• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 508
  • 157
  • 114
  • 86
  • 25
  • 20
  • 15
  • 9
  • 7
  • 6
  • 6
  • 5
  • 5
  • 4
  • 4
  • Tagged with
  • 1186
  • 201
  • 168
  • 110
  • 101
  • 98
  • 94
  • 94
  • 93
  • 91
  • 89
  • 88
  • 87
  • 83
  • 82
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
741

Spin-orbit Effects and Electronic Transport in Nanostructures

Ngo, Anh T. 25 April 2011 (has links)
No description available.
742

Spin and Tunneling Effects in Coupled Quantum Dots

Ramanathan, Swati 26 July 2012 (has links)
No description available.
743

Strain mediated self-assembly of ceramic nano islands

Rauscher, Michael D. 10 December 2007 (has links)
No description available.
744

Magnetic field effects and self-assembled n-type nanostructures to increase charge collection in organic photovoltaics

Carter, Austin Roberts January 2011 (has links)
No description available.
745

Three-dimensional Structural Effects of Porous Materials on the Direct-electron-transfer-type Bioelectrocatalysis of Bilirubin Oxidase / ビリルビンオキシダーゼの直接電子移動型バイオエレクトロカタリシス反応に及ぼす多孔質材料の立体構造効果

Wanibuchi, Mizue 23 March 2021 (has links)
京都大学 / 新制・課程博士 / 博士(農学) / 甲第23243号 / 農博第2450号 / 新制||農||1084(附属図書館) / 学位論文||R3||N5333(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 白井 理, 教授 三芳 秀人, 教授 森 直樹 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM
746

Electron Spectromicroscopy of Multipole Moments in Plasmonic Nanostructures / Spectromicroscopy of Plasmonic Multipoles

Bicket, Isobel Claire January 2020 (has links)
The geometry of a plasmonic nanostructure determines the charge-current distributions of its localized surface plasmon resonances (LSPR), thereby determining the device’s interactions with external electromagnetic fields. To target specific applications, we manipulate the nanostructure geometry to create different electromagnetic multipole moments, from basic electric and magnetic dipoles to more exotic higher order and toroidal multipoles. The nanoscale nature of the resonance phenomena makes electron beam spectromicroscopy techniques uniquely suited to probe LSPRs over a wide spectral range, with nanoscale spatial resolution. We use electron energy loss spectroscopy (EELS) in a monochromated scanning transmission electron microscope and cathodoluminescence spectroscopy (CL) in a scanning electron microscope to probe the near-field and far-field properties of LSPR. Electric dipoles within triangular prisms and apertures in Sierpiński fractals couple as the generation number is advanced, creating predictable spectral bands from hybridized dipole modes of parent generations with hierarchical patterns of high field intensity, as visualized in EELS. A magnetic dipole moment is engineered using a vertical split ring resonator (VSRR), pushing the limits of nanofabrication techniques. On this nanostructure we demonstrate the calculation of spatially resolved Stokes parameters on the emission of the magnetic dipole mode and a series of coupled rim modes. Coupling of the magnetic dipole mode of four VSRRs in a circular array creates an LSPR mode supporting the lesser-known toroidal dipole moment. We further probe the near-field configuration of this 3D array through tilting under the electron beam in EELS, and the far-field emission through CL of higher order rim modes. We also propose further configurations of five and six VSRRs to strengthen the toroidal dipole moment. All of the data presented herein was analyzed using custom Python code, which provides a unique graphical interface to 3D spectromicroscopy datasets, and a parallelized implementation of the Richardson-Lucy deconvolution algorithm. / Thesis / Doctor of Philosophy (PhD) / Certain types of metallic particles are capable of trapping light on a scale far below that which we can see; their light-trapping properties depend on their material and on their geometry. Using these tiny particles, we can manipulate the behaviour of light with greater freedom than is otherwise possible. In this thesis, we study how we can engineer the geometry of these particles to give predictable responses that can then be targeted towards specific applications. We study a fractal structure with predictable self-similar responses useful for high sensitivity detection of disease or hormone biomarkers; a resonating structure emulating a magnetic response which can be used in the design of unique new materials capable of bending light backwards and cloaking objects from sight; and a combination of these resonators in an array to demonstrate exotic electromagnetic behaviour still on the limit of our understanding.
747

Preparation et performance d'une cellule photocatalytique à base d'hématite pour la génération d'hydrogène

Bouhjar, Feriel 27 July 2018 (has links)
Tesis por compendio / El hidrógeno es un portador de energía que ya ha demostrado su capacidad para reemplazar el petróleo como combustible. Sin embargo, los medios de producción actualmente en uso siguen siendo altamente emisores de gases de efecto invernadero. La foto-electrólisis del agua es un proceso que, a partir de la energía solar, separa los compuestos elementales del agua como el hidrógeno y el oxígeno utilizando un semiconductor con propiedades físicas adecuadas. La hematita (¿-Fe2O3) es un material prometedor para esta aplicación debido a su estabilidad química y su capacidad para absorber una porción significativa de la luz (con una banda prohibida entre 2.0 - 2.2 eV). A pesar de estas propiedades ventajosas, existen limitaciones intrínsecas al uso de óxido de hierro para la descomposición fotoelectroquímica del agua. La primera restricción es la posición de su banda de conducción que es menor que el potencial de reducción de agua. Esta limitación se puede superar mediante la adición en serie de un segundo material, en tándem, que absorberá una parte complementaria del espectro solar y llevar a los electrones a un nivel de energía más alto que el potencial para la liberación de hidrógeno. El segundo obstáculo proviene del desacuerdo entre la corta longitud de difusión de los portadores de carga y la profundidad de penetración larga de la luz. Por lo tanto, es necesario controlar la morfología de los electrodos de hematita en una escala de tamaño similar a la longitud de transporte del orificio. En esta tesis, se introduce un nuevo concepto para mejorar el rendimiento fotoelectroquímico de la hematita. Usando el método hidrotermal depositamos capas delgadas de hematita dopada con Cr en sustratos de vidrio conductivo. También se ha preparado por medios electroquímicos una heterounión del tipo p-CuSCN/n-Fe2O3 depositando secuencialmente una capa de ¿-Fe2O3 y una película de CuSCNsobre sustratos de FTO (SnO2: F).Finalmente, se ha preparado células solares de perovskitas y óxido de hierro. Para ello se depositó una capa delgada, densa y uniformede óxido de hierro (¿-Fe2O3) como capa de transporte de electrones (ETL) en lugar de dióxido de titanio (TiO2) que se utiliza convencionalmente en las células fotovoltaicas perovskitastipoCH3NH3PbI3 (SGP). Este último dispositivo mostró un aumento en la fotocorriente del 20% y un IPCE30 veces mayor que la hematita simple, lo que sugiere una mejor conversión de las longitudes de onda por encima de 500 nm. Palabras clave: Fotoelectroquímica, división de agua, producción de hidrógeno, evolución de oxígeno, semiconductores de óxido de metal, hematita, óxido de hierro, nanoestructuras / Hydrogen is an energy carrier that has already demonstrated its ability to replace oil as a fuel. However, the means of production currently used remain highly emitting greenhouse gases. Photo-electrolysis of water is a process that uses solar energy to separate the elemental compounds of water such as hydrogen and oxygen using a semiconductor with adequate physical properties. Hematite (¿-Fe2O3) is a promising material for this application because of its chemical stability and ability to absorb a significant portion of light (with a band-gap between 2.0 - 2.2 eV). Despite these advantageous properties, there are intrinsic limitations to the use of iron oxide for the photoelectrochemical cracking of water. The first constraint is the position of its conduction band, which is lower than the water reduction potential. This constraint can be overcome by the addition in series of a second material, in tandem, which will absorb a complementary part of the solar spectrum and bring the electrons to a higher energy level than the potential of hydrogen release. The second obstacle comes from the disagreement between the short diffusion length of the charge carriers and the long light penetration depth. It is therefore necessary to control the morphology of the hematite electrodes on a scale of similar size to the transport length of the hole. In this thesis a new concept is introduced to improve the photoelectrochemical performances. Using the hydrothermal method we deposited thin layers of Cr-doped hematite on conductive glass substrates. We also electrochemically prepared a p-CuSCN / n-Fe2O3 heterojunction by sequentially depositing ¿-Fe2O3 and CuSCN films on FTO (SnO2: F) substrates. Finally, we have used uniform and dense thin layers of iron oxide (¿-Fe2O3) as an electron transport layer (ETL) in place of titanium dioxide (TiO2) conventionally used in photovoltaic cells based on perovskites CH3NH3PbI3 (PSC). This latter concept showed a 20% increase of the photocurrent and an IPCE 30 times greater than the simple hematite, suggesting better conversion of high wavelengths (> 500 nm). Keywords: Photoelectrochemistry, Water Splitting, Hydrogen Production, Oxygen Evolution, MetalOxide Semiconductors, Hematite, Iron Oxide, Nanostructures, Surface. / L'hidrogen és un proveïdor d'energia que ja ha demostrat la seva capacitat per reemplaçar el petroli com a combustible, però els mitjans de producció actuals continuen essent fortament emissors dels gasos responsables d'efecte hivernacle. La fotoelectròlisi de l'aigua és un procés que, a partir de l'energia solar, separa els compostos elementals d'aigua com l'hidrogen i l'oxigen utilitzant un semiconductor amb propietats físiques adequades. La hematita (¿-Fe2O3) és un material prometedor per a aquesta aplicació a causa de la seva estabilitat química i capacitat d'absorbir una porció significativa de la llum (amb un gap entre 2,0 i 2,2 eV). Malgrat aquestes propietats avantatjoses, hi ha limitacions intrínseques per a l'ús d'òxid de ferro per a la descomposició fotoelectroquímica de l'aigua. La primera restricció és la posició de la seva banda de conducció que és inferior al potencial de reducció d'aigua. Aquesta limitació es pot superar mitjançant l'addició en sèrie d'un segon material, en tàndem, que absorbirà una part complementària de l'espectre solar i portar els electrons a un nivell d'energia més alt que el potencial per a l'alliberament d'hidrogen. El segon obstacle prové del desacord entre la curta durada de la difusió dels portadors de càrrega i la llarga profunditat de penetració de la llum. Per tant, és necessari controlar la morfologia dels elèctrodes d'hematita en una escala de mida similar a la longitud del forat del transport. En aquesta tesi, es presenta un nou concepte per millorar el rendiment fotoelectroquímic. Mitjançant el mètode hidrotermal es van dipositar capes primes de hematita Cr-doped sobre substrats de vidre conductor. També s'han preparat electroquímicamentheterounions de tipus p-CuSCN/n-Fe2O3 dipositant seqüencialment una capa de ¿-Fe2O3 i altra de CuSCN sobre substrats FTO (SnO2: F).Finalment, s'han produït cél·lules solars de perovskitesi óxid de ferro. Per això es va depositaruna capa prima,densai uniforme d'òxid de ferro (¿-Fe2O3) com a capa de transport d'electrons (ETL) en lloc de diòxid de titani (TiO2) que s'utilitza convencionalment en les cèl·lules fotovoltaiques de perovskita híbrida del tipus CH3NH3PbI3 (SGP). Aquest últim dispositiu va mostrar un augment del fotocorrent del 20% i una IPCE30 vegades superior a la hematita simple, la qual cosa suggereix una millor conversió a longitud d'ones per sobre de 500 nm. Paraules clau:Fotoelectroquímica, divisió d'aigua, producció d'hidrogen, evolució d'oxigen, semiconductors d'òxids metàl·lics, hematita, òxid de ferro, nanoestructures. / Bouhjar, F. (2018). Preparation et performance d'une cellule photocatalytique à base d'hématite pour la génération d'hydrogène [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/106345 / Compendio
748

Influence of the Local Dielectric Environment and its Spatial Symmetry on Metal Nanoparticle Surface Plasmon Resonances

Torrance, David 01 January 2007 (has links)
This project examines how the collective oscillation of electrons in optically excited metal nanoparticles ( diameter < 100 nm) is affected by the presence of different dielectric environments. When coupled with material polarization, these collective oscillations are known as a Surface Plasmon Polaritons (SPPs), which preferentially absorb and scatter light at a specific frequency satisfying the Local Surface Plasmon Resonance (LSPR) condition. Surface plasmons on metal nanoparticles are widely studied for use in optical labeling, ultrasensitive biodetection, and thermally activated tissue treatment. In general Mie theory can be used to accurately model the optical behavior of ideal spherical particles in a homogeneous environment. However, many experiments involving LSPRs deal with metal nanoparticles in inhomogeneous environments; a typical experimental procedure involves the deposition of a colloidal suspension of metal nanoparticles directly onto a substrate. This project explains how the LSPR of nanoparticles deposited onto planar substrates depends upon the polarization of incident radiation, and demonstrates evidence of resonance tuning by comparing the optical response in various dielectric environments.
749

Machine learning and statistical approaches to extend structure solution methods to lower symmetry cases

Lan, Ling January 2024 (has links)
Crystallography has transformed our understanding of atomic arrangements in materials, yet modern applications increasingly demand more complex, nanoscale structures where traditional methods fall short. The atomic pair distribution function (PDF), derived from X-ray total scattering data, has proven valuable for probing these lower-symmetry structures. However, encoding PDF data into structural information, especially for materials with intricate atomic disorders, presents an ill-posed inverse problem that requires innovative solutions. In this thesis, we propose a “divide and conquer” framework that decomposes this challenge into manageable, well-defined sub-problems by applying constraints on the scope of structures, then solving each sub-problem using machine learning methods. Defining these sub-problems is itself challenging, as lower-symmetry structures often exhibit slight randomness and local deviations from the average structure that are difficult to quantify and simulate in general. To address this, we use a continuous representation of finite clusters and propose a symmetry-breaking measure based on Jensen-Shannon divergence. This measure not only offers a statistical tool that facilitates complex structure analysis by quantifying local symmetry changes in response to distortions, but also provides a universal metric for comparing various structures with differing distortions. The measure also supports ML-based symmetry discovery by serving as a loss function or labeling method. To demonstrate the potential of ML methods in extracting structural information from PDF and diffraction data, we first evaluate the robustness of PDFs as inputs for deep learning models. We then address two case studies: classifying point defects in metals and regressing octahedral tilts in perovskites. For the latter, we introduce a new parameterization of distortions that ensures invariance under distance-preserving transformations, enabling a one-to-one mapping between structural signals and parameterized values. For both studies, we generate structural and PDF datasets, ensuring accessibility to the ML community and fostering interdisciplinary collaboration. Our results show that deep learning models can effectively extract distortion information from PDFs when the inverse problem is well-defined. This work provides novel tools and insights for applying PDFs and ML to analyze complex, lower-symmetry structures.
750

Synthèse et caractérisation de nanostructures organiques covalentes stables

Fiset, Erika 13 April 2018 (has links)
La découverte des nanotubes de carbone représente une avancée significative dans le domaine de la chimie des matériaux. Ce type de matériau et ses dérivés ont trouvés une utilité importante, particulièrement en électronique moléculaire. Même si la synthèse et la fonctionnalisation des nanotubes de carbone sont très développées, les matériaux produits sont souvent coûteux, de formes irrégulières, impurs et ont tendance à former des agrégats, ce qui rend leur manipulation difficile. Malgré l' intense focalisation sur les nanotubes de carbones, la recherche est encore peu développée vers des synthèses alternatives de nanostructures organiques. Plusieurs arrangements moléculaires montrent la capacité d'encapsuler ou de transporter une molécule d'intérêt à l'intérieur de cavités ou de canaux spécifiques, ce qui donne un large potentiel dans des applications en nanotechnologie. Les problèmes majeurs est un contrôle de la longueur de la structure tout en ayant une cavité rigide et une stabilité du matériau. L'objectif global de ce projet de recherche est d' obtenir un nanotube et un nanofilament organiques, covalents, solubles et stables. Pour l' obtention d'un nanotube, il y a deux stratégies proposées qui utilisent comme gabarit soit une polyrotaxane ou un polyméthylméthacrylate afin d'y assembler des dendrimères rigides. Ces dendrimères sont réticulés entre eux et le gabarit est éliminé par hydrolyse menant à la formation d'un vide. Pour l'obtention d'un nanofilament organique, covalent et stable, la stratégie employée est la polymérisation de dendrimères rigides. Un nanofilament a été obtenu par la copolymérisation de deux dendrimères. Ce matériau est fonctionnalisé avec des fullerènes C60 et des porphyrines zinc afin de démontrer son potentiel dans divers domaines de l'électronique.

Page generated in 0.1233 seconds