieeintrag durch Absorption 4.1.4 Physikalische Effekte bei der Laser-Materie-Wechselwirkung 4.1.5 Das Zwei-Temperatur-Modell 4.1.6 Zusammenhang von Elektronendichte und Absorption 4.1.7 Generierung freier Ladungsträger 4.2 Materialgrundlagen 4.2.1 Herstellung von thermisch stabilisierten PET 4.2.2 Aufbau des verwendeten Barrieresystem 4.2.3 Herstellung und Eigenschaften der verwendeten Schichten 5 Experimentelle Arbeit und Simulation 5.1 Mess- und Analysemethoden 5.1.1 Spektrale Charakterisierung der Elektrodenschichten 5.1.2 Auflichtmikroskopie 5.1.3 Konfokalmikroskopie 5.1.4 Test auf Barriereintegrität 5.1.5 Messung des Isolationswiderstands 5.1.6 Parametertest an funktionellen Solarzellen 5.2 Laserbearbeitung 5.2.1 Laserauswahl 5.2.2 Strahlformung 5.2.3 Untersuchungen des Laserabtrags 5.2.4 Versuchsaufbau 5.3 Simulationsmodell 5.3.1 Simulationsmodell mit Absorption nach Lambert-Beer 5.3.2 Simulationsmodell mit Absorption durch Interferenzeffekten 6 Ergebnisse und Diskussion 6.1 Optische Eigenschaften der Schichten und Ermittlung von Kennwerten 6.2 Strahlcharakterisierung 6.3 Kontrastscan 6.4 Prozessentwicklung 6.4.1 Abtragsschwelle der Barriere 6.4.2 Laserabtrag der ITO-Elektrode 6.4.3 DMD-Bearbeitung 6.5 Rolle zu Rolle Prozessierung 6.5.1 Charakterisierung des Bandmaterials 6.5.2 Einzelpulsabtrag 6.5.3 Prozessfenster und Überführung auf die R2R-Laseranlage 7 Zusammenfassung 8 Literaturangaben 9 Anhang 9.1 Strahlvermessung zur Gaußsche Energieverteilung 9.2 Verwendung des VORTEX doE – Justage und resultierende Energieverteilung 9.3 Generierung einer TopHat Verteilung mit dem FBS DOE 9.4 ITO Abtrag mit dem Vortex-DOE 9.5 Prozessieren der DMD Varianten mit Alternative Energieverteilungen 9.6 Abtragsschwellen für Intensitäten 9.7 Weitere elektrische Ergebnisse info:eu-repo/classification/ddc/620 ddc:620
193	Matrixunabhängige Elementbestimmung in Polymeren mittels Massenspektrometrie mit Induktiv Gekoppeltem Plasma nach Laserablation Deiting, Daniel 23 June 2017 (has links) Die Analyse von organischen Polymeren mittels Massenspektrometrie mit induktiv gekoppeltem Plasma nach Laserablation unterliegt starken Matrixeffekten. Mögliche Korrekturmodelle sollten basierend auf der tatsächlich ablatierten Elementmasse sowie der Signalintensität des Kohlenstoffisotops C-13 (13C-Korrektur) entworfen werden. Damit die 13C-Korrektur erfolgreich verlaufen kann, ist ein direkter Zusammenhang zwischen ablatiertem Kohlenstoff und gemessenem 13C-ICP-MS Signal erforderlich. Dies wurde überprüft, indem unter Anwendung der konfokalen Mikroskopie das Ablationskratervolumen bestimmt und der ablatierte Kohlenstoff berechnet wurde. Dieser Zusammenhang konnte sowohl für undotierte, wie auch für elementdotierte Polymere und die Verwendung verschiedener Ablationsgase (Helium, Argon und Sauerstoff) ermittelt werden. Eigens hergestellte polymere elementdotierte Standardmaterialien wurden hinsichtlich der Matrixeffekte charakterisiert. Als größter Einflussfaktor stellte sich die unterschiedliche Ablationsrate bei der Ablation verschiedener Polymere heraus. Unter Anwendung der tatsächlich ablatierten Elementmasse sowie unter Anwendung der 13C-Korrektur konnte die Matrixabhängigkeit deutlich verringert werden. info:eu-repo/classification/ddc/540 ddc:540
194	Laser Ablation Inductively Coupled Plasma Mass Spectrometry and Raman Spectroscopy Imaging of Biological Tissues Gorishek, Emma Lee 05 1900 (has links) Laser Ablation Inductively coupled plasma mass spectrometry (LA-ICP-MS) and Raman spectroscopy are both powerful imaging techniques. Their applications are numerous and extremely potential in the field of biology. In order to improve upon LA-ICP-MS an in-house built cold cell was developed and its effectiveness studied by imaging Brassica napus seeds. To further apply LA-ICP-MS and Raman imaging to the field of entomology a prong gilled mayfly (Ephemeroptera: Leptophlebiidae) from the Róbalo River, located on Navarino Island in Chile, was studied. Analysis of both samples showcased LA-ICP-MS and Raman spectroscopy as effective instruments for imaging trace elements and larger molecules in biological samples respectively. LA-ICP-MS Raman imaging biological tissues mass spectrometry spectroscopy botany entomology Laser ablation. Mayflies. Imaging systems in biology. Raman spectroscopy.
195	[pt] IMPACTOS DE MICROMETEORITOS COM A SUPERFÍCIE DA TERRA: SIMULAÇÕES MEDIANTE ABLAÇÃO POR LASER / [en] IMPACTS OF MICROMETEORITES WITH THE EARTH S SURFACE: SIMULATIONS BY LASER ABLATION 13 July 2020 (has links) [pt] O espaço interplanetário contem partículas de poeira cósmica originárias do meio interestrelar ou que são produtos da erosão de Asteroides, Meteoróides e Cometas. As partículas que chegam à superfície da Terra são chamadas de micro-meteoritos. Os micrometeoritos participam dos processos de erosão da superfície terrestre e, por isso, são estudados para se ter uma melhor compreensão da evolução do nosso planeta e do Sistema Solar. Um novo programa de pesquisa iniciado em 2016 no Departamento de Física da PUC-Rio tem os objetivos de 1) desenvolver um meio experimental para simular os impactos de micrometeoritos com a superfície terrestre e 2) analisar, as mudanças físico-químicas causadas pelos impactos nos minerais terrestres. A fim de simular o impacto dos micrometeoritos, empre-gou-se a técnica de Ablação por Laser, o que permitiu fazer deposições a taxas controladas de energia em áreas determinadas das amostras. Para este trabalho foram escolhidas amostras dos silicatos mais abundantes encontrados na crosta terrestre, como jadeíta, quartzo e feldspato. A ablação dos silicatos foi efetuada em dois meios: amostra no ar ou amostra em H2O. A principal técnica analítica utilizada foi a espectroscopia Raman. Complementarmente foram utilizadas a micros-copia óptica e a perfilometria. Um total de cerca 500 espectros Raman foram obti-dos, e várias bandas para cada amostra nos dois meios, antes e depois da ablação, foram analisadas estatisticamente. A análise energética e morfológica dos impactos por laser mostrou que a técnica de ablação por laser é razoavelmente boa para simular os impactos dos micrometeoritos com a crosta terrestre. A análise dos espetros Raman mostrou que depois da ablação, tanto no ar como em H2O deionizada, os três silicatos apresentaram modificações na intensidade, na largura e na posição do centro de várias das suas bandas principais. Constatou-se que, quando há modificações, o comportamento é o mesmo para todos os silicatos: deslocamento dos centros das bandas para números de onda menores. Os resultados da análise por espectroscopia Raman são encorajantes para a utilização desta técnica na caracterização e interpretação das mudanças espectrais e estruturais na superfície terrestre depois do impacto de micrometeoritos. Este trabalho, no melhor do nosso conheci-mento, nunca foi feito. A perspectiva é dar continuidade a esta linha de pesquisa, aumentando o número de experimentos de ablação por laser e estendendo a análise das amostras irradiadas a outras técnicas de caracterização complementares a espetroscopia Raman (espetroscopia UV-Vis-NIR, FTIR, ....). Além disso, numa fase futura de estudo, serão estudadas amostras mais complexas, onde material orgânico será adicionado aos silicatos já estudados. / [en] The interplanetary space contains particles of cosmic dust that come from the interstellar medium, or that are the product of the erosion of Asteroids, Meteoroids and Comets. The particles that reach the Earth s surface are called micrometeorites. Micrometeorites participate in the erosion processes of the Earth s surface and, therefore, are studied in order to have a better understanding of the evolution of our planet and the Solar System. A new research program was initiated in 2016 in the Department of Physics of PUC-Rio with the objectives of 1) finding an experimental means to simulate the impacts of micrometeorites with the terrestrial surface, and 2) analyzing the physical-chemical changes caused by the impacts on terrestrial minerals. In order to simulate the impact of micrometeorites the Laser Ablation technique was employed, which allowed us to make energy depositions at controlled rates in certain areas of the samples. For this work, we chose samples of the most abundant silicates found in the earth s crust, such as jadeite, quartz and feldspar. The ablation of the silicates was carried out in two medium: the sample in air, and the sample in H2O. The main analytical technique used was Raman spectroscopy. In addition, optical microscopy and profilometry were used. About 500 Raman spectra were obtained, and several bands for each sample and in each medium, before and after ablation, were statistically analyzed. The energetic and morphological analysis of the laser impacts showed that the technique of laser ablation is reasonably good to simulate the impacts of micrometeorites with the terrestrial crust. The analysis of the Raman spectra showed that after the ablation, in air as well as in deionized H2O, all three silicates presented modifications in the intensity, width and position of the center of several of their main bands. It was found that, when there were modifications, the behavior was the same for all silicates: a shift of the center of de bands to smaller wavelengths. The results of the analysis by Raman spectroscopy are encouraging to use this technique in the characterization and interpretation of the spectral and structural changes in the terrestrial surface after the impact of micrometeorites. This work, to the best of our knowledge, has never been done before. Its perspective is to give continuity to this line of research, incrementing the amount of experiments by laser ablation and extending the analysis of the irradiated samples to other characterization techniques that complement Raman spectroscopy (UV-Vis-NIR spectroscopy, FTIR, …). Also, in future studies, more complex samples will be studied, where organic material will be added to the already studied silicates. [pt] ESPECTROSCOPIA RAMAN [en] RAMAN SPECTROSCOPY [pt] MICROMETEORITOS [en] MICROMETEORITES [pt] SILICATOS [en] SILICATES [pt] ABLACAO POR LASER [en] LASER ABLATION [pt] PERFILOMETRIA [en] RAMAN SPECTROSCOPY
196	APLIKACE NANOMATERIÁLŮ PRO VÝVOJ PÁJEK BEZ OLOVA / THE APPLICATION OF NANOMATERIALS FOR LEAD FREE SOLDERS DEVELOPMENT Pešina, Zbyněk January 2012 (has links) The present dissertation is motivated by the search for alternatives of lead-free soldering by nanoparticles of metals and their alloys. The research focuses on the possibility of replacing lead-free solders by nanoparticles. This issue is currently being addressed by the use of lead-free solders but their properties are not entirely equivalent to properties of lead-tin based alloys. The theoretical part of the dissertation first summarizes up-to date knowledge on the development of lead-free alloys currently used for soldering in the electronics. The work compares these lead-free solder candidates with previously used Pb-Sn alloys. The second section of the theoretical part is devoted to nanotechnology that offers possible solutions of problems associated with the use of lead-free solders. The text contains a description of the properties of nanocrystalline materials in comparison with those of compact alloys having the same chemical composition. The possibility of preparation of nanoparticles and potential problems associated with small particle sizes are also presented. Introduction of the experimental part focuses on the preparation of nanoparticles of pure metals and alloys by chemical and physical ways as well as on an instrumentation for characterisation and analysis. Attention is focused on the silver in nanoparticle form that exhibits the low temperature sintering effect, which is thermally activated by decomposition of oxide envelope covering the Ag nanoparticles. This factor is critical for low-temperature sintering and thus also for possible future applications. The thermal effects of the low sintering process were studied by methods of thermal analysis. The preparation of the Cu / Ag nano / Cu joints was carried out in-situ in inert atmosphere and under the action of atmospheric oxygen. In both cases varying conditions of thermal treatment were used. The cross sections of the prepared joints were then used for the metallographic analysis of the local mechanical properties of the resulting silver layer, for the chemical composition evaluation of the resulting layers of the joint, and for the microstructure study. Strength characteristics are represented by testing shear strength of individual joints.
197	Mechanisms of microtubule nucleation in metaphase spindles and how they set spindle size Decker, Franziska 25 September 2018 (has links) Regulation of size and growth is a fundamental problem in biology and often closely related to functionality and fitness. A prominent example is the mitotic spindle, whose size needs to be perfectly tuned to ensure proper chromosome segregation during cell division. It is known that spindle size generally scales with cell volume, most likely as a result of limiting components. However, this relation breaks down in very large cells where spindles have a maximum size. How the size and microtubule mass are set and why spindles show an upper size limit in large cells is still not understood. Spindles mainly consist of highly dynamic short microtubules that turn over very quickly in comparison to the lifetime of the entire structure. Thus, microtubules need to be constantly created throughout the spindle, a process called nucleation. Understanding the role of microtubule nucleation in setting the size of spindles is limited by the fact that little is known about the rate, distribution, and regulation of microtubule nucleation in these structures. This is partly due to the lack of methods to measure microtubule nucleation in spindles. During this work, I developed an assay based on laser ablation to probe microtubule nucleation in monopolar spindles assembled in Xenopus laevis egg extract. Using this new method in combination with quantitative microscopy, I found that microtubule nucleation in these structures is spatially regulated. Furthermore, I observed that nucleation is stimulated by pre-existing microtubules leading to new microtubule growth in their physical proximity. Combining my experimental results on nucleation with theory and further biochemical perturbations, I show that this autocatalytic nucleation mechanism is limited by the availability of active nucleators. In spindles, the amount of active nucleators decreases with distance from the chromosomes. Thus, this mechanism provides an upper limit to spindle size even when resources are not limiting. info:eu-repo/classification/ddc/570 ddc:570
198	UV laser patterning of silicone-based soft electrode grids Jakobsson, Maria January 2023 (has links) Roughly 123 million people worldwide are affected by conditions such as epilepsy, dementia, and cardiovascular diseases. Wearable electrodes are currently used to monitor these conditions short-term. Long-term monitoring would allow for predicting seizures and could be used as a preventive treatment. As opposed to the currently used electrodes, wearables that are intended for long-term use must be soft and flexible in order not to cause harm or discomfort for the user. The electrodes should also have high resolution, meaning that the electrode paths should be as narrow as possible without negatively affecting the performance of the electrode. In this thesis, soft and flexible electrode grids based on silicones are developed using UV laser patterning. Two different methods are evaluated: laser curing of silicones with the addition of a photoinitiator, and laser ablation of conductive composite. The results found in this thesis are that photocuring silicones gives a too low resolution to be useful for patterning soft electrode grids. UV laser ablation on the other hand showed high resolution while the electrodes retained stretchability. / <p>Examensarbetet är utfört vid Institutionen för teknik och naturvetenskap (ITN) vid Tekniska fakulteten, Linköpings universitet</p> Soft electrodes Wearable electrodes UV laser Laser ablation Laser curing Polydimethylsiloxane PDMS Silver flakes Teknisk biologi Teknisk biologi Medical Equipment Engineering Medicinsk apparatteknik
199	Vývoj zařízení a metodiky pro spektrometrii laserem buzeného mikroplazmatu (LIBS) / Development of a device and methodology for Laser-Induced Breakdown Spectroscopy (LIBS) Képeš, Erik January 2021 (has links) Táto práca sa zaoberá prenosom analytických modelov medzi rôznymi systémami spektroskopie laserom indukovanej plazmy (LIBS) a porovnaním LIBS výsledkov získaných na rôznych systémoch. Instrumentácia LIBS aj spracovanie LIBS spektier sú vysoko flexibilné. Bohužiaľ, kvôli týmto flexibilitám sú výsledky získané na jednom LIBS systéme zriedka priamo porovnateľné s výsledkami získanými na inom systéme. Toto je ďalej komplikované rôznymi, často neznámymi, účinkami algoritmov spracovania LIBS spektier. V dôsledku toho sú modely analýzy spravidla špecifické pre systém (a parametre). Prenos analytických modelov medzi rôznými systémami by viedol k významnému zlepšeniu analytických schopností metódy LIBS a k miernemu zníženiu nákladov v priemyselných aplikáciách LIBS. Práca skúma vplyv rôznych stratégií merania metódou LIBS. Naďalej, práca skúma transformáciu získaných LIBS spektier prostredníctvom spracovávania údajov. Práca sa napokon zaoberá prenosom analytických modelov medzi rôznymi LIBS systémami.
200	[pt] ABLAÇÃO POR LASER PULSADO DE ALVOS DE FERRO E NÍQUEL EM ÁGUA E SUAS IMPLICAÇÕES EM ASTROQUÍMICA / [en] PULSED LASER ABLATION OF IRON AND NICKEL TARGETS IN WATER AND ITS IMPLICATIONS IN ASTROCHEMISTRY JOAO GABRIEL GIESBRECHT F PAIVA 02 December 2021 (has links) [pt] A pesquisa aponta para a possibilidade de realizar a reação de redução de CO2 (CO2RR) para a formação de nanomateriais de carbono por ablação a laser pulsado(PLA) de alvos magnéticos de Ferro(Fe) e Níquel(Ni) em água pura deionizada. Os materiais coloidais sintetizados foram caracterizados por diferentes técnicas de espectroscopias ópticas (UVVis, ICP-MS, FTIR e Raman) e microscopia eletrônica de transmissão (TEM), revelando a presença de nanopartículas de óxidos e hidróxidos de metais de transição, junto com nanomaterial orgânico. Esse último, é bem visível por TEM, espectroscopia de raio-X por dispersão em energia (EDS), espectroscopia por perda de energia de elétrons (EELS), e espectroscopia Raman, que indica a presença de carbono amorfo grafítico e vibrações CH. No caso do nanomaterial obtido do Níquel, os resultados FTIR confirmam a presença da fase do hidróxido beta-Ni(OH)2, enquanto as medidas Raman e TEM sugerem também a presença de nano-folhas de Ni(HCO3)2. Os resultados experimentais foram enfim discutidos no contexto da origem e da evolução de moléculas simples e complexas de interesse astroquímico, com foco especial nas espécies potencialmente formadas na superfície de pequenos corpos metálicos do Sistema Solar e grãos de poeira cósmica do meio interestelar. / [en] The proposed research points to the possibility to perform CO2 reduction reaction (CO2RR) to solid carbon nanomaterials by the pulsed laser ablation (PLA) of magnetic target of iron (Fe) and nickel (Ni) in pure deionized water. The synthesized colloidal dispersions were characterized by different optical spectroscopies (UV-Vis, ICP-MS, FTIR and Raman) and transmission electron microscopy (TEM), revealing the presence of nanosized transition metal oxide and hydroxide nanoparticles, together with organic nanomaterial. The latter is well visible by TEM, energy-dispersive X-Ray spectroscopy (EDS), electron energy-loss spectroscopy(EELS), and Raman spectroscopy, which indicates the presence of amorphous graphitic carbon and CH vibrations. In the case of Ni derived nanomaterial, FTIR results confirm the presence of a beta-Ni(OH)2 hydroxide phase, while Raman and TEM measurements suggest also the presence of Ni(HCO3)2 nanosheets. The experimental results were finally discussed in the frame of the origin and evolution of simple and complex molecules of astrochemical interest, with special focus on those species potentially formed on the surface of metallic minor bodies in the solar system and cosmic dust grains in the interstellar medium(ISM). [pt] NANOPARTICULAS MAGNETICAS [pt] INTEMPERISMO ESPACIAL [pt] NANOESTRUTURAS DE CARBONO [pt] ABLACAO POR LASER PULSADO [en] MAGNETIC NANOPARTICLES [en] SPACE WEATHERING [en] CARBON NANOSTRUCTURES [en] PULSED LASER ABLATION

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