Weibull Modulus of Hardness, Bend Strength, and Tensile Strength of Ni-Ta-Co-X Metallic Glass Ribbons

Neilson, Henry Jathuren

12 June 2014

No description available.

Materials Science

Weibull modulus

metallic glass

high density

Ni-Co-Ta-X

Ribbons

Hardness

Bend strength

Tension

mechanical characterization

Thermal and thermoelectric measurements of silicon nanoconstrictions, supported graphene, and indium antimonide nanowires

Seol, Jae Hun

04 October 2012

This dissertation presents thermal and thermoelectric measurements of nanostructures. Because the characteristic size of these nanostructures is comparable to and even smaller than the mean free paths or wavelengths of electrons and phonons, the classical constitutive laws such as the Fourier’s law cannot be applied. Three types of nanostructures have been investigated, including nanoscale constrictions patterned in a sub-100 nm thick silicon film, monatomic thick graphene ribbons supported on a silicon dioxide (SiO₂) beam, and indium antimonide (InSb) nanowires. A suspended measurement device has been developed to measure the thermal resistance of 48-174 nm wide constrictions etched in 35-65 nm thick suspended silicon membranes. The measured thermal resistance is more than ten times larger than the diffusive thermal resistance calculated from the Fourier’s law. The discrepancy is attributed to the ballistic thermal resistance component as a result of the smaller constriction width than the phonon-phonon scattering mean free path. Because of diffuse phonon scattering by the side walls of the constriction with a finite length, the phonon transmission coefficient is 0.015 and 0.2 for two constrictions of 35 nm x 174 nm x220 nm and 65 nm x 48 nm x 50 nm size. Another suspended device has been developed for measuring the thermal conductivity of single-layer graphene ribbons supported on a suspended SiO₂ beam. The obtained room-temperature thermal conductivity of the supported graphene is about 600 W/m-K, which is about three times smaller than the basal plane values of high-quality pyrolytic graphite because of phonon-substrate scattering, but still considerably higher than for common thin film electronic materials. The measured thermal conductivity is in agreement with a theoretical result based on quantum mechanical calculation of the threephonon scattering processes in graphene, which finds a large contribution to the thermal conductivity from the flexural vibration modes. A device has been developed to measure the Seebeck coefficients (S) and electrical conductivities ([sigma]) of InSb nanowires grown by a vapor-liquid-solid process. The obtained Seebeck coefficient is considerably lower than the literature values for bulk InSb crystals. It was further found that decreasing the base pressure during the VLS growth results in an increase in the Seebeck coefficient and a decrease in the electrical conductivity, except for a nanowire with the smallest diameter of 15 nm. This trend is attributed to preferential oxidation of indium by residual oxygen in the growth environment, which could cause increased n-type Sb doping of the nanowires with increasing base pressure. The deviation in the smallest diameter nanowire from this trend indicates a large contribution from the surface charge states in the nanowire. The results suggest that better control of the chemical composition and surface states is required for improving the power factor of InSb nanowires. On approach is to use Indium-rich source materials for the growth to compensate for the loss of indium due to oxidation by residual oxygen. / text

Thermal measurements

Thermoelectric measurements

Nanoscale constrictions

Silicon film

Monoatomic thick graphene ribbons

Silicon dioxide beam

Indium antimonide nanowires

Thermal resistance

Phonons

Seebeck coefficients

Electrical conductivities

Tuning of color and polarization of the fluorescence of nano-ribbons using laser microscopy and controlled self-assembly / Nano-rubans à fluorescence accordable en couleur et en polarisation par microscopie laser et auto-assemblage contrôlé

Schäfer, Philip Sudadyo

15 December 2016

Des matériaux ayant des propriétés émissives spécifiques peuvent être obtenus par l'organisation contrôlée de fluorophores aux échelles moléculaire, nano- et micro-métrique. Dans ce travail, l'émission de lumière bleue polarisée est obtenue par l'auto-assemblage hautement anisotrope de n-acènes alcoxylés en nano-rubans. Des techniques de microscopie de fluorescence ont été utilisées pour déterminer le mécanisme de leur croissance et ont été combinées à la cristallographie aux rayons X pour déterminer l'empilement moléculaire dans les nano-objets. L'étude a révélé que la formation des nano-rubans est induite non seulement par le mécanisme de maturation d'Ostwald très commun, mais aussi par une croissance par attachement orienté rarement démontré dans des systèmes organiques. En plus des techniques plus courantes, la microscopie en polarisation de fluorescence de molécules uniques a contribué à caraxctériser l'emplilement moléculaire, bien que les nano-objets à haute densité en chromophore constituent des échantillons très difficiles à étudier. Dans ce travail, les propriétés des nano-rubans ont été contrôlées au niveau microscopique par les conditions de croissance, ainsi que par l'addition de dopants. Ainsi, en combinant différentes molécules et une réaction photochimique sous microscopie, des rubans à motifs colorés sub-micrométriques ont été obtenus. Par ailleurs, l'assemblage orthogonal a été exploité pour développer des réseaux interpénétrés. Ces derniers se distinguent par une émission à double couleur, un transfert d'énergie entre objets et une électroluminescence aux jonctions. / Materials with specific emissive properties can be obtained by the controlled organization of fluorophores at the molecular, nano- and microscales. In this work, polarized blue light emission is achieved by the highly anisotropic self-assembly of alkoxylated n-acenes into nano-ribbons. Fluorescence microscopy techniques were used to determine the growth mechanism and were combined to X-ray crystallography to determine the molecular packing in the nano-objects. The study revealed that the formation of the nano-ribbons is induced not only by the very common Ostwald ripening mechanism but also by an oriented attachnment growth, rarely observed with such evidence in organic systems. Besides more common techniques, single molecule fluorescence polarization microscopy contributed to characterize the molecular packing, although the nano-objects with high chromophore density represent very challenging samples. In this work, the properties of the nano-ribbons have been controlled at the microscopic level by the growth conditions, as well as by the addition of dopants Thereby, combining different molecules and photochemistry at the sub-micrometer scale under the microscope, colorful patterned ribbons could be obtained. In addition, orthogonal assembly was exploited to grow interpenetrated networks. The latter demonstrated dual color-emission, as well as inter-object energy transfer and electroluminescence at junctions.

Nano-rubans

Fluorescence

Microscopie

Auto-assemblage

Anthracène

Photo-patterning

Réseaux orthogonaux

Microscopie en molécule unique

Nano-ribbons

Fluorescence

Microscopy

Self-assembly

Anthracene

Photo-patterning

Orthogonal networks

Single molecule microscopy

Investigação dos estados topologicamente protegidos em siliceno e germaneno

Araújo, Augusto de Lelis

02 September 2014

The main objective of this work is to research and obtain surface protected topological states in nano-ribbons created from the leaves of Germanene and Silicene. These sheets belong to the class of Topological Insulators and correspond to monolayers of germanium and silicon atoms in a hexagonal arrangement that is similar to the graphene sheet. For this investigation, we conducted a study of the electronic and structural properties of these sheets, as well as their respective nano-ribbons through first-principles calculations based on density functional theory (DFT). In this methodology we use the generalized gradient approximation (GGA) for estimating the exchange and correlation term, and the PAW method for the effective potential and the expansion of plane waves of the Kohn-Sham. We conducted a computer simulation with the aid of the package VASP (Vienna ab-initio Simulation Package). As a starting point for our research, we used the methodology of solid state physics in order to describe the crystalline structure of the leaves as well as their mutual space. Subsequently we analyze the band structure, from which many of its properties can be visualized. For this task, we initially proceeded to investigate the stability of these systems via total energy calculations, in turn obtaining the network parameters that minimizes the energy of the system. We also obtained the energy cutoff, ECUT used in our calculations, or in other words, determining the number of plane waves needed to expand the electronic wave functions on the DFT formalism. We continued our study, with the creation and analysis of two different configurations of nano-ribbons, one that corresponds to a straightforward cut of the sheet with the armchair termination pattern, and the other based on a reconstruction of those edges, which provide an energetically more stable system. Subsequently we obtained electronic structures, and conducted a study of its variation due to the change of the width of the nano-ribbon and ionic relaxation of its edges. In a way, we modified the above parameters in order to obtain a system that would give us a zero gap, or at least insignificant, as well as a specific configuration for the spin texture, in order to verify the evidence of surface protected topological states in these nano-ribbons. / O objetivo principal deste trabalho é a investigação e obtenção dos estados topologicamente protegidos de superfície em nano-fitas criadas a partir das folhas de Germaneno e Siliceno. Estas folhas pertencem a classe dos Isolantes Topológicos e correspondem a monocamadas de átomos de Germânio e Silício, em um arranjo hexagonal que se assemelha a folha do Grafeno. Para esta investigação, realizamos um estudo das propriedades eletrônicas e estruturais destas folhas, bem como de suas respectivas nano-fitas, através de cálculos de primeiros princípios fundamentados na teoria do funcional da densidade (DFT). Nesta metodologia utilizamos a aproximação do gradiente generalizado (GGA) para a estimativa do termo de troca e correlação, e o método PAW para o potencial efetivo e a expansão em ondas planas dos orbitais de Kohn-Sham. Realizamos a simulação computacional com o auxílio do pacote VASP (Vienna ab-initio Simulation Package). Como ponto de partida para nossa pesquisa, utilizamos a metodologia da física do estado sólido com o intuito de descrever a estrutura cristalina das folhas, bem como seu espaço recíproco. Posteriormente analisamos as estruturas de bandas, a partir das quais muitas de suas propriedades podem ser visualizadas. Para esta tarefa, inicialmente procedemos à investigação da estabilidade destes sistemas via cálculos de energia total, obtendo o parâmetro de rede a que minimiza a energia do sistema. Obtivemos também a energia de corte ECUT utilizada em nossos cálculos, ou em outras palavras, a determinação do número de ondas planas necessárias para expandir as funções de onda eletrônicas no formalismo da DFT. Prosseguimos nosso estudo, com a criação e análise de duas distintas configurações de nano-fitas, uma que corresponde a um corte simples e direto da folha com terminação no padrão armchair, e a outra baseada em uma reconstrução destas bordas, que acaba por fornecer um sistema mais estável energeticamente. Posteriormente obtivemos as estruturas eletrônicas, e realizamos um estudo de sua variação em função da alteração da largura da nano-fita e a relaxação iônica de suas bordas. De certa maneira, modificamos os parâmetros acima, de forma a obter um sistema que nos fornecesse um gap nulo, ou pelo menos desprezível, bem como uma determinada configuração para a textura de spin, de modo a verificarmos a evidência de uma proteção topológica nos estados de superfície nestas nano-fitas. / Mestre em Física

Isolantes topológicos

Estados topologicamente protegidos

Proteção topológica

Siliceno

Germaneno

Nano-fitas

Cálculos de primeiros princípios

Germanio - Propriedades elétricas

Silício - Propriedades elétricas

Topological insulators

Topologically protected states

Topological protection

Silicene

Germanene

Nano-ribbons

First-principles calculations

CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA

Propriétés Electro-mécaniques des Nanotubes de Carbone

Wang, Zhao

18 October 2008

Le but de cette thèse était de modéliser la réponse mécanique de nanotubes de carbone à des champs électriques. Nous avons commencé par utiliser le potentiel AIREBO dans des simulations de dynamique moléculaire afin d'étudier l'élasticité non-linéaire et la limite de déformation en torsion de divers nanotubes, en fonction de leur longueur, rayon et chiralité. Nous trouvons notamment que le module d'Young effectif des tubes décroît d'autant plus vite que la chiralité est faible. D'autre part, nous montrons que la limite de l'énergie stockable par atome lors de la torsion d'un tube est d'autant plus grande que le diamètre est petit.<br><br>Nous modélisons ensuite, de façon atomistique, la distribution surfacique de charge électrique sur des nanotubes de carbone possédant une charge nette. Nous retrouvons notamment l'effet de pointe classique avec un très bon accord quantitatif avec des résultats expérimentaux obtenus par microscopie à force électrostatique.<br><br>Par combinaison des méthodes utilisées dans les études précédentes, nous simulons la déflection de nanotubes semi-conducteurs et métalliques par un champ électrique extérieur, dans une configuration de type interrupteur moléculaire. L'effet des caractéristiques géométriques des tubes et du champ sur cette déflection ont été systématiquement étudiés.<br><br>En outre, nous avons vu que des simulations de dynamique moléculaire avec le potentiel AIREBO permettent de retrouver quantitativement les énergies expérimentales d'adsorption du benzène, du naphtalène et d'anthracène sur le graphite. Ce type de simulation nous permet d'avancer sur la voie de la compréhension de la sélectivité de l'adsorption de certaines molécules surfactantes à plusieurs cycles benzéniques sur des nanotubes de chiralité donnée.

[PHYS:MPHY] Physics/Mathematical Physics

[PHYS:COND] Physics/Condensed Matter

[PHYS:PHYS] Physics/Physics

Computational physics

Electrostatics

Structure optimization

Molecular dynamics

Interatomic chemical potentials

carbon system

Nanotubes

graphene ribbons

fullerenes

Physisorption

interface

Molecular mechanics

Electromechanical

Polyfunkční koncový dům v Karlových Varech / Multifunctional house in Karlovy Vary

Růžička, Jiří

January 2017

The project solves a multifunctional Duma building in a vacant lot, contemplated the construction site is located in Carlsbad, in the street Vyhlíce. This is a protected site spa. Part of the project's layout and structural design of the house. It is a six-storey house with an attic and a basement floor. It is designed as a free-standing in the gap as the final house. The layout is divided into two complete units with their own input. There are spaces for business and residential units for permanent housing. Part of the living area are also room house equipment. Inputs to both parts are wheelchair accessible. The house is not wheelchair The house is designed as a brick building of brick masonry Porotherm the module dimensions of 250 (125) mm with reinforced concrete ceilings. Roofed by a hipped roof. The house is located on a private plot of 519 m2 built-up area of 221 m2. The land is gently sloping. The main orientation of the building to the cardinal's east and west. The south wall is adjacent to the neighboring house.