Growth and Characterization of Thermoelectric Ba₈Ga₁₆Ge₃₀ Type-I Clathrate Thin-Films Deposited by Pulsed Dual-Laser Ablation

Hyde, Robert Harry

01 January 2011

The on-going interest in thermoelectric (TE) materials, in the form of bulk and films, motivates investigation of materials that exhibit low thermal conductivity and good electrical conductivity. Such materials are phonon-glass electron-crystals (PGEC), and the multi-component type-I clathrate Ba8Ga16Ge30 is in this category. This work reports the first investigation of Ba8Ga16Ge30 films grown by pulsed laser deposition (PLD). This dissertation details the in-situ growth of polycrystalline type-I clathrate Ba8Ga16Ge30 thin-films by pulsed laser ablation. Films deposited using conventional laser ablation produced films that contained a high density of particulates and exhibited weak crystallinity. In order to produce high quality, polycrystalline, particulate-free films, a dual-laser ablation process was used that combines the pulses of (UV) KrF excimer and (IR) CO2 lasers that are temporally synchronized and spatially overlapped on the target surface. The effect of the laser energy on stoichiometric removal of material and morphology of the target has been investigated. In addition, in-situ time-gated emission spectroscopy and imaging techniques were used to monitor expansion of components in the ablated plumes. Through these investigations, the growth parameters were optimized not only to significantly reduce the particulate density but also to produce large area stoichiometric films. Structure and electrical transport properties of the resultant films were also evaluated. This work provides new insight toward the in-situ growth of complex multi-component structures in thin-film form for potential TE applications.

hydrodynamic modeling

ICCD imaging

in-situ growth

PLD

polycrystalline

power factor

American Studies

Arts and Humanities

Materials Science and Engineering

Physics

Carbon nanotubes developed on ceramic constituents through chemical vapour deposition

Liu, JingJing

January 2012

Carbon nanotubes (CNTs) were successfully grown on the surface of carbon fibre reinforcements in carbon fibre architecture through in-situ catalytic chemical vapour deposition (CCVD). Success was also implemented on powders of oxides and non-oxides, including Y-TZP powder, ball milled alumina powder, alumina grits, silicon carbide powder. Preliminary results have been achieved to demonstrate the feasibility of making ceramic composites consisting of CNTs reinforcements.

620.1

Synthèse in-situ et caractérisation de nanotubes de carbone individuels sous émission de champ / In-situ growth and characterization of individual carbon nanotubes by field emission

Marchand, Mickaël

16 November 2009

L'étape clé pour intégrer des nanotubes de carbone à une échelle industrielle demeure un meilleur contrôle de leur croissance et notamment le contrôle sélectif de leurs chiralités en lien avec leurs propriétés électroniques. Ce travail a pour but de s'intéresser à la synthèse in-situ et à la caractérisation de nanotubes de carbone individuels par émission de champ pour mieux comprendre les mécanismes de nucléation et de croissance qui conditionnent sa chiralité. Nous avons développé un microscope à émission de champ couplé à un réacteur CVD (Chemical Vapor Deposition) pour observer directement la croissance catalytique de nanotubes de carbone individuels sur des pointes émettrices. Nous avons ainsi découvert que les nanotubes tournent souvent axialement pendant leur croissance, soutenant ainsi un modèle de « dislocation de vis ». L’analyse détaillée des résultats obtenus montre que nous observons directement la croissance atome par atome d'un nanotube monofeuillet individuel avec ajout d’un dimère de carbone à la fois à sa base. Parallèlement, des échantillons ont été caractérisés en détail sous émission de champ. Nous avons établi un protocole de collage de nanotubes individuels à l’apex d’une pointe métallique sous microscopies optique et électronique à balayage à l’aide d’un nanomanipulateur. Leur dépendance en température à très bas courant a été mise en évidence avec un compteur d’électrons afin d'identifier les différents domaines d'émission électronique. L'analyse des distributions énergétiques a fait apparaître un phénomène de chauffage induit qui peut mener à des températures de l’ordre de 2000 K à l’extrémité du nanotube lorsqu’il est soumis à un fort champ. / The key issue for realizing the potential of carbon nanotubes has always been, and still remains, a better control of their growth and in particular the selective control of their chirality related to their electronic properties. This work aims to address the in-situ synthesis and characterization of individual carbon nanotubes by field emission to better understand the mechanisms of nucleation and growth that determine their chirality. We have developed a field emission microscope coupled to a CVD reactor (Chemical Vapor Deposition) to observe directly the catalytic growth of individual carbon nanotubes on metallic tips. We found that nanotubes often turn axially during growth, thereby supporting a model of "screw dislocation". Detailed analysis of results shows that we directly observe the atom by atom growth of one individual single wall nanotube with addition of a carbon dimer to the base. In parallel, certain samples were characterized by in-depth field emission studies. For this we established a protocol of bonding individual nanotubes at the apexes of metal tips under optical and scanning electron microscopies using a nanomanipulator. Their temperature dependence at very low current has been demonstrated with an electron counter to identify the various fields of electron emission. Analysis of energy distributions revealed an induced heating phenomenon that can lead to temperatures of about 2000 K at the end of the nanotube subjected to strong fields that create high current emission.

Nanotubes de carbone

Croissance

Microscopie à émission de champ

CVD

Ultra-vide

Synthèse in-situ

Chiralité

Nanomanipulation

Carbon Nanotube

Growth

Field emission microscopy

Chemical Vapor Deposition

Ultra High Vacuum (UHV)

In-situ growth

Chirality

Nanomanipulation