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601	Synthèse et vectorisation de biomolécules type Chalcone en vue d'une application anticancéreuse / Synthesis and vectorization of chalcone-type biomolecules for anticancer application Rioux, Benjamin 15 December 2016 (has links) La synthèse et la vectorisation d’agents anticancéreux constituent des axes de recherche majeurs du LCSN. De nombreux composés naturels possèdent des propriétés anticancéreuses, mais ils sont abandonnés en raison de leur manque de sélectivité vis-à-vis des cellules cancéreuses ou de leur faible biodisponibilité. Ainsi, un grand intérêt est actuellement porté sur le développement de médicaments spécifiquement vectorisés vers les cellules cancéreuses. Les vecteurs utilisés dans ce travail sont des dérivés de polyamines et des nano objets de type β-cyclodextrines / nanocristaux de cellulose (β-CD/CNCx). Les polyamines vont permettre un ciblage actif des cellules cancéreuses grâce au système de transport de polyamine (PTS) surexprimé dans ces cellules. Les nano objets vont cibler spécifiquement les tumeurs via un ciblage passif dû à l’effet EPR. Les principes actifs employés dans cette étude sont des flavonoïdes, et plus particulièrement des chalcones. En effet, les flavonoïdes, qui constituent une large famille de composés phénoliques naturels, sont connus pour leurs nombreux effets biologiques comme les activités antioxydantes, anti-inflammatoires et anti-prolifératives.L’intérêt du LCSN à la fois pour les chalcones et les agents anticancéreux nous a conduits à concevoir de nouveaux composés antiprolifératifs vectorisés. Ce travail présente dans un premier temps la synthèse de chalcones et l’obtention de dérivés couplés aux différents vecteurs décrits précédemment (motifs polyaminés,β-CD/CNCx) ; un travail sur la synthèse d’une bis-chalcone via le couplage de Suzuki est également exposé.L’ensemble des molécules obtenues est caractérisé par des analyses RMN 1H, 13C et HRMS. Dans une seconde partie, nous présentons l’ensemble des évaluations biologiques des composés précédemment obtenus. Ces évaluations sont réalisées par un test de viabilité cellulaire (test MTT) sur quatre lignées cancéreuses : deux colorectales (HT-29 et HCT-116) et deux prostatiques (PC-3 et DU-145). / Synthesis and vectorization of anticancer agents are major research themes of LCSN. Many natural compoundspossess anti-cancer properties, but they are dropped because of their lack of selectivity to cancer cells or theirlow bioavailability. Thus, great interest is currently focused on the development of drugs specifically vectorizedto cancer cells. The vectors used in this work are polyamine derivatives and nano-objects type Î²-cyclodextrin /cellulose nanocrystals (Î²-CD/CNCx). Polyamines allow active targeting of cancer cells through the polyaminetransport system (PTS) overexpressed in these cells. Nano-objects specifically target tumors using a passivetargeting due to the EPR effect. Drugs used in this study are flavonoids, especially chalcones. Indeed,flavonoids, which constitute a large family of natural phenolic compounds, are known for their numerousbiological effects such as antioxidant, anti-inflammatory and anti-proliferative activities. The interest of LCSNfor both chalcones and anticancer agents led us to design new vectorized anti-proliferative compounds. Firstly,this work shows the synthesis of chalcones and their derivatives coupled to various above-described vectors(polyamines units, Î²-CD/CNCx); a work on the synthesis of a bis-chalcone through the Suzuki coupling reactionis also exposed. All molecules obtained are characterized by 1H NMR, 13C NMR and HRMS analysis. In thesecond part of this work, we present all biological evaluations of compounds previously obtained. Theseassessments are performed through a cell viability test (MTT test) on four cancer cell lines: two colorectal (HT-29 and HCT-116) and two prostate (PC-3 and DU-145) cell lines. Flavonoïde Antiproliférative Cancer prostatique Cancer colorectal Suzuki Bis-chalcone Cyclodextrine Nanocristaux de cellulose Spermidine Spermine Polyamine Chalcone Flavonoid Anti-proliferative Prostatic cancer Colorectal cancer Suzuki Bischalcone Cyclodextrine Cellulose nanocrystals Spermidine Spermine Polyamine Chalcone 540
602	Etude de nanocristaux unidimensionnels confinés dans des nanotubes de carbone / The investigation of 1D nanocrystals confined in carbon nanotubes Nie, Chunyang 23 September 2016 (has links) Le remplissage des nanotubes de carbone (NTC) est considéré comme une approche relativement simple permettant de synthétiser des nanocristaux du fait de l'effet de confinement 1D imposé par la cavité centrale des NTC, qui peut être seulement de l'ordre du nanomètre ou moins, notamment dans le cas des NTC monoparoi et en particulier des NTC biparois (DWCNT) sur lesquels nous avons concentré nos efforts. De tels nanocristaux devraient avoir des propriétés physiques (électriques, magnétiques) différentes de celles de leurs équivalents à l'état massif du fait de la modification de la coordinence des atomes ou des ions les composant. Parmi les différentes méthodes existantes pour le remplissage des NTC, (in situ pendant la synthèse, a posteriori à partir de solutions), la méthode faisant intervenir des matériaux fondus est la plus populaire pour le remplissage par des matériaux inorganiques. Elle permet en effet d'atteindre des taux de remplissage raisonnablement élevés et demeure assez simple à mettre en œuvre. Cependant, elle fait preuve d'un certain nombre de limitations (techniques) qui posent problème dans le cas de matériaux à haut point de fusion (typiquement > 1000°C), dont la réactivité avec le carbone à haute température pourrait être gênante (carboréduction des oxydes par exemples), ou encore dont la faible mouillabilité vis-à-vis du carbone à l'état fondu est rédhibitoire (métaux par exemple). Il est possible de palier à cette difficulté en procédant par étapes successives et en remplissant d'abord les NTC avec un précurseur puis d'utiliser la cavité interne des NTC comme des nanoréacteurs afin de procéder dans un second temps à une transformation in situ. Dans ces travaux, nous avons étudié (1) le remplissage de DWCNT avec de l'iode ainsi qu'avec différents iodures métalliques en mettant en œuvre essentiellement la méthode des sels fondus. Nous avons étudié en détails l'influence des paramètres physico-chimiques du matériau de remplissage (réactivité chimique sous la forme en particulier du potentiel rédox du couple iodure métallique / métal, mais aussi viscosité, tension de surface, pression de vapeur saturante en milieu fondu) mais aussi du NTC (texture cylindrique ou "en arrêtes de poisson", diamètre, nombre de parois) sur le taux de remplissage. (2) Nous avons étudié en détail un certain nombre de structures inhabituelles de nanomatériaux confinés dans les DWCNT, en faisant appel à la modélisation structurale et à la simulation d'images de microscopie électronique sur la base de ces modèles pour guider notre analyse. (3) Nous avons enfin étudié différentes réactions in situ dans les DWCNT telles que la sulfuration, la réduction sous hydrogène ou encore la fluoration afin de synthétiser des nanocristaux originaux et de les caractériser en détails à l'aide d'outils tels que par exemple le MET Haute Résolution et la spectroscopie de perte d'énergie des électrons (EELS). / Filling carbon nanotubes (CNTs) has been considered as an easy approach to synthesize various nanocrystals since the inserted materials are forced to adopt a nearly one-dimensional morphology arising from their very high aspect ratio, especially in the case of single-walled CNTs (SWCNTs) or double-walled CNTs (DWCNTs). Nanocrystals/nanowires of transition metals, especially those with very narrow diameters, are predicted to exhibit peculiar magnetic property differing from the bulk metals. Filling CNTs provides a possible way for the synthesis of such metal nanocrystals/nanowires. There are several methods for filling CNTs including the in situ method, gas phase method, molten phase method, solution method, etc. Among them, molten phase has been very popular for filling various types of nanotubes due to the possibility to reach high filling rates, simplicity and versatility. However, for materials with high melting point such as metals, it is difficult to insert them into CNTs directly. To solve this problem, we also took advantage of the inner cavity of CNTs which not only templates the growth but also acts as a nanoreactor in order to perform chemical reactions. The insertion of materials with high melting point is typically achieved by first filling CNTs with a precursor, and then transforming the precursor into the desired 1D nanostructure by post-treatments. In this thesis, (i) filling DWCNTs with iodine and various halides via the molten phase method was performed and the influence of the relevant physical and chemical properties of the halides on the filling rate was investigated. The role of the redox potential as a main parameter driving the filling efficiency is pointed out, and explained; (ii) peculiar structures of the nanocrystals confined within DWCNTs were imaged by transmission electron microscopy (TEM) and corresponding modeling of the observed crystal nanostructures and related TEM images were proposed; (iii) different in situ transformations on the iodide-filled DWCNTs were attempted and the chemical composition of the encapsulated 1D nanocrystals before and after post-filling treatments was systematically identified by means of electron energy loss spectroscopy (EELS). Nanotubes de carbone biparois Transformation in situ Remplissage Nanomatériaux hybrides Nanocristaux 1D Double-walled carbon nanotubes (DWCNTs) Filling Hybrid nanomaterials 1D nanocrystals In situ transformation Transmission electron microscopy (TEM) Energy loss electron spectroscopy (EELS)
603	Synthesis, optical and morphological characterization of pbse quantum dots for diagnostic studies: a model study Ouma, Linda Achiengꞌ January 2013 (has links) >Magister Scientiae - MSc / In this study PbSe quantum dots (QDs) were successfully synthesized via the organometallic and aqueous routes. Optical characterization was carried out using photoluminescence (PL) spectroscopy, structural and morphological characterization were carried out using X-ray diffraction (XRD) and transmission electron microscopy (TEM). Energy-dispersive X-ray spectroscopy (EDS) was used to determine the composition of the QDs. All the synthesized QDs were found to have emissions within the near-infrared region of the spectrum (≥1000 nm) with most of them being less than 5 nm in size. The aqueous synthesized QDs had a perfect Gaussian emission spectrum with a FWHM of ~23 nm indicating pure band gap emission and narrow size distribution respectively. The QDs were determined to have a cubic rock-salt crystal structure consistent with bulk PbSe. The aqueous synthesized QDs were however not stable in solution with the QDs precipitating after approximately 48 h. The organometallic synthesized QDs were transferred into the aqueous phase by exchanging the surface oleic acid ligands with 11-mercaptoundecanoic acid ligands. The ligand exchanged QDs were however stable in solution for over two weeks. The effects of reaction parameters on the optical and structural properties of the organometallic synthesized QDs were investigated by varying the reaction time, temperature, ligand purity, lead and selenium sources. It was observed that larger QDs were formed with longer reaction times, with reactions proceeding faster at higher reaction temperatures than at lower temperatures. Varying the ligand purity was found to have minimal effects on the properties of the synthesized QDs. The lead and selenium sources contributed largely to the properties of the QDs with lead oxide producing spherical QDs which were smaller compared to the cubic QDs produced from lead acetate. TBPSe was seen to produce smaller QDs as compared to TOPSe. The cytotoxity of the synthesized QDs was determined following the WST-1 cell viability assay with the QDs being found to be non-toxic at all the tested concentrations PbSe Quantum dots (QDs) Semiconductor nanocrystals (NCs) Near-infrared (NIR) Organometallic synthesis Aqueous synthesis Ligand exchange Photoluminescence spectroscopy (PL) 3-Mercaptopropionic acid (MPA) 11-Mercaptoundecanoic acid (MUA) Water-soluble tetrazolium salt (WST-1)
604	Propriétés de luminescence et caractérisation structurale de films minces d'oxydes de silicium dopés au cérium et codopés cérium-ytterbium / Photoluminescence properties and structural characterization of cerium-doped and cerium-ytterbium co-doped silicon oxide thin films Weimmerskirch, Jennifer 11 December 2014 (has links) Ce travail de thèse concerne l’élaboration et la caractérisation chimique et structurale de couches minces d’oxyde de silicium dopées avec des terres rares ainsi que l’étude de leurs propriétés de photoluminescence. Les films sont dopées avec du cérium. Le co-dopage cérium et ytterbium est également étudié dans le cas des couches de SiO2. Il est montré que dans les oxydes de composition SiO1, le cérium joue un rôle important dans la structure et l’organisation chimique de l’oxyde, notamment en favorisant la démixtion de l’oxyde. L’exposition à un faisceau laser focalisé engendre une démixtion locale favorisée par le cérium. Pour les films minces de SiO1,5 contenant à la fois du cérium et des nanocristaux de silicium, les différentes étapes de la séparation de phase entre nanocristaux de Si et agrégats riches en Ce ont été mises en évidence, notamment par sonde atomique tomographique et par microscopie électronique à balayage en transmission. Les propriétés de luminescence des dopants sont discutées en lien avec la microstructure de la matrice hôte. Pour tous ces systèmes, la formation d’un silicate de cérium de composition Ce2Si2O7 à haute température (> 1100°C) a été mise en évidence. Le cérium présent sous forme d’ions isolés ou dans un silicate émet intensément dans le bleu (400 nm) à température ambiante ce qui pourrait être intéressant pour le développement de diodes bleues en filière Si. Enfin, un transfert d’énergie des ions Ce3+ vers les ions Yb3+ a été mis en évidence dans les films minces de SiO2 ouvrant ainsi la voie à de possibles applications dans le domaine du solaire photovoltaïque / This thesis concerns the structural characterization and the photoluminescence properties of thin silicon oxide films doped with rare earths The films are doped with cerium. The co-doping with both cerium and ytterbium is also studied in the case of SiO 2 layers. It is shown that in oxides with composition SiO1, cerium plays an important role in the structure and chemical organization of the oxide, in particular by promoting phase separation of the oxide. The exposure to a focused laser beam generates a local demixtion favored by cerium. For thin SiO1,5 films containing both cerium and silicon nanocrystals, we are able to follow the phase separation occuring between Si nanocrystals and Ce rich aggregates using both atom probe tomography and scanning transmission electron microscopy. The luminescence properties of dopants are discussed in connection with the microstructure of the host matrix. For all these systems, the formation of a cerium silicate with composition Ce2Si2O7 is observed at high temperature (> 1100 ° C). The cerium present either as isolated Ce3+ ions or in a silicate emits intensely at 400 nm (blue) at room temperature, which might be of interest for the development of blue light emitting diodes fully compatible with the Si technology. Finally, an energy transfer from Ce3+ ions to Yb3+ ions is demonstrated in thin SiO2 films opening the route to possible applications in the field of photovoltaics Couches minces Évaporation Oxyde de silicium Nanocristaux de silicium Dopage aux terres rares Cérium Ytterbium Photoluminescence Thin films Evaporation Silicon oxide Silicon nanocrystals Rare earth doping Cerium Ytterbium Photoluminescence 530.417 621.36
605	[pt] NANOPARTÍCULAS SEMICONDUTORES FOTOLUMINESCENTES COMO SONDAS ÓPTICAS PARA DETERMINAÇÃO DE CAPTOPRIL, HISTAMINA, AMINOGLICOSÍDEOS E TIROXINA / [en] PHOTOLUMINESCENT SEMICONDUCTORS NANOPARTICLES AS OPTICAL PROBES FOR THE DETERMINATION OF CAPTOPRIL, HISTAMINE, AMINOGLYCOSIDES AND THYROXINE 20 December 2021 (has links) [pt] Recentemente, os nanocristais semicondutores, também conhecidos como pontos quânticos, tornaram-se muito atrativos em abordagens de detecção por fotoluminescência devido as suas propriedades ópticas peculiares, tais como fluorescência intensa e com perfil estreito, comprimento de onda máximo ajustável através do controle do tamanho das partículas e maior fotoestabilidade em comparação com os corantes orgânicos convencionais. As nanopartículas sintetizadas foram avaliadas como sondas fotoluminescentes (na forma de dispersão aquosa) para a determinação de captopril, histamina, canamicina e tiroxina (analitos não fotoluminescentes na temperatura ambiente) evitando o uso de procedimentos complexos de derivatização química e permitindo quantificações de forma simples e com sensibilidade. Nanopartículas de CdTe modificadas com o ácido tioglicólico (TGA) e com o ácido 2-mercaptopropiônico (2MPA) e também nanopartículas de ZnS modificadas com L-cisteína foram sintetizadas pela abordagem em fase aquosa coloidal. Estas foram caracterizadas usando métodos microscópicos e espectroscópicos adequados. A fotoluminescência da nanopartícula 2MPA-CdTe foi consideravelmente mais intensa quando na presença de captropil. Sob condições ótimas, o modelo de calibração (isoterma de ligação de Langmuir) foi linear até 4,8 x 10-4 mol L-1 com constante de equilíbrio de ligação de 3,2 x 104 L mol-1 e limite de detecção (LOD) de 6,2 x 10-6 mol L-1 (1,3 (micro)g mL-1). Aplicações em soro sanguíneo humano fortificado com captropil e em formulações farmacêuticas foram demonstradas. A fotoluminescência das nanopartículas de TGA-CdTe foi reduzida (supressão) após adição de diferentes concentrações de histamina seguindo o modelo de Stern- Volmer. A resposta linear cobriu uma faixa de concentração até 5,7 x 10-4 mol L-1, com LOD de 9,6 x 10-6 mol L-1 (1,1 (micro)g mL-1). A abordagem proposta foi utilizada para determinação de histamina em carne de atum. Já a presença de aminoglicosídeos aumentou a fluorescência das nanopartículas de TGA-CdTe (seguindo o modelo da isoterma da adsorção de Langmuir). A kanamicina foi o aminoglicosídeo escolhido para estudar o efeito do aumento da intensidade da fotoluminescência das nanopartículas de TGA-CdTe disperso em solução aquosa. A faixa linear estendeu-se até 8,2 x 10-7 mol L-1 com LOD de 2,5 x 10-8 mol L-1 (14,2 ng mL-1). As constantes de ligação entre diversos aminoglicosídeos e TGACdTe foram calculadas e indicou que existe uma relação entre o número de grupos amino primários disponíveis e o aumento da luminescência. Essa abordagem foi aplicada com sucesso para a análise de amostras de leite e água de riacho, ambos fortificados com kanamicina, usando procedimento de extração em fase sólida com um polímero impresso molecularmente (MIP). A intensidade da fotoluminescência da nanopartícula cisteína-ZnS em solução contendo brometo de cetiltrimetilamônio (CTAB) foi reduzida (quenched) após adição de tiroxina. A redução total do sinal (quenching) seguiu o modelo de Stern-Volmer com resposta linear até 4,0 x 10-6 mol L-1 de concentração do analito, o LOD foi 6,2 x 10-8 mol L-1 (48,3 ng mL-1). A dispersão aquosa da cisteína-ZnS foi usada como sonda óptica para a determinação de tiroxina em formulações farmacêuticas e em saliva humana fortificada com analito. / [en] Recently, semiconductor nanocrystals, also known as quantum dots, have become very attractive for photoluminescence based sensing approaches due to their unique optical properties like intense photoluminescence with narrow profile, maximum wavelength adjustable by the control of particle size and higher photostability in comparison of conventional organic dyes. Different synthesized nanoparticles were evaluated as photoluminescent probes (as aqueous dispersions) for the determination of captopril, histamine, kanamycin and thyroxine (nonphotoluminescent analytes at room-temperature) avoiding the use of complex chemical derivatization procedures and enabling simple and sensitive quantifications. Thioglycolic acid (TGA) and 2-mercapoprionic acid (2MPA) modified CdTe nanoparticles and L-cysteine modified ZnS nanoparticles were synthesized via the colloid aqueous phase route. Their characterization was made using proper microscopic and spectroscopic methods. The emission intensity of 2MPA-Cdte is greatly enhanced in the presence of captopril. Under optimum conditions, the calibration model (Langmuir binding isotherm) was linear up to 4.8 x 10-4 mol L-1 with equilibrium binding constant of 3.2 x 104 L mol-1 and limit of detection (LOD) of 6.2 x 10-6 mol L-1 (1.3 (micro)g mL-1). Applications in captopril fortified human serum and in pharmaceutical formulations were demonstrated. The photoluminescence of TGA-CdTe nanoparticles was quenched by histamine in a concentration dependent manner (Stern-Volmer model). The linear response covered the concentration range up to 5.7 x 10-4 mol L-1 with LOD of 9.6 x 10-6 mol L-1 (1.1 (micro)g mL-1). The proposed method was used for the analysis of tuna fish. The presence of aminoglycosides enhanced the photoluminescence of the TGA-CdTe nanoparticles (following a Langmuir binding isotherm model). Kanamycin was used as a model aminoglycoside in order to study its effect on the photoluminescence enhancement of TGA-CdTe quantum dots dispersed in aqueous solution. The linear range extended up to 8.2 x 10-7 mol L-1 with LOD of 2.5 x 10-8 mol L-1 (14.2 ng mL-1). Binding constants were calculated for several aminoglycosides indicating that there is a relationship between the number of available primary amino groups and the increasing in photoluminescence. This approach was successfully applied for determination of kanamycin fortified milk and in stream water samples after solid phase extraction using a molecular imprinted polymer produced using a kanamycin template. The photoluminescence intensity of cysteine-ZnS in solution containing cetyltrimethyl ammonium bromide (CTAB) was quenched by thyroxine. The overall quenching followed a Stern-Volmer model with linear response coveing an analyte concentration range up to 4.0 x 10-6 mol L-1. LOD was 6.2 x 10-8 mol L-1 (48.3 ng mL-1). The aqueous dispersion of cysteine-ZnS was used as optical probe for the determination of thyroxine in pharmaceutical formulations and in analyte fortified human saliva. [pt] AMINOGLICOSIDEOS [pt] TIROXINA [pt] MODELO DE STERN-VOLMER [pt] QUANTUM DOTS [pt] NANOCRISTAIS SEMICONDUTORES [pt] HISTAMINA [pt] CAPTOPRIL [en] AMINOGLYCOSIDES [en] THYROXINE [en] STERN-VOLMER MODEL [en] QUANTUM DOTS [en] SEMICONDUCTOR NANOCRYSTALS [en] HISTAMINE [en] CAPTOPRIL
606	Syntéza a studium nano-strukturovaných perovskitů pro aplikace v organické elektronice / Synthesis and Study of Nano-Structured Perovskites for Applications in Organic Electronics Jančík Procházková, Anna January 2020 (has links) Nanočástice perovskitů halogenidů kovů vykazují unikátní vlastnosti, především výjimečně vysoké hodnoty kvantových výtěžků fluorescence, které předurčují tyto materiály pro aplikace v optoelektronických a fotonických zařízeních. Tato práce popisuje přípravu nanočástic perovskitů halogenidů kovů pomocí stabilizačních činidel inspirovaných přírodou. Stabilizační činidla zde slouží nejen ke stabilizaci, ale i k modifikaci povrchu nanočástic za účelem zvýšení funkčnosti výsledných nanostruktur. Úvod práce popisuje optimalizaci přípravy nanočástic precipitační technikou za použití stabilizačních činidel; jako stabilizační činidlo byl zvolen adamantan-1-amin spolu s hexanovou kyselinou. Bylo prokázáno, že klíčový vliv na optické vlastnosti výsledných koloidních roztoků má volba rozpouštědel a teploty při precipitaci. Mimo jiné byl zkoumán vliv koncentrace prekurzorů na výslednou morfologii a optické vlastnosti nanočástic a jejich koloidních roztoků. V neposlední řadě byly nanočástice stabilizovány adamantan-1-aminem spolu s různými karboxylovými kyselinami a byly studovány optické vlastnosti a koloidní stabilita výsledných koloidních roztoků. V dalším kroku byly nanočástice perovskitů stabilizovány pomocí proetogenních aminokyselin L-lysinu and L-argininu. Takto stabilizované nanočástice vykazovaly úzká emisní spektra ve viditelné oblasti a kvantové výtěžky fluorescence dosahující hodnot téměř 100 %. Stabilizace nanočástic prostřednictvím postranních skupin aminokyselin byla prokázána navázáním chránící terc-butoxykarbonylové skupiny na -amino skupinu. Nanočástice stabilizované modifikovaným lysinem v průběhu jejich přípravy vykazovaly závislost optických vlastností na přítomnosti vody. Předpokládá se, že molekuly vody jsou schopné kontrolovat růst krystalové mřížky po navázání na prekurzory perovskitů a ovlivňovat tak výslednou velikost nanočástic, což vede k projevení kvantových jevů. Spojení nanočástic perovskitů s peptidy představuje nový typ materiálů kombinujících výjimečné optické vlastnosti se samoorganizačními a senzorickými vlastnostmi. Tento koncept byl představen přípravou nanočástic perovskitů stabilizovaných cyklo(RGDFK) pentapeptidem. Vzhledem k citlivosti peptidů na jejich byly nanočástice stabilizovány peptidovými nukleovými kyselinami, robustními analogy nukleových kyselin. Ke stabilizaci nanočástic byl připraven monomer a trimer peptidové nukleové kyseliny obsahující thymin jako dusíkatou bázi. Thymin byl na povrchu nanočástic dostupný k interakci s adeninem přes vodíkové můstky umožňující přenos náboje. Kombinace peptidových nukleových kyselin a perovskitů s unikátními optickými vlastnostmi otevírá aplikační možnosti zejména v oblasti optických senzorů.
607	Spectroscopic characterization of upconversion nanomaterials with systematically varied material composition and surface chemistry Kraft, Marco 09 January 2019 (has links) Ziel dieser Doktorarbeit war es, den Einfluss von verschiedenen Parametern auf die spektroskopischen Eigenschaften von Lanthanid-basierten Aufkonversions-Materialien zu erforschen. Ein besonderer Fokus lag dabei auf hexagonalen Natrium-Yttrium-Tetrafluorid Kristallen, die mit dreifachgeladenen Yb und Er oder Tm Ionen kodotiert wurden. Eine wesentliche Voraussetzung für mögliche Anwendungen dieser Kristalle ist ein Verständnis aller ihrer wichtigen photophysikalischen Besonderheiten. Die erste Studie dieser Doktorarbeit untersuchte daher, wieso Nanokristalle viel weniger absorbierte in ausgesendete Photonen umwandeln als mikrokristalline Teilchen. Die Ergebnisse zeigten, dass man ungeschalte Kristalle aufgrund von Oberflächen-Lösch-Effekten in zwei Teile unterteilen kann, einen strahlenden Kern und eine Schale aus stark oder vollständig gelöschten oberflächennahen Lanthanid-Ionen, welche für Kristalle abnehmender Größe einen immer größeren Volumenanteil einnimmt. Die zweite Studie untersuchte exemplarisch, ob eine kompliziertere Partikelarchitektur, bestehend aus einem einfach-dotierten Er Kern und Yb als Schalenmaterial, diesen Effizienzverlust der Lumineszenz reduzieren kann. Die Ergebnisse zeigten jedoch, dass dies nicht der Fall ist. Eine weitere Studie untersuchte den Einfluss der Konzentration der Tm Ionen in Yb, Tm kodotierten Nanokristallen auf die spektroskopischen Eigenschaften dieser Materialien und zeigte, dass für eine maximale Emission im Lichtwellenbereich über 700 nm andere Tm Konzentrationen benötigt werden als für maximale Lichtemissionen in den unteren Lichtwellenbereichen. Die letzte Studie untersuchte den Einfluss eines zuvor berichteten Zersetzungsprozesses von exemplarisch ausgewählten Yb, Tm kodotierte Nanokristallen in wässrigen Dispersionen auf deren spektroskopische Eigenschaften. Mithilfe dieser Ergebnisse war es möglich, mehrere Emissionsbanden als Parameter für das Langzeit-Stabilitäts-Monitoring dieser Materialien zu identifizieren. / This PhD thesis investigated the influence of various parameters on the spectroscopic properties of so-called upconversion nanoparticles (UCNPs). A special emphasis was dedicated to hexagonal-phase sodium yttrium tetrafluoride crystals that were codoped with trivalent Yb and either Er or Tm ions. Such UCNPs can, however, experience no breakthrough in the field of UC nanotechnology before all of their important photophysical features are understood. The first study of this PhD thesis therefore investigated, why nanocrystalline upconverters with different surface chemistries convert less absorbed to emitted photons than their microcrystalline counterparts. The results revealed that upconverting crystals apparently have to be subdivided into two parts, with one being the luminescent core and the other being a completely dark shell that is quenched by surface effects and assumes an ever increasing volumetric content for small UCNPs. The second study exemplarily investigated, if a more complex particle nanostructure that consisted of a Er doped core, surrounded by a Yb doped shell, could overcome these efficiency losses, however, it concluded that it does not. Another study explored the influence of Tm doping concentrations of Yb, Tm codoped nanocrystals on their spectroscopic properties and concluded that different Tm doping concentrations are required for a maximum upconversion luminescence in the wavelength regions above 700 nm, than for the wavelength regions below that. The last study of this PhD thesis investigated the influence of a previously reported dissolution process of UCNPs in aqueous solutions on the spectroscopic properties of exemplarily chosen Yb, Tm codoped nanocrystals. These results were then utilized to identify several upconversion emission bands that can be used as a screening parameter for the long-term stability monitoring of UCNPs. Aufkonversion Quantenausbeute Lebenszeitmessung Spektroskopie Partikelgröße Wasser Nanostruktur Screening-Parameter Upconversion quantum yield lifetime measurements spectroscopy particle diameter water nanostructure screening-parameter 530 Physik VG 8930 VE 9850 ddc:530
608	Near-Infrared Cu-In-Se-Based Colloidal Nanocrystals via Cation Exchange Lox, Josephine F. L., Dang, Zhiya, Dzhagan, Volodymyr, Spittel, Daniel, Martín-García, Beatriz, Moreels, Iwan, Zahn, Dietrich R.T., Lesnyak, Vladimir 17 December 2019 (has links) We developed a three-step colloidal synthesis of near-infrared active Cu-In-Se (CISe)/ZnS core/shell nanocrystals (NCs) via a sequential partial cation exchange. In the first step binary highly copper deficient Cu2‒xSe NCs were synthesized, followed by a partial cation exchange of copper to indium ions yielding CISe NCs. In order to enhance the stability and the photoluminescence (PL) properties of the NCs, a subsequent ZnS shell was grown, resulting in CISe/ZnS core/shell NCs. These core/shell hetero-NCs exhibited a dramatic increase in size and a restructuring to trigonal pyramidal particles. The reaction parameters, e.g. the Cu:Se-ratio, the temperature and the time were carefully tuned enabling a distinct control over the size and the composition of the NCs. By varying only the size of the CISe/ZnS NCs (from 9 to 18 nm) the PL spectra could be tuned covering a wide range with maxima from 990 nm to 1210 nm. Thus, in these experiments we demonstrate a clear dependence of the optical properties of these materials on their size and extend the PL range of CISe-based nanoparticles further to the infrared part of the spectrum. Furthermore, the relatively large size of these NCs allows their detailed structural analysis via electron microscopy techniques, which is particularly challenging in the case of small particles and especially important to relate the size, composition and crystal structure to their optoelectronic properties. info:eu-repo/classification/ddc/540 ddc:540
609	A two-dimensional hybrid with molybdenum disulfide nanocrystals strongly coupled on nitrogen-enriched graphene via mild temperature pyrolysis for high performance lithium storage Tang, Yanping, Wu, Dongqing, Mai, Yiyong, Pan, Hao, Cao, Jing, Yang, Chongqing, Zhang, Fan, Feng, Xinliang 16 December 2019 (has links) A novel 2D hybrid with MoS₂ nanocrystals strongly coupled on nitrogen-enriched graphene (MoS₂/NGg-C₃N₄) is realized by mild temperature pyrolysis (550 °C) of a self-assembled precursor (MoS₃/g-C₃N₄–H⁺/GO). With rich active sites, the boosted electronic conductivity and the coupled structure, MoS₂/NGg₋C₃N₄ achieves superior lithium storage performance. info:eu-repo/classification/ddc/600 ddc:600
610	Größenkontrollierte Herstellung von Ge-Nanokristallen in Hoch-Epsilon-Dielektrika auf Basis von ZrO2 Lehninger, David 08 December 2018 (has links) Nanokristalle werden beispielsweise für eine Anwendung in Solarzellen, Lichtemittern und nichtflüchtigen Datenspeichern diskutiert. Damit diese Anwendungen funktionieren können, ist eine genaue Kontrolle der Kristallitgröße sowie der Flächendichte und Lage der Kristallite in der Matrix wichtig. Zudem sollte die Matrix amorph sein, da amorphe Matrixmaterialien die Nanokristall-Oberfläche besser passivieren und beständiger gegen Leckströme sind. In dieser Arbeit werden Ge-Nanokristalle in die Hoch-Epsilon-Dielektrika ZrO2 und TaZrOx eingebettet. Im System Ge/ZrO2 kristallisieren die Ge-Cluster und die ZrO2-Matrix bei der gleichen Temperatur. Aufgrund der kristallinen Matrix weicht die Form der Ge-Nanokristalle von einer Kugel ab, worunter unter anderem die Größenkontrolle leidet. Die Beimischung von Ta2O5 stabilisiert die amorphe Phase des ZrO2 und verhindert dadurch die gemeinsame Kristallisation. Dadurch wird es im System Ge/TaZrOx möglich, kugelförmige Ge-Nanokristalle im Größenbereich von 3 nm bis 6 nm positionskontrolliert in eine amorphe Matrix einzubetten. Für die Untersuchung einer möglichen Anwendung des Materialsystems wurden Speicherzellen eines nichtflüchtigen Datenspeichers auf Basis von Ge-Nanokristallen hergestellt. Dabei zeigte sich, dass das System Ge/TaZrOx überdurchschnittlich viele Ladungen speichert und daher für diese Anwendung vielversprechend ist. Zudem stabilisiert die Beimischung von Ta2O5 eine extrem seltene orthorhombische Modifikation des ZrO2. Für ferroelektrische Datenspeicher könnte diese Phase eine aussichtsreiche Alternative zum HfO2 sein. info:eu-repo/classification/ddc/530 ddc:530 info:eu-repo/classification/ddc/660 ddc:660

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