Novel thermal and electron-beam approaches for the fabrication of boron-rich nanowires

Gonzalez Martinez, Ignacio Guillermo

07 April 2017

Pursuing the development and implementation of novel synthesis techniques to produce nanostructures with an interesting set of properties is a goal that advances the frontiers of nanotechnology. Also of fundamental importance is to revisit well-established synthesis techniques employing a new set of materials as precursors, substrates and catalysts. Fundamental breakthroughs in the field of nanotechnology can be achieved by developing new synthesis procedures as well as by adapting known procedures to new materials. This thesis focuses on both kinds of experiments. A variant of chemical vapor deposition (CVD) has been used to produce Al5BO9 nanowires out of sapphire wafers without the need of a catalyst material. The novelty of the work relies on the formation mechanism of the Al5BO9 nanowires. Essentially, the process can be described as a large-scale topological transformation taking place on the substrate’s surface as its chemical composition changes due to the arrival of precursor molecules. Dense mats of Al5BO9 nanowires cover large areas of the substrate that were previously relatively flat. The process is enhanced by a high temperature and the presence of pre-existing superficial defects (cracks, terraces, etc.) on the substrates. Al5BO9 nanowires as well as B/BOX nanowires and BOX nanotubes were also produced via a novel in-situ electron beam-induced synthesis technique. The process was carried out at room temperature and inside a transmission electron microscope. Au nanoparticles were used as catalyst for the case of B/BOX nanowires and BOX nanotubes, while the Al5BO9 nanowires were synthesized without the need of a catalyst material. The formation and growth of the nanostructures is solely driven by the electron beam. The growth mechanism of the B/BOX nanowires and BOX nanotubes relies on interplay between electrostatic charging of the precursor material (to produce and transport feedstock material) and electron stimulated desorption of oxygen which is able to activate the catalytic properties of the Au nanoparticles. For the case Al5BO9 nanowires a nucleation process based on massive atomic rearrangement in the precursor is instigated by the e-beam, afterwards, the length of some of the nanowires can be extended by a mechanism analogous to that of the growth of the B/BOX nanowires.

Nanotechnologie

Bor

Aluminumborat

Nanodrähte

Nanoröhrchen

TEM

In-situ Synthesetechnik

CVD

Nanotechnology

Nanowires

Aliuminium borate

Nanowires

Nanotubes

TEM

In-situ synthesis

CVD

ddc:620

rvk:VE 9850

K laterálním interakcím v samoorganizovaných monomolekulárních vrstvách / Towards lateral interactions within self-organized monomolecular layers

Staněk, Jan

January 2018

This work aimed at the utilization of chemical principles for stabilization of self-assembled monolayers (SAMs) of carboranethiol derivatives on a flat gold surface. Ideas employing surface confined coordination complex formation and dipole-dipole intermolecular interactions were outlined and the respective literature survey was compiled. Preliminary experiments were carried out to test for their feasibility and surfaces modified with self assembled monolayers proved very sensitive to reaction conditions ordinarily used for bulk synthesis. The chemical sensitivity of the studied surfaces, the necessity of using appropriate surface-sensitive analytical techniques and the depth of the problem initially defined made this task both advanced and challenging. The formation of intermolecular coordination complexes with ω-carboxylated SAMs of meta-carborane-9-thiol was chosen to answer those issues, extending the previous work of the author on carboxylated carboranethiol isomers presented in his bachelor thesis. Concepts different of those based on coordination chemistry are briefly discussed as well, but more as prospects for future work and to present this work in a broader context to which it belongs. Characterization of molecules assembled on a surface in a single layer requires surface sensitive...

EXPERIMENTALLY VALIDATED CRYSTAL PLASTICITY MODELING OF TITANIUM ALLOYS AT MULTIPLE LENGTH-SCALES BASED ON MATERIAL CHARACTERIZATION, ACCOUNTING FOR RESIDUAL STRESSES

Kartik Kapoor (7543412)

30 October 2019

<p>There is a growing need to understand the deformation mechanisms in titanium alloys due to their widespread use in the aerospace industry (especially within gas turbine engines), variation in their properties and performance based on their microstructure, and their tendency to undergo premature failure due to dwell and high cycle fatigue well below their yield strength. Crystal plasticity finite element (CPFE) modeling is a popular computational tool used to understand deformation in these polycrystalline alloys. With the advancement in experimental techniques such as electron backscatter diffraction, digital image correlation (DIC) and high-energy x-ray diffraction, more insights into the microstructure of the material and its deformation process can be attained. This research leverages data from a number of experimental techniques to develop well-informed and calibrated CPFE models for titanium alloys at multiple length-scales and use them to further understand the deformation in these alloys.</p> <p>The first part of the research utilizes experimental data from high-energy x-ray diffraction microscopy to initialize grain-level residual stresses and capture the correct grain morphology within CPFE simulations. Further, another method to incorporate the effect of grain-level residual stresses via geometrically necessary dislocations obtained from 2D material characterization is developed and implemented within the CPFE framework. Using this approach, grain level information about residual stresses obtained spatially over the region of interest, directly from the EBSD and high-energy x-ray diffraction microscopy, is utilized as an input to the model.</p> <p>The second part of this research involves calibrating the CPFE model based upon a systematic and detailed optimization routine utilizing experimental data in the form of macroscopic stress-strain curves coupled with lattice strains on different crystallographic planes for the α and β phases, obtained from high energy X-ray diffraction experiments for multiple material pedigrees with varying β volume fractions. This fully calibrated CPFE model is then used to gain a comprehensive understanding of deformation behavior of Ti-6Al-4V, specifically the effect of the relative orientation of the α and β phases within the microstructure.</p> <p>In the final part of this work, large and highly textured regions, referred to as macrozones or microtextured regions (MTRs), with sizes up to several orders of magnitude larger than that of the individual grains, found in dual phase Titanium alloys are modeled using a reduced order simulation strategy. This is done to overcome the computational challenges associated with modeling macrozones. The reduced order model is then used to investigate the strain localization within the microstructure and the effect of varying the misorientation tolerance on the localization of plastic strain within the macrozones.</p>

Aerospace Engineering

Dual-phase Ti alloy

Burgers Orientation Relationship (BOR)

Dwell Fatigue

Parameter Optimization

model calibration process

Macrozones

Microtextured Regions

Reduced order modeling

Synthesis and characterisation of molecular nanostructures / Synthese und Charakterisierung von molekularen Nanostrukturen

Borowiak-Palen, Ewa

16 July 2004

In this thesis, bulk and local scale spectroscopic and microscopic tools have been applied to investigate the purified raw material of SWCNT and synthesized MWBNNT, BN-nanocapsules, B-doped SWCNT and SiC nanostructures. Using bulk scale sensitive techniques, including optical absorption spectroscopy, Raman spectroscopy, high-resolution electron energy-loss spectroscopy, the average response of the whole sample is obtained. On the other hand, on a local scale transmission and scanning electron microscopy as well as TEM-electron energy-loss spectroscopy provide information on single tubes or other nanostructures. First, diverse chemical and oxidation methods for the purification of as-produced SWCNT were presented. Purified samples were investigated using TEM and OAS. The analysis of the optical absorption spectra in the UV-Vis energy range revealed that some of the chemical treatments are harmful to nanotubes. In contrast to the chemical treatments an oxygen burning procedure was used on the raw material in high vacuum and a temperature range 450?650oC. The purification processes of SWCNT by HNO3 and oxygen burning procedures resulted in SWCNT comprised of selected diameters and a reduced diameter distribution. Both HNO3 and oxygen burning treatments can be used to selectively remove SWCNT with smaller diameters from the samples. In addition, an adapted substitution reaction was used for the synthesis of multiwall boron nitride nanotubes. It was shown that the IR-response of MWBNNT can be used as a fingerprint to analyse MWBNNT. As in h-BN for the analysis one has to be aware of the sample texture and the LO-TO splitting of the IR-active modes. TEM images and B1s and N 1s excitation edges of the grown material reveal the presence of multiwall BN nanotubes with an inner diameter of 3.1 nm and with a larger interplanar distance than in h-BN. The electronic properties of the multiwall BN nanotubes as derived from the q-dependent dielectric function e(w,q) are dominated by the band structure of the hexagonal-like BN sheets, as revealed by the large degree of momentum dispersion observed for the p and s+p plasmons, in agreement with that previously reported for different graphitic allotropic forms. Moreover, a fast and highly efficient synthesis route to produce BN nanocapsules with a narrow size distribution was developed. This was achieved by an adapted substitution process using SWCNT as templates followed by a rapid cooling treatment. The IR responses reveal the strong dipole active fingerprint lines of h-BN with distinct differences, which are due to texturing effects and which highlight the BN nanocapsules potential application as a reference source when deriving the sp2 to sp3 ratio in BN species due to their random orientation Furthermore, the idea of substitution was used for the systematic studies of B-doped SWCNT. The experiments carried out have resulted in 1, 5, 10, and 15 % boron incorporated into the single wall carbon nanotubes. Core level excitation spectroscopy of the B1s and C1s edges revealed that the boron atoms substitute carbon atoms in the tube lattice keeping an sp2-like bond with their nearest C neighbour atoms. Our results show that a simple rigid band model as has been applied previously to intercalated SWCNT is not sufficient to explain the changes in the electronic properties of highly doped B-SWCNT and a new type of a highly defective BC3 SWNT with new electronic properties is obtained. Finally, different silicon carbide nanostructures were produced. The spectroscopic and microscopic data led to a good understanding of the formation process. NH3 acts as a source of hydrogen that plays a key role in the formation of the structures through its ability to decompose SiC at high temperature such that along with the stacking faults that arise from the many polytypes of SiC the produced SiC nanorods become porous then hollow and eventually are completely decomposed.

Bordotierte Kohlenstoffnanoröhren

Einzelwändige Kohlenstoffnanoröhren

Multiwändige Boronnitridenanoröhren

multiwall boron nitride nanotubes

single wall carbon nanotubes

ddc:540

rvk:VK 7157

Bor

Kohlenstoff

Nanoröhre

Nitride

Spektroskopie

Oberflächenmodifikation des Hartmetalls Wolframkarbid-Kobalt durch Bor-Ionenimplantation

Mrotchek, Irina

24 February 2007

Thema dieser Arbeit ist eine experimentelle Untersuchung zur Verbesserung der tribologischen Eigenschaften von Hartmetallen auf der Basis von Wolframkarbid– Kobalt unter Benutzung von Ionen–Implantation in Kombination mit den hierbei auftretenden Struktur– und Phasen–Änderungen. Die vorliegende Arbeit unterscheidet sich von allen anderen bisherigen Arbeiten besonders durch (1.) die detaillierte Analyse der mikroskopischen Veränderungen und durch (2.) deren Verknüpfung mit der Änderung der tribologischen Eigenschaften des Materials.

Ionenimplantation

Hartmetall

Wolframkarbid-Kobalt

Bor

Verschleiß

ion implantation

cemented carbide

hard metal

boron

wear

ddc:530

rvk:UP 9350

Ionenimplantation

Hartmetall

Verschleiß

Untersuchungen zur Sauerstoffausscheidung in hoch bordotiertem Silicium

Zschorsch, Markus

24 July 2009

Die Sauerstoffausscheidung in Silicium wird durch die Höhe der Bordotierung beeinflusst. Mit dem Ziel der Aufklärung der Mechanismen bei der Ausscheidung wurden verschiedene physikalische Messmethoden angepasst und ein breiter Borkonzentrationsbereich charakterisiert. Es wurden die frühen Phasen der Ausscheidungsbildung sowie Komplexbildung als auch das Wachstum der Sauerstoffausscheidungen untersucht. Mithilfe einer neuen Methodenkombination aus alkalischem Ätzen und FTIR-Spektroskopie konnten verschiedene Bor-Komplexe nachgewiesen werden. Die Erkenntnisse über deren Existenz sowie Kinetik wurden numerisch umgesetzt. Mittels Kleinwinkel-Neutronenstreuung wurden erstmals in den frühen Phasen der Sauerstoffausscheidung deren Form und Größe in Abhängigkeit der Borkonzentration bestimmt. Die physikalischen Prozesse, die zu einem beschleunigten als auch anomalen Ausscheidungsverhalten in Abhängigkeit der Borkonzentration führen, konnten teilweise aufgeklärt werden.

Halbleitermesstechnik

p-Halbleiter

Gitterbaufehler

Sauerstoff

Bor

Silicium

Werkstoffkunde

FT-IR-Spektroskopie

Ätzen

Neutronenkleinwinkelstreuung

Reaktionskinetik

Computersimulation

Dotierung

Neutronenaktivierung

Ätzen

ddc:530

rvk:VH 8021

Darstellung und Kopplung von Cyclosilazanen und Borazinen - Precursoren für Si-B-N- und Si-B-C-N-Keramiken / Synthesis and Coupling of Cyclosilazanes and Borazines - Precursors for Si-B-N- and Si-B-C-N-Ceramics

Jaschke, Bettina

26 January 2000

No description available.

540 Chemie

Mathematics and Computer Science

Cyclosilazane

Borazine

Fluorborazine

Kristallstrukturanalysen

Keramikprecursor

ternäre Keramiken

quaternäre Keramiken

Hochtemperatureigenschaften

35.42 Präparative Anorganische Chemie

STL 100 Bor

STM 250 Silicium

STN 200 Stickstoff

Bytový dům / Apartment house

Vokál, Jaroslav

January 2016

Diploma thesis work solves design of the apartment house in city Nový Bor. It is a four-storey detached building without basement. The shape of house is rectangle with maximum dimensions 38,27x14,17 m. The apartment house is designed of clay block Porotherm 300 mm, is founded on foundation strips and the roof is flat in two levels. There is designed a 14 flats.

Novel thermal and electron-beam approaches for the fabrication of boron-rich nanowires

Gonzalez Martinez, Ignacio Guillermo

01 November 2016

Pursuing the development and implementation of novel synthesis techniques to produce nanostructures with an interesting set of properties is a goal that advances the frontiers of nanotechnology. Also of fundamental importance is to revisit well-established synthesis techniques employing a new set of materials as precursors, substrates and catalysts. Fundamental breakthroughs in the field of nanotechnology can be achieved by developing new synthesis procedures as well as by adapting known procedures to new materials. This thesis focuses on both kinds of experiments. A variant of chemical vapor deposition (CVD) has been used to produce Al5BO9 nanowires out of sapphire wafers without the need of a catalyst material. The novelty of the work relies on the formation mechanism of the Al5BO9 nanowires. Essentially, the process can be described as a large-scale topological transformation taking place on the substrate’s surface as its chemical composition changes due to the arrival of precursor molecules. Dense mats of Al5BO9 nanowires cover large areas of the substrate that were previously relatively flat. The process is enhanced by a high temperature and the presence of pre-existing superficial defects (cracks, terraces, etc.) on the substrates. Al5BO9 nanowires as well as B/BOX nanowires and BOX nanotubes were also produced via a novel in-situ electron beam-induced synthesis technique. The process was carried out at room temperature and inside a transmission electron microscope. Au nanoparticles were used as catalyst for the case of B/BOX nanowires and BOX nanotubes, while the Al5BO9 nanowires were synthesized without the need of a catalyst material. The formation and growth of the nanostructures is solely driven by the electron beam. The growth mechanism of the B/BOX nanowires and BOX nanotubes relies on interplay between electrostatic charging of the precursor material (to produce and transport feedstock material) and electron stimulated desorption of oxygen which is able to activate the catalytic properties of the Au nanoparticles. For the case Al5BO9 nanowires a nucleation process based on massive atomic rearrangement in the precursor is instigated by the e-beam, afterwards, the length of some of the nanowires can be extended by a mechanism analogous to that of the growth of the B/BOX nanowires.

info:eu-repo/classification/ddc/620

ddc:620

Untersuchungen zur Sauerstoffausscheidung in hoch bordotiertem Silicium

Zschorsch, Markus

14 December 2007

Die Sauerstoffausscheidung in Silicium wird durch die Höhe der Bordotierung beeinflusst. Mit dem Ziel der Aufklärung der Mechanismen bei der Ausscheidung wurden verschiedene physikalische Messmethoden angepasst und ein breiter Borkonzentrationsbereich charakterisiert. Es wurden die frühen Phasen der Ausscheidungsbildung sowie Komplexbildung als auch das Wachstum der Sauerstoffausscheidungen untersucht. Mithilfe einer neuen Methodenkombination aus alkalischem Ätzen und FTIR-Spektroskopie konnten verschiedene Bor-Komplexe nachgewiesen werden. Die Erkenntnisse über deren Existenz sowie Kinetik wurden numerisch umgesetzt. Mittels Kleinwinkel-Neutronenstreuung wurden erstmals in den frühen Phasen der Sauerstoffausscheidung deren Form und Größe in Abhängigkeit der Borkonzentration bestimmt. Die physikalischen Prozesse, die zu einem beschleunigten als auch anomalen Ausscheidungsverhalten in Abhängigkeit der Borkonzentration führen, konnten teilweise aufgeklärt werden.

info:eu-repo/classification/ddc/530

ddc:530