Atomistic simulation studies of nanostructural titanium dioxide and its lithiation

Matshaba, Malili Gideon.

January 2013

Thesis (P.hD (Physics)) --University of Limpopo, 2013 / Titanium dioxide (TiO2) nanoparticles, nanowires, nanosheets and nanoporous are of great interest in many applications. This is due to inexpensive, safety and rate capability of the material. It has being considered as a replacement of graphite anode material in rechargeable lithium batteries. Much experimental work on pure and lithiated nanostructures of TiO2 has been reported, mostly with regards to their complex microstructures. In this work we employ molecular dynamics (MD) simulation to generate models of TiO2 nano-architectures including: nanosheet, nanoporous, nanosphere and bulk. We have successfully recrystallised all four nanostructures from amorphous precursors; calculated radial distribution functions (RDFs), were used to confirm crystallinity. Configuration energies, calculated as a function of time, were used to monitor the recrystallisation. Calculated X-Ray Diffraction (XRD) spectra, using the model nanostructures, reveal that the nanostructures are polymorphic with TiO2 domains of both rutile and brookite in accord with experiment. Amorphisation and recrystallisation was successful in generating complex microstructures. In particular, bulk and nanoporous structures show zigzag tunnels (indicative of micro-twinning) while nanosphere and nanosheet shows zigzag and straight tunnels in accord with experiment. All model nanostructures of TiO2 were lithiated with different lithium content. RDFs, microstructures, configuration energies, calculated as a function of time and XRDs of all lithiated structures are presented. / University of Limpopo Research Office,The Royal Institution(Ri),Granfield University,Materials Modelling Centre,UCL,and the CHPC

Atomistic simulation

Nanostructural titanium dioxide

Lithiation

669.7233

Atomic structure

Titanium dioxide

Energy storage -- South Africa

Interrupted ageing of Al-Mg-Si-Cu alloys

Buha, Joka, School of Materials Science & engineering, UNSW

January 2005

This thesis systematically investigates the effects of a recently developed modified ageing procedure of aluminium alloys, termed the T6I6 temper, on the microstructural development and mechanical properties of the Al ??? Mg ??? Si - Cu alloy 6061. For the T6I6 temper, a conventional single stage T6 temper is interrupted by an ageing period at a reduced temperature (65??C) to facilitate secondary precipitation, before resuming the final ageing at the temperature of the initial T6 treatment. The T6I6 temper was found to cause simultaneous increases in tensile properties, hardness, and toughness as compared with 6061 T6. Al ??? Mg ??? Si ??? Cu alloys are medium strength alloys widely used in the automotive industry and their further improvement is underpinned by stringent demands for weight reduction placed on the transportation industry in recent years. The potential for further improvement of the mechanical properties was found in the control of secondary precipitation that may take place even in some fully aged alloys when exposed to reduced temperatures. The overall improvement in the mechanical properties of 6061 T6I6 was attributed to the formation of finer and more densely dispersed precipitates in the final microstructure. The refinement of precipitates was facilitated by control of the precipitation processes and gradual evolution of the microstructure throughout each stage of the T6I6 treatment. The results indicated that the concentration and the chemical environment of the vacancies controlled the precipitation processes in this alloy. Findings also show that the proportion of the different precipitate phases present in the final microstructure, as well as the amount of the solute in these precipitates, can be controlled and modified utilizing secondary precipitation. A number of analytical techniques were used in this study. The evolution of the microstructure was studied using Transmission Electron Microscopy (TEM), High Resolution TEM (HRTEM) and Three Dimensional Atom Probe (3DAP). Vacancy-solute interactions were studied using Positron Annihilation Lifetime Spectroscopy (PALS) and 3DAP. The distribution of the solute was studied using 3DAP and Nuclear Magnetic Resonance (NMR). Differential Scanning Calorimetry (DSC) was used to identify precipitation reactions and to determine the stability of vacancy-associated aggregates.

aluminium alloys

Al-Mg-Si-Cu alloys

AA6061

precipitation hardeninig

secondary precipitation

interrupted ageing

T6I6

nanostructural characterisation

mechanical properties

TEM

3DAP

PALS

NMR

DSC

Interrupted ageing of Al-Mg-Si-Cu alloys

Buha, Joka, School of Materials Science & engineering, UNSW

January 2005

This thesis systematically investigates the effects of a recently developed modified ageing procedure of aluminium alloys, termed the T6I6 temper, on the microstructural development and mechanical properties of the Al ??? Mg ??? Si - Cu alloy 6061. For the T6I6 temper, a conventional single stage T6 temper is interrupted by an ageing period at a reduced temperature (65??C) to facilitate secondary precipitation, before resuming the final ageing at the temperature of the initial T6 treatment. The T6I6 temper was found to cause simultaneous increases in tensile properties, hardness, and toughness as compared with 6061 T6. Al ??? Mg ??? Si ??? Cu alloys are medium strength alloys widely used in the automotive industry and their further improvement is underpinned by stringent demands for weight reduction placed on the transportation industry in recent years. The potential for further improvement of the mechanical properties was found in the control of secondary precipitation that may take place even in some fully aged alloys when exposed to reduced temperatures. The overall improvement in the mechanical properties of 6061 T6I6 was attributed to the formation of finer and more densely dispersed precipitates in the final microstructure. The refinement of precipitates was facilitated by control of the precipitation processes and gradual evolution of the microstructure throughout each stage of the T6I6 treatment. The results indicated that the concentration and the chemical environment of the vacancies controlled the precipitation processes in this alloy. Findings also show that the proportion of the different precipitate phases present in the final microstructure, as well as the amount of the solute in these precipitates, can be controlled and modified utilizing secondary precipitation. A number of analytical techniques were used in this study. The evolution of the microstructure was studied using Transmission Electron Microscopy (TEM), High Resolution TEM (HRTEM) and Three Dimensional Atom Probe (3DAP). Vacancy-solute interactions were studied using Positron Annihilation Lifetime Spectroscopy (PALS) and 3DAP. The distribution of the solute was studied using 3DAP and Nuclear Magnetic Resonance (NMR). Differential Scanning Calorimetry (DSC) was used to identify precipitation reactions and to determine the stability of vacancy-associated aggregates.

aluminium alloys

Al-Mg-Si-Cu alloys

AA6061

precipitation hardeninig

secondary precipitation

interrupted ageing

T6I6

nanostructural characterisation

mechanical properties

TEM

3DAP

PALS

NMR

DSC

Advances in hybrid plasmonics : from passive to active functions / Nouvelles avancées en nanoplasmonique hybride : intégration de fonctions passives et actives

Zhou, Xuan

18 July 2013

La plasmonique hybride est un sujet d’actualité qui exploite des interactions physiques entre nano-objets métalliques et d’autres nanomatériaux. En bénéficiant des propriétés de chacun de leurs constituants, les nanostructures hybrides sont utilisées dans de nombreuses applications comme la détection d’espèces bio-chimiques. Dans cette thèse, nous présentons une nouvelle nanostructure hybride polymère/metal qui est non seulement utilisée comme nano-émetteur anisotrope qui s’avère aussi être un outil puissant de caractérisation du champ proche optique.La fabrication de cette nouvelle nanostructure est basée sur une approche de par photopolymérisation à l’échelle nanométrique. Cette technique, en comparaison aux méthodes traditionnelles de caractérisation, ne fournit pas seulement l’image de la distribution du champ, mais permet aussi des mesures quantitatives des plasmons de surface avec une résolution sub -5nm, incluant une description fine de la décroissance exponentielle des ondes évanescentes impliquées.A l’aide du mode plasmon dipolaire, une distribution anisotrope de matériau organique est intégrée dans le voisinage de la nanoparticule métallique. Avec une haute concentration de molécules de colorant dans le polymère, l’intensité des signaux de fluorescence et Raman du nano-émetteur hybride dépend de la polarisation incidente. À notre connaissance, il s’agit de la première réalisation d’un nano-émetteur dont le milieu à gain présente une distribution spatiale complexe le rendant sensible à la polarisation / Hybrid plasmonics has given rise to increasing interest in the context of the interaction between metal nano-objects and other materials. By benefiting from each of its constituents, hybrid nanostructures are commonly adopted in studies and optimization of biological and chemical sensors, nanoparticle with high plasmon resonance tunability, and nano-emitters. This PhD thesis presents a hybrid nanostructure of photopolymer/metal nanoparticle that is used as a near-field characterizing tool and as an anisotropic nano-emitter.The fabrication of this hybrid nanostructure is a near-field imprinting process based on nanoscale photopolymerization. This technique, compared with traditional near-field characterization methods, provides not only the image of the field distribution, but also enables quantification of the surface plasmon properties with sub-5nm resolution and reproduction of the exponential decay of the near-field.Under dipolar mode plasmon, the photopolymer was created anisotropically in the vicinity of the metal nanoparticle. With high concentration of dye molecules trapped in the polymer, the hybrid nano-emitter displays surface enhanced fluorescence and Raman signal that is dependent on the incident polarization. To our knowledge, this is the first achievement of the anisotropic nano-emitter based on the inhomogeneous distribution of the active molecule

Optique en champ proche

Plasmons

Spectroscopie de fluorescence

Raman, effet augmenté de surface

Matériaux nanostructurés

Polymérisation

Near-field optics

Plasmons (physics)

Fluorescence spectroscopy

Raman effect, surface enhanced

Nanostructural materials

Polymerization

620.5

Моделирование колебательных свойств пленок наноструктурного углерода на металлической подложке : магистерская диссертация / Modeling of vibrational properties of nanostructural carbon films on metal support

Бокизода, Д. А., Boqizoda, D. A.

January 2017

Объект исследования – наноразмерные пленки двумерно упорядоченного линейно - цепочечного углерода на металлической подложке без примесей и с примесями. Цель работы – теоретическое исследование структурных, механических и колебательных свойств наноразмерных пленок двумерно упорядоченного линейно - цепочечного углерода на металлической подложке. Методы исследования: метода функционала плотности (DFT), сделан обзор экспериментальных и теоретических работ по применению DFT для вычисления структурных, упругих и колебательных свойств; использование пакетов ABINIT и Quantum-Espresso в приближении DFT; графическое представление результатов с помощью программного обеспечения MS Office Excel и Origin Pro. Результаты работы: рассчитан спектр комбинационного рассеяние ЛЦУ пленок; совмещение экспериментального и расчетного спектров комбинационного рассеяния для линейной структурной модели кристалла карбина; анализ возможности аттестации линейно-цепочечных структур методом КРС. / The object of investigation is nanosized films of two-dimensionally ordered linear-chained carbon on a metal substrate without impurities and with impurities. The aim of the work is a theoretical study of structural, mechanical and vibrational properties of nanosized films of two - dimensional ordered linear - chain carbon on a metallic substrate. Research methods: density functional method (DFT), an overview of experimental and theoretical works on DFT application for calculation of structural, elastic and vibrational properties; the use of Abinit and Quantum-Espresso packages in the DFT approximation; graphical representation of results. The results of the work: the spectrum of Raman scattering of LCC films was calculated; combining the experimental and calculated Raman spectra for the linear structural model of a carbyne crystal, analysis of the possibility of characterization of linear-chained structures by the Raman spectroscopy method was performed.

СПЕКТР

АНАЛИЗ

MASTER'S THESIS

LINEAR-CHAIN CARBON (LCC)

SPECTRUM

ANALYSIS

RAMAN SPECTRUM

DENSITY FUNCTION THEORY (DFT)

NANOSTRUCTURAL CARBON

METALLIC SUBSTRUCTION