Evaluation of novel metalorganic precursors for atomic layer deposition of Nickel-based thin films

Sharma, Varun

17 February 2015

Nickel und Nickel (II) -oxid werden in großem Umfang in fortgeschrittenen elektronischen Geräten verwendet. In der Mikroelektronik-Industrie wird Nickel verwendet werden, um Nickelsilizid bilden. Die Nickelmono Silizid (NiSi) wurde als ausgezeichnetes Material für Source-Drain-Kontaktanwendungen unter 45 nm-CMOS-Technologie entwickelt. Im Vergleich zu anderen Siliziden für die Kontaktanwendungen verwendet wird NiSi wegen seines niedrigen spezifischen Widerstand, niedrigen Kontaktwiderstand, relativ niedrigen Bildungstemperatur und niedrigem Siliziumverbrauchs bevorzugt. Nickel in Nickelbasis-Akkus und ferromagnetischen Direktzugriffsspeicher (RAMs) verwendet. Nickel (II) oxid wird als Transistor-Gate-Oxid und Oxid in resistive RAM genutzt wird. Atomic Layer Deposition (ALD) ist eine spezielle Art der Chemical Vapor Deposition (CVD), das verwendet wird, um sehr glatte sowie homogene Dünnfilme mit hervorragenden Treue auch bei hohen Seitenverhältnissen abzuscheiden. Es basiert auf selbstabschließenden sequentielle Gas-Feststoff-Reaktionen, die eine präzise Steuerung der Filmdicke auf wenige Angström lassen sich auf der Basis. Zur Herstellung der heutigen 3D-elektronische Geräte, sind Technologien wie ALD erforderlich. Trotz der Vielzahl von praktischen Anwendungen von Nickel und Nickel (II) -oxid, sind einige Nickelvorstufen zur thermischen basierend ALD erhältlich. Darüber hinaus haben diese Vorstufen bei schlechten Filmeigenschaften führte und die Prozesseigenschaften wurden ebenfalls begrenzt. Daher in dieser Masterarbeit mussten die Eigenschaften verschiedener neuartiger Nickelvorstufen zu bewerten. Alle neuen Vorstufen heteroleptische (verschiedene Arten von Liganden) und Komplexe wurden vom Hersteller speziell zur thermischen basierend ALD aus reinem Nickel mit H 2 als ein Co-Reaktionsmittel gestaltet. Um die neuartige Vorläufer zu untersuchen, wurde eine neue Methode entwickelt, um kleine Mengen in einer sehr zeitsparend (bis zu 2 g) von Ausgangsstoffen zu testen. Diese Methodologie beinhaltet: TGA / DTA-Kurve analysiert der Vorstufen, thermische Stabilitätstests in dem die Vorläufer (<0,1 g) wurden bei erhöhter Temperatur in einer abgedichteten Umgebung für mehrere Stunden wurde die Abscheidung Experimenten und Film Charakterisierungen erhitzt. Die Abscheidungen wurden mit Hilfe der in situ Quarzmikrowaage überwacht, während die anwendungsbezogenen Filmeigenschaften, wie chemische Zusammensetzung, physikalische Phase, Dicke, Dichte, Härte und Schichtwiderstand wurden mit Hilfe von ex situ Messverfahren untersucht. Vor der Evaluierung neuartiger Nickelvorstufen ein Benchmark ALD-Prozess war vom Referenznickelvorläufer (Ni (AMD)) und Luft als Reaktionspartner entwickelt. Das Hauptziel der Entwicklung und Optimierung von solchen Benchmark-ALD-Prozess war es, Standard-Prozessparameter wie zweite Reaktionspartner Belichtungszeiten, Argonspülung Zeiten, gesamtprozessdruck, beginnend Abscheidungstemperatur und Gasströme zu extrahieren. Diese Standard-Prozessparameter mussten verwendet, um die Prozessentwicklung Aufgabe (das spart Vorläufer Verbrauch) zu verkürzen und die Sublimationstemperatur Optimierung für jede neuartige Vorstufe werden. Die ALD Verhalten wurde in Bezug auf die Wachstumsrate durch Variation des Nickelvorläuferbelichtungszeit, Vorläufer Temperatur und Niederschlagstemperatur überprüft.:Lists of Abbreviations and Symbols VIII Lists of Figures and Tables XIV 1 Introduction 1 I Theoretical Part 3 2 Nickel and Nickel Oxides 4 2.1 Introduction and Existence 5 2.2 Material properties of Nickel and Nickel Oxide 5 2.3 Application in electronic industry 5 3 Atomic Layer Deposition 7 3.1 History 8 3.2 Definition 8 3.3 Features of thermal-ALD 8 3.3.1 ALD growth mechanism – an ideal view 8 3.3.2 ALD growth behaviour 10 3.3.3 Growth mode 11 3.3.4 ALD temperature window 11 3.4 Benefits and limitations 12 3.5 Precursor properties for thermal-ALD 13 3.6 ALD & CVD of Nickel – A literature survey 13 4 Metrology 17 4.1 Thermal analysis of precursors 18 4.2 Film and growth characterization 21 4.2.1 Quartz Crystal Microbalance 21 4.2.2 Spectroscopic Ellipsometry 24 4.2.3 X-Ray Photoelectron Spectroscopy 28 4.2.4 Scanning Electron Microscopy 29 4.2.5 X-Ray Reflectometry and X-Ray Diffraction 29 4.2.6 Four Point Probe Technique 20 5 Rapid Thermal Processing 32 5.1 Introduction 33 5.2 Basics of RTP 33 5.3 Nickel Silicides-A literature survey 33 II Experimental Part 36 6 Methodologies 37 6.1 Experimental setup 38 6.2 ALD process 41 6.2.1 ALD process types and substrate setups 41 6.2.2 Process parameters 41 6.3 Experimental procedure 42 6.3.1 Tool preparation 42 6.3.2 Thermal analysis and ALD experiments from nickel precursors 43 6.3.3 Data acquisition and evaluation 44 6.3.4 Characterization of film properties 46 7 Results and discussion 48 7.1 Introduction 49 7.2 QCM verification with Aluminum Oxide ALD process 49 7.3 ALD process from the reference precursor 50 7.3.1 Introduction 50 7.3.2 TG analysis for Ni(amd) precursor 51 7.3.3 Thermal stability test for Ni(amd) 51 7.3.4 ALD process optimization 52 7.3.5 Film properties 54 7.4 Evaluating the novel Nickel precursors 55 7.4.1 Screening tests for precursor P1 55 7.4.2 Screening tests for precursor P2 62 7.4.3 Screening tests for precursor P3 66 7.4.4 Screening tests for precursor P4 70 7.4.5 Screening tests for precursor P5 72 7.5 Comparison of all nickel precursors used in this work 74 8 Conclusions and outlook 77 References 83 III Appendix 101 A Deposition temperature control & Ellipsometry model 102 B Gas flow plan 105 / Nickel and nickel(II) oxide are widely used in advanced electronic devices . In microelectronic industry, nickel is used to form nickel silicide. The nickel mono-silicide (NiSi) has emerged as an excellent material of choice for source-drain contact applications below 45 nm node CMOS technology. As compared to other silicides used for the contact applications, NiSi is preferred because of its low resistivity, low contact resistance, relatively low formation temperature and low silicon consumption. Nickel is used in nickel-based rechargeable batteries and ferromagnetic random access memories (RAMs). Nickel(II) oxide is utilized as transistor gate-oxide and oxide in resistive RAMs. Atomic Layer Deposition (ALD) is a special type of Chemical Vapor Deposition (CVD) technique, that is used to deposit very smooth as well as homogeneous thin films with excellent conformality even at high aspect ratios. It is based on self-terminating sequential gas-solid reactions that allow a precise control of film thickness down to few Angstroms. In order to fabricate todays 3D electronic devices, technologies like ALD are required. In spite of huge number of practical applications of nickel and nickel(II) oxide, a few nickel precursors are available for thermal based ALD. Moreover, these precursors have resulted in poor film qualities and the process properties were also limited. Therefore in this master thesis, the properties of various novel nickel precursors had to be evaluated. All novel precursors are heteroleptic (different types of ligands) complexes and were specially designed by the manufacturer for thermal based ALD of pure nickel with H 2 as a co-reactant. In order to evaluate the novel precursors, a new methodology was designed to test small amounts (down to 2 g) of precursors in a very time efficient way. This methodology includes: TGA/DTA curve analyses of the precursors, thermal stability tests in which the precursors (< 0.1 g) were heated at elevated temperatures in a sealed environment for several hours, deposition experiments, and film characterizations. The depositions were monitored with the help of in situ quartz crystal microbalance, while application related film properties like chemical composition, physical phase, thickness, density, roughness and sheet resistance were investigated with the help of ex situ measurement techniques. Prior to the evaluation of novel nickel precursors, a benchmark ALD process was developed from the reference nickel precursor (Ni(amd)) and air as a co-reactant. The main goal of developing and optimizing such benchmark ALD process was to extract standard process parameters like second-reactant exposure times, Argon purge times, total process pressure, starting deposition temperature and gas flows. These standard process parameters had to be utilized to shorten the process development task (thus saving precursor consumption) and optimize the sublimation temperature for each novel precursor. The ALD behaviour was checked in terms of growth rate by varying the nickel precursor exposure time, precursor temperature and deposition temperature.:Lists of Abbreviations and Symbols VIII Lists of Figures and Tables XIV 1 Introduction 1 I Theoretical Part 3 2 Nickel and Nickel Oxides 4 2.1 Introduction and Existence 5 2.2 Material properties of Nickel and Nickel Oxide 5 2.3 Application in electronic industry 5 3 Atomic Layer Deposition 7 3.1 History 8 3.2 Definition 8 3.3 Features of thermal-ALD 8 3.3.1 ALD growth mechanism – an ideal view 8 3.3.2 ALD growth behaviour 10 3.3.3 Growth mode 11 3.3.4 ALD temperature window 11 3.4 Benefits and limitations 12 3.5 Precursor properties for thermal-ALD 13 3.6 ALD & CVD of Nickel – A literature survey 13 4 Metrology 17 4.1 Thermal analysis of precursors 18 4.2 Film and growth characterization 21 4.2.1 Quartz Crystal Microbalance 21 4.2.2 Spectroscopic Ellipsometry 24 4.2.3 X-Ray Photoelectron Spectroscopy 28 4.2.4 Scanning Electron Microscopy 29 4.2.5 X-Ray Reflectometry and X-Ray Diffraction 29 4.2.6 Four Point Probe Technique 20 5 Rapid Thermal Processing 32 5.1 Introduction 33 5.2 Basics of RTP 33 5.3 Nickel Silicides-A literature survey 33 II Experimental Part 36 6 Methodologies 37 6.1 Experimental setup 38 6.2 ALD process 41 6.2.1 ALD process types and substrate setups 41 6.2.2 Process parameters 41 6.3 Experimental procedure 42 6.3.1 Tool preparation 42 6.3.2 Thermal analysis and ALD experiments from nickel precursors 43 6.3.3 Data acquisition and evaluation 44 6.3.4 Characterization of film properties 46 7 Results and discussion 48 7.1 Introduction 49 7.2 QCM verification with Aluminum Oxide ALD process 49 7.3 ALD process from the reference precursor 50 7.3.1 Introduction 50 7.3.2 TG analysis for Ni(amd) precursor 51 7.3.3 Thermal stability test for Ni(amd) 51 7.3.4 ALD process optimization 52 7.3.5 Film properties 54 7.4 Evaluating the novel Nickel precursors 55 7.4.1 Screening tests for precursor P1 55 7.4.2 Screening tests for precursor P2 62 7.4.3 Screening tests for precursor P3 66 7.4.4 Screening tests for precursor P4 70 7.4.5 Screening tests for precursor P5 72 7.5 Comparison of all nickel precursors used in this work 74 8 Conclusions and outlook 77 References 83 III Appendix 101 A Deposition temperature control & Ellipsometry model 102 B Gas flow plan 105

info:eu-repo/classification/ddc/620

ddc:620

Bicouches lipidiques modèles pour l'étude des interactions de substances exogènes avec les membranes biologiques : exemple d'un principe actif squalénisé, le ddC-SQ / Interactions between exogene molecules and lipidic model membranes : example of a squalenoyl prodrug, SQddC

Allain, Vanessa

15 December 2011

Les principes actifs, dans leur chemin vers leur cible thérapeutique, rencontrent une ou plusieurs membranes biologiques (plasmique, intracellulaire). Les interactions entre un principe actif et ces membranes sont importantes : d’une part les propriétés pharmacocinétiques de la molécule active (transport, distribution, accumulation) en dépendent, d’autre part le principe actif peut modifier les propriétés structurales des membranes. L’étude de ces interactions est rendue difficile par la complexité des membranes en termes de composition (lipidique et protéique) et de structure (hétérogénéité de l’organisation). Par conséquent, l’utilisation de systèmes modèles simplifiés est nécessaire. Au cours de ce travail de thèse nous avons cherché à réaliser des bicouches lipidiques modèles dont les caractéristiques se rapprochaient de celles des membranes biologiques en complexifiant progressivement leur composition lipidique. Nous avons ensuite étudié l’interaction d’une molécule anti-VIH squalénisée, le ddC-SQ, avec nos modèles de membrane.Un des rôles essentiels des membranes biologiques étant de séparer deux milieux aqueux de composition ionique différente, nous avons étudié dans un premier temps l’influence de la nature du milieu d’hydratation sur les propriétés thermiques et structurales des bicouches lipidiques. A pH physiologique, nous avons mis en évidence que seuls les ions divalents (à faibles concentrations) induisaient de profondes modifications structurales en provoquant la formation de vésicules unilamellaires dans les systèmes simples. Une seconde partie de nos travaux a consisté à étudier l’interaction d’un antiviral squalénisé, le ddC-squalène (ddC-SQ), avec nos différentes bicouches modèles. Cet analogue nucléosidique a été associé de manière covalente à une chaîne de squalène afin d’améliorer ses propriétés pharmacocinétiques. Cette squalénisation confère à la molécule la capacité de s’auto-assembler en nanoparticules présentant une structure cubique bicontinue. Les résultats obtenus ont révélé que le principe actif squalénisé interagissait fortement avec les membranes à l’inverse de la molécule native. L’organisation structurale des systèmes modèles est profondément modifiée par l’insertion du ddC-SQ, ce qui pourrait influer sur l’activité du composé. / Drugs must cross one or more biological membranes (plasma membrane, intracellular membrane) to reach their intracellular target. Interactions between drug and membranes play a significant role in the pharmacokinetic properties of drug such as transport, distribution, accumulation. Moreover, drugs may alter membrane properties. The complexity of the composition (protein and lipid) and the structural properties (heterogeneity) of membranes leads to a difficult investigation of these interactions. Consequently, use of simplified model membranes is needed. In this work, model lipid bilayer systems in which the lipid organization mimics the arrangement of lipids in natural membrane have been developed. In this way, the complexity of lipid composition mixtures has been progressively increased. The primary function of membrane is to physically separate aqueous compartments from their surroundings. The intracellular and extracellular fluids differ in ionic composition. This study firstly consists to estimate the influence of aqueous medium nature on the thermodynamic and structural properties of these model membranes.In physiological conditions (pH 7.4, ionic strength 150 mM), the most significant change was obtained in the presence of divalent ions. Markedly change in lipid organization was observed and the formation of unilamellar vesicles has been evidenced (at low concentrations) in simple model bilayers. Interactions of an antiretroviral nucleoside analogue, the SQddC, with lipid systems constitute the second part of our work. Squalene has been covalently coupled to ddC, in order to improve its therapeutic index. Squalenoylation leads to amphiphilic prodrugs which self-organize as nanoparticles. ddC weakly interacts with lipid membranes while SQddC-SQ can insert into membranes between hydrophobic alkyl chains and induce disruption of lipid organization. Consequently, the efficacy and/or toxicity of this drug could change.

Membranes modèles

Séparations de phases

Sphingomyéline

Analogue nucléosidique

Dideoxycytidine (ddC)

Squalénisation

DdC squalène (ddC-SQ)

Calorimétrie (DSC)

Model membranes

Phase separations

Phosphatidylcholine

Sphingomyelin

Cholesterol

PH

Ions

Nucleoside analogue

Dideoxycytidine (ddC)

Squalenoylation

DdC squalene (SQddC)

X ray diffraction (XRD)

Differential scanning calorimetry (DSC)

Estudos teórico e experimental de propriedades estruturais e eletrônicas da molécula emodina em solvente e em bicamadas lipídicas / Theoretical and Experimental Studies of Structural and Electronic Properties of Emodin Molecule in Solvent and Lipid Bilayers

Cunha, Antonio Rodrigues da

08 August 2014

A Emodina (EMH) é uma das antraquinonas mais abundantes na natureza. Essa molécula vem sendo largamente usada como material de estudo científico por apresentar diversas atividades farmacológicas, tais como antiviral, antitumoral, antifungal, digestiva e outras. É conhecido que a Emodina em solução aquosa alcalina pode sofrer mais de um processo de desprotonação, apresentando-se na forma desprotonada, EM-, após a primeira desprotonação. Nesta tese de doutorado estudamos as propriedades estruturais e eletrônicas da molécula Emodina em meio solvente e em bicamadas lipídicas a fim de caracterizar as propriedades relacionadas à espectroscopia UV-Vis, à reatividade e à termodinâmica dessa molécula nesses ambientes. Realizamos cálculos quânticos com a Emodina em vácuo e em meio solvente, onde consideramos todos os possíveis sítios de desprotonação. Como resultados desses cálculos, identificamos os sítios da primeira, segunda e terceira desprotonação. Calculamos o pKa1 da Emodina em água e o pK*a1 em metanol através de simulações computacionais com o método Monte Carlo e cálculos quânticos, com o solvente descrito com o modelo contínuo polarizável. Nossos melhores valores para o pKa1 da Emodina determinados nesses solventes foram 8.4±0.5 e 10.3±1.5, que estão em boa concordância com os valores experimentais, (pKa1=8.0±0.2 e pK*a1=11.1±0.1) obtidos nesta tese para Emodina em água e metanol, respectivamente. Adicionalmente realizamos simulações com Dinâmica Molecular com as espécies EMH e EM- em bicamada lipídica de DMPC, para investigar a nível atômico as interações dessas espécies com a bicamada e determinar as posições preferenciais dessas espécies nesse ambiente anfifílico. Os resultados dessas simulações mostraram que as espécies EMH e EM- ficam inseridas na bicamada, na região polar dos lipídios, próximos aos gliceróis. Esses resultados corroboram as nossas medidas do espectro de absorção dessas espécies em bicamada lipídica, onde mostramos de forma qualitativa, que ambas as espécies ficam inseridas na bicamada, na região das cabeças polares dos lipídios. A análise das propriedades estruturais da bicamada na vizinhança das espécies da Emodina como área por lipídio e densidade eletrônica dos lipídios, mostrou que o efeito da EM- na estrutura da bicamada lipídica é maior do que o da EMH. Esses resultados corroboram as nossas medidas de DSC(Differential Scanning Calorimetry) das espécies da Emodina na bicamada. / Emodin (EMH) is one of the most abundant anthraquinone derivatives found in nature. This molecule has been used widely as research material, due to its biological and pharmacological activities such as antiviral, anticancer, antifungal, digestive and antibacterial activities. It is known that Emodin in alkaline aqueous solution can undergo more than one deprotonation, leading to the specie EM- in the first deprotonation process. In this PhD thesis, we studied the structural and electronic properties of this molecule in several solvents and lipid bilayers, in order to characterize the properties related to UV-Vis absorption spectroscopy, reactivity and thermodynamics of this molecule in these environments. Performing quantum mechanics (QM) calculations for all possible deprotonation sites and tautomeric isomers of Emodin in vacuum and in water, we identified the sites of the first, second and third deprotonations. We calculated the pKa1 of Emodin in water and pK*a1 in methanol with free energy perturbation method, implemented in the Monte Carlo simulation, and with QM calculations, where the solvent was treated as a polarizable continuum medium. Our best values for pKa1 of Emodin in these solvents were 8.4±0.5 and 10.3±1.5, which are in very good agreement with the experimental values obtained in this thesis pKa1=8.0±0.2 and pK*a1=11.1±0.1, for water and methanol, respectively. Additionally, we performed molecular dynamics simulations of both species in fully hydrated lipid bilayers of DMPC to investigate at atomic detail the molecular mechanism of the interaction of these species with lipid membrane and its preferred positions in this amphiphilic environment. As results of these simulations, we obtained that both species of Emodin have a strong tendency to insert into the lipid bilayer, remaining near the glycerol group of DMPC. These results corroborate our measured absorption spectra of these species in the bilayer, which qualitatively showed that both species are within the bilayer, inserted in the lipid headgroup region. Our results also show that the effect of EM- specie in the lipid bilayer structure is stronger than the EMH, which corroborate our DSC(Differential Scanning Calorimetry) measurements.

Acidity constant

Constante de acidez

Differential scanning calorimetry

Física Atômica e Molecular/Biofísica

Processo de protonação/desprotonação

Protonation / deprotonation process

Spectroscopic titration

Titulação espectroscópica

Biodegradable Composites : Processing of thermoplastic polymers for medical applications.

Damadzadeh, Behzad, Jabari, Hamideh

January 2009

Despite the recent development in PLA and PLGA based medical devices, there are still needs to further improve the mechanical performance of bioresorbable medical implants and their bioactivity. This is normally done by optimizing the filler compositions in selected groups ofbiodegradable polymer matrices. In this study, the effects of various filler levels on mechanical strength and thermal properties of PLA and PLGA composites were investigated. Composites containing different dosage of osteoconductive HAp with various particles size (0-5μm, 0-50 μm, nano size), β-TCP, bioactive glass and biodegradable Poly-L-lactide and Polylactide-glycolic acid was manufactured with melt blending, using a twin-screw extruder.The samples were investigated by Differential Scanning Calorimetry (DSC), thermo gravimetric analysis (TGA), Scanning Electron Microscopy (SEM), viscometer, three points bending machine, and Optical Microscopy (OM). The Extruder produced a porous profile. The result from TGA and SEM indicated that there was homogenous filler dispersion in the matrix after compounding.The result from DSC and Viscometer shows that there was some degradation duringcompounding. Mechanical properties of composites were modified by adding filler to matrix. The addition of Bioactive glass, as a filler, increases the degradation of the polymer matrix. The best filler that was applied is 0-5μm and nano HAp. Also in in-vitro degradation part of this thesis work, the effects of calcium phosphate materialsare investigated on degradation process.

poly lactic acid

poly glycolic acid

microcompounder

in-vitro degradation

biomedical application

hydroxy appetite (hap)

tricalcium phosphate (tcp)

bioactive glass (bag)

bioceramic

medical composite

differential scanning calorimetry (dsc)

inherent viscosity

termogravimetric analysis (tga)

scanning electron microscopy (sem)

biodegradable composite

Engineering and Technology

Teknik och teknologier

The Influence of Fibre Processing and Treatments on Hemp Fibre/Epoxy and Hemp Fibre/PLA Composites

Islam, Mohammad Saiful

January 2008

In recent years, due to growing environmental awareness, considerable attention has been given to the development and production of natural fibre reinforced polymer (both thermoset and thermoplastic) composites. The main objective of this study was to reinforce epoxy and polylactic acid (PLA) with hemp fibre to produce improved composites by optimising the fibre treatment methods, composite processing methods, and fibre/matrix interfacial bonding. An investigation was conducted to obtain a suitable fibre alkali treatment method to: (i) remove non-cellulosic fibre components such as lignin (sensitive to ultra violet (UV) radiation) and hemicelluloses (sensitive to moisture) to improve long term composites stability (ii) roughen fibre surface to obtain mechanical interlocking with matrices (iii)expose cellulose hydroxyl groups to obtain hydrogen and covalent bonding with matrices (iv) separate the fibres from their fibre bundles to make the fibre surface available for bonding with matrices (v) retain tensile strength by keeping fibre damage to a minimum level and (vi) increase crystalline cellulose by better packing of cellulose chains to enhance the thermal stability of the fibres. An empirical model was developed for fibre tensile strength (TS) obtained with different treatment conditions (different sodium hydroxide (NaOH) and sodium sulphite (Na2SO3) concentrations, treatment temperatures, and digestion times) by a partial factorial design. Upon analysis of the alkali fibre treatments by single fibre tensile testing (SFTT), scanning electron microscopy (SEM), zeta potential measurements, differential thermal analysis/thermogravimetric analysis (DTA/TGA), wide angle X-ray diffraction (WAXRD), lignin analysis and Fourier transform infrared (FTIR) spectroscopy, a treatment consisting of 5 wt% NaOH and 2 wt% Na2SO3 concentrations, with a treatment temperature of 120oC and a digestion time of 60 minutes, was found to give the best combination of the required properties. This alkali treatment produced fibres with an average TS and Young's modulus (YM) of 463 MPa and 33 GPa respectively. The fibres obtained with the optimised alkali treatment were further treated with acetic anhydride and phenyltrimethoxy silane. However, acetylated and silane treated fibres were not found to give overall performance improvement. Cure kinetics of the neat epoxy (NE) and 40 wt% untreated fibre/epoxy (UTFE) composites were studied and it was found that the addition of fibres into epoxy resin increased the reaction rate and decreased the curing time. An increase in the nucleophilic activity of the amine groups in the presence of fibres is believed to have increased the reaction rate of the fibre/epoxy resin system and hence reduced the activation energies compared to NE. The highest interfacial shear strength (IFSS) value for alkali treated fibre/epoxy (ATFE) samples was 5.2 MPa which was larger than the highest value of 2.7 MPa for UTFE samples supporting that there was a stronger interface between alkali treated fibre and epoxy resin. The best fibre/epoxy bonding was found for an epoxy to curing agent ratio of 1:1 (E1C1) followed by epoxy to curing agent ratios of 1:1.2 (E1C1.2), 1: 0.8 (E1C0.8), and finally for 1:0.6 (E1C0.6). Long and short fibre reinforced epoxy composites were produced with various processing conditions using vacuum bag and compression moulding. A 65 wt% untreated long fibre/epoxy (UTLFE) composite produced by compression moulding at 70oC with a TS of 165 MPa, YM of 17 GPa, flexural strength of 180 MPa, flexural modulus of 10.1 GPa, impact energy (IE) of 14.5 kJ/m2, and fracture toughness (KIc) of 5 MPa.m1/2 was found to be the best in contrast to the trend of increased IFSS for ATFE samples. This is considered to be due to stress concentration as a result of increased fibre/fibre contact with the increased fibre content in the ATFE composites compared to the UTFE composites. Hygrothermal ageing of 65 wt% untreated and alkali treated long and short fibre/epoxy composites (produced by curing at 70oC) showed that long fibre/epoxy composites were more resistant than short fibre/epoxy composites and ATFE composites were more resistant than UTFE composites towards hygrothermal ageing environments as revealed from diffusion coefficients and tensile, flexural, impact, fracture toughness, SEM, TGA, and WAXRD test results. Accelerated ageing of 65 wt% UTLFE and alkali treated long fibre/epoxy (ATLFE) composites (produced by curing at 70oC) showed that ATLFE composites were more resistant than UTLFE composites towards hygrothermal ageing environments as revealed from tensile, flexural, impact, KIc, SEM, TGA, WAXRD, FTIR test results. IFSS obtained with untreated fibre/PLA (UFPLA) and alkali treated fibre/PLA (ATPLA) samples showed that ATPLA samples had greater IFSS than that of UFPLA samples. The increase in the formation of hydrogen bonding and mechanical interlocking of the alkali treated fibres with PLA could be responsible for the increased IFSS for ATPLA system compared to UFPLA system. Long and short fibre reinforced PLA composites were also produced with various processing conditions using compression moulding. A 32 wt% alkali treated long fibre PLA composite produced by film stacking with a TS of 83 MPa, YM of 11 GPa, flexural strength of 143 MPa, flexural modulus of 6.5 GPa, IE of 9 kJ/m2, and KIc of 3 MPa.m1/2 was found to be the best. This could be due to the better bonding of the alkali treated fibres with PLA. The mechanical properties of this composite have been found to be the best compared to the available literature. Hygrothermal and accelerated ageing of 32 wt% untreated and alkali treated long fibre/PLA composites ATPLA composites were more resistant than UFPLA composites towards hygrothermal and accelerated ageing environments as revealed from diffusion coefficients and tensile, flexural, impact, KIc, SEM, differential scanning calorimetry (DSC), WAXRD, and FTIR results. Increased potential hydrogen bond formation and mechanical interlocking of the alkali treated fibres with PLA could be responsible for the increased resistance of the ATPLA composites. Based on the present study, it can be said that the performance of natural fibre composites largely depend on fibre properties (e.g. length and orientation), matrix properties (e.g. cure kinetics and crystallinity), fibre treatment and processing methods, and composite processing methods.

Hemp Fibre

Epoxy Resin

Poly(lactic acid)

Interfacial Shear Strength

Fracture Toughness

Impact Energy

Tensile Properties

Flexural Properties

Accelerated Ageing

Hygrothermal Ageing

Experimental Design

Cure Kinetics

Dynamic Sheet Forming

Long and Short Fibres

Untreated Fibre

Alkali Treated Fibre

Silane Treated Fibre

Acetylated Fibre

Zeta Potential

Differential Scanning Calorimetry

X-ray Diffraction

Infrared Spectra.

Artificial biomineralisation and metallic soaps

Corkery, Robert, robert.corkery@anu.edu.au

January 1998

In this thesis, geometry is used as a basis for conducting experiments aimed at growing and arranging inorganic minerals on curved interfaces. Mineralisation is directed using crystalline and liquid-crystalline metallic soaps and surfactant/water systems as templates.¶ A review of the history, syntheses, structure and liquid crystallinity of metallic soaps and other amphiphiles is presented as a foundation to understanding the interfacial architectures in mesostructured template systems in general.¶ In this study, a range of metallic soaps of varying chain length and cation type are synthesised and characterised to find potentially useful templates for mineral growth. These include alkaline-earth, transition metal, heavy metal and lanthanide soaps. These are systematically characterised using a variety of analytical techniques, including chemical analyses, x-ray diffraction (XRD) infrared spectroscopy (IR) and differential scanning calorimetry (DSC). Their molecular and crystal structures are studied using transmission electron microscopy (TEM), cryo-TEM, electron diffraction (ED), electron paramagnetic spin resonance (EPR), absorption spectroscopy (UV-VIS), high resolution laser spectroscopy, atomic force microscopy (AFM), nuclear magnetic resonance spectroscopy, scanning electron microscopy (SEM), electron dispersive x-ray analysis (EDXA), thermal gravimetric analysis (TGA) and magnetic measurements. Models for the molecular and crystal structures of metallic soaps are proposed. The soaps are predominantly lamellar crystalline or liquid crystalline lamellar rotor phases with tilted and/or untilted molecular constituents. These display evidence of varying degrees of headgroup organisation, including superstructuring and polymerisation. A single crystal structure is presented for a complex of pyridine with cobalt soap. Simple models for their structure are discussed in terms of their swelling properties in water and oils. Experiments are also presented to demonstrate the sorbent properties of aluminium soaps on oil spills.¶ The thermotropic liquid crystallinity of alkaline earth, transition metal, heavy metal and lanthanide soaps is investigated in detail. This is done to assess their suitability as templates, and to document their novel thermotropic behaviour, particularly the relatively unknown lanthanide soaps. Liquid crystalline behaviours are studied using high-temperature XRD (HTXRD), hot-stage optical microscopy and DSC. Models for a liquid crystalline phase progression from crystals to anisotropic liquids are discussed in terms of theories of self-assembly and interfacial curvature. The terminology required for this is drawn from various nomenclature systems for amphiphilic crystals and liquid crystals. General agreement with previous studies is reported for known soaps, while liquid crystallinity is demonstrated in the lanthanide and some non-lanthanide soaps for the first time. A general phase progression of crystalline lamellar through liquid crystalline lamellar to non-lamellar liquid crystalline is discussed in terms of models concerned with the molecular and crystal structures of the soaps and their phase transitions via headgroup and chain re-arrangements.¶ Experiments aimed at guiding growth of metal sulfides using metallic soaps as templates are described, and a model for this growth is discussed. Metal sulfides have been successfully grown by reacting crystalline and liquid crystalline transition metal and heavy metal soaps with H2S gas at room temperature and at elevated temperature. These have been characterised using XRD, TEM, ED and IR. Sulfide growth is demonstrated to be restricted and guided by the reacting soap template architecture. Zinc, cadmium, indium and lead soaps formed confined nanoparticles within the matrix of their reacting soap template. In contrast, curved and flat sheet-like structures, some resembling sponges were found in the products of sulfided iron, cobalt, nickel, copper, tin and bismuth soaps. A model to explain this behaviour is developed in terms of the crystal and liquid crystal structures of the soaps and the crystal structures of the metal sulfide particles.¶ Liquid crystalline iron soaps have been subjected to controlled thermal degradation yielding magnetic iron oxide nanoparticles. Some XRD and TEM evidence has been found for formation of magnetic mesostructures in heat-treated iron soaps. Models for the molecular and liquid crystalline structure of iron soaps, their thermotropic phase progression and eventual conversion to these magnetic products are discussed. Systematic syntheses of mesoporous silicates from sheeted clays are discussed.¶The templates that have been used are cationic surfactants and small, organic molecular salts. Experiments are reported where a cooperative self-assembly of surfactant/water/kanemite plus or minus salt and oils yields 'folded sheet materials' (FSM'S). Templating of kanemite has also been achieved using cobalt cage surfactants. A theoretical prediction of the specific surface areas and specific volumes of homologous sets of FSM's gave excellent agreement with measured values. The geometry and topology of the mesostructures are discussed. A theoretical model is also discussed regarding the curvature found in the sheets of natural clays , and results of templating clays and silica using metallic soaps are presented. Experiments and a model for low temperature nucleation and growth of microporous silicalite-1 are described in terms of silica templating by water clathrates.¶ Finally, the problem of finding minimal surface descriptions of crystal networks is addressed. Combinatoric methods are used to disprove the existence of possible embeddings of type I and II clathrate networks in non-self intersecting periodic minimal surfaces. The crystal network of the clathrate silicate, melanophlogite is successfully embedded in the WI-10 self-intersecting surface. Details of a previously unreported, genus-25 periodic surface with symmetry Im3m are discussed.

Biomineral

metal soap

metallic soap

curvature

structure

self-assembly

lipid

lanthanide

fatty acid

liquid crystal

mesophase

nanoparticle

quantum dot

metal sulfide

transmission electron microscopy

x-ray diffraction

differential scanning calorimetry

metal oxide

kanemite

mesoporous

FSM-16

clay

talc

minimal surface

cubic

lamellar

hexagonal

hyperbolic

saddle

template

interface

silica

surfactant

Langmuir-Blodgett

zeolite

silicalite

zsm-5

amphiphile

differential geometry

topology

mesostructured

nanostructured

nanoporous

Crystallization of Parabens : Thermodynamics, Nucleation and Processing

Huaiyu, Yang

January 2013

In this work, the solubility of butyl paraben in 7 pure solvents and in 5 different ethanol-water mixtures has been determined from 1 ˚C to 50 ˚C. The solubility of ethyl paraben and propyl paraben in various solvents has been determined at 10 ˚C. The molar solubility of butyl paraben in pure solvents and its thermodynamic properties, measured by Differential Scanning Calorimetry, have been used to estimate the activity of the pure solid phase, and solution activity coefficients. More than 5000 nucleation experiments of ethyl paraben, propyl paraben and butyl paraben in ethyl acetate, acetone, methanol, ethanol, propanol and 70%, 90% ethanol aqueous solution have been performed. The induction time of each paraben has been determined at three different supersaturation levels in various solvents. The wide variation in induction time reveals the stochastic nature of nucleation. The solid-liquid interfacial energy, free energy of nucleation, nuclei critical radius and pre-exponential factor of parabens in these solvents have been determined according to the classical nucleation theory, and different methods of evaluation are compared. The interfacial energy of parabens in these solvents tends to increase with decreasing mole fraction solubility but the correlation is not very strong. The influence of solvent on nucleation of each paraben and nucleation behavior of parabens in each solvent is discussed. There is a trend in the data that the higher the boiling point of the solvent and the higher the melting point of the solute, the more difficult is the nucleation. This observation is paralleled by the fact that a metastable polymorph has a lower interfacial energy than the stable form, and that a solid compound with a higher melting point appears to have a higher solid-melt and solid-aqueous solution interfacial energy. It has been found that when a paraben is added to aqueous solutions with a certain proportion of ethanol, the solution separates into two immiscible liquid phases in equilibrium. The top layer is water-rich and the bottom layer is paraben-rich. The area in the ternary phase diagram of the liquid-liquid-phase separation region increases with increasing temperature. The area of the liquid-liquid-phase separation region decreases from butyl paraben, propyl paraben to ethyl paraben at the constant temperature. Cooling crystallization of solutions of different proportions of butyl paraben, water and ethanol have been carried out and recorded using the Focused Beam Reflectance Method, Particle Vision and Measurement, and in-situ Infrared Spectroscopy. The FBRM and IR curves and the PVM photos track the appearance of liquid-liquid phase separation and crystallization. The results suggest that the liquid-liquid phase separation has a negative influence on the crystal size distribution. The work illustrates how Process Analytical Technology (PAT) can be used to increase the understanding of complex crystallizations. By cooling crystallization of butyl paraben under conditions of liquid-liquid-phase separation, crystals consisting of a porous layer in between two solid layers have been produced. The outer layers are transparent and compact while the middle layer is full of pores. The thickness of the porous layer can reach more than half of the whole crystal. These sandwich crystals contain only one polymorph as determined by Confocal Raman Microscopy and single crystal X-Ray Diffraction. However, the middle layer material melts at lower temperature than outer layer material. / <p>QC 20130515</p> / investigate nucleation and crystallization of drug-like organic molecules

Nucleation

Induction time

Interfacial energy

Ethyl paraben

Propyl paraben

Butyl paraben

Methanol

Ethanol

Propanol

Acetone

Ethyl acetate

Solubility

Thermodynamics

Activity

Activity coefficient

Liquid-liquid phase separation

Ternary phase diagram

Melting point

Boiling point

Polarity

Cooling crystallization

Sandwich crystal

Porous

Particle Vision and Measurement

Focused Beam Reflectance Method

Infrared Spectroscopy

Confocal Raman Microscopy

X-Ray Diffraction

Differential Scanning Calorimetry

Synthese nanostrukturierter, organisch-anorganischer Hybridmaterialien über Zwillingspolymerisation

Löschner, Tina

06 August 2013

Im Fokus dieser Arbeit stand die Methode Zwillingspolymerisation zur Synthese organisch-anorganischer Hybridmaterialien. Die simultane Zwillingspolymerisation wird als neues Konzept zur gezielten Herstellung homogener, nanostrukturierter Hybridmaterialien unterschiedlicher Zusammensetzung vorgestellt. Hierfür wurden die Zwillingsmonomere 2,2’-Spirobi[4H-1,3,2-benzodioxasilin] und 2,2 Dimethyl-4H-1,3,2-benzodioxasilin in einem Arbeitsschritt gemeinsam polymerisiert. Die erhaltenen Phenolharz-Siliciumdioxid/Dimethylsiloxan-Hybridmaterialien weisen aufgrund einstellbarer Syntheseparameter unterschiedliche Eigenschaftsprofile auf, die systematisch analysiert wurden. Die Charakterisierung der Produkte erfolgte mit Hilfe der Festkörper-NMR-Spektroskopie, Elektronenmikroskopie, DSC, TGA-MS, sowie durch Extraktionsversuche und die Erzeugung und Analyse poröser Materialien. Neben der simultanen Zwillingspolymerisation wird die Synthese, Charakterisierung und thermisch induzierte Polymerisation literaturunbekannter Silicium-Spiroverbindungen mit einfach- oder zweifach substituierter Salicylalkohol-Einheit beschrieben. Hierbei wurden nanostrukturierte Hybridmaterialien mit teils hohem löslichen Anteil erhalten. Die Produktbildung wird in Abhängigkeit von der Entstehung und Weiterreaktion gefundener Chinonmethid-Strukturen diskutiert.

Nanostrukturen

Zwillingspolymerisation

Organisch-anorganische Hybridmaterialien

DSC

Stickstoff-Physisorption

mesoporöse Materialien

mikroporöse Materialien

Silicium-Spiroverbindung

Phenolharz

Chinonmethid

nanostructure

twin polymerization

organic-inorganic hybrid material

DSC

nitrogen physisorption

mesoporous material

microporous material

silicon monomer

phenolic resin

quinone methide

ddc:540

Nanostruktur

Sol-Gel-Verfahren

Organisch-anorganischer Hybridwerkstoff

Differential scanning calorimetry

Physisorption

Siliciumdioxid

Siloxane

Phenoplast

Wheat Straw-Clay-Polypropylene Hybrid Composites

Sardashti, Amirpouyan

23 September 2009

The preparation of polymeric hybrid composite consisting of organic and inorganic fillers is of interest for industries like automotive, construction and packaging. In order to understand and predict the physical and chemical properties of these hybrid composites, it is necessary to fully understand the nature and properties of the employed fillers. In this study, the preparation of polypropylene hybrid composite consisting of wheat straw and clay was investigated. A detailed study was performed on wheat straw from South Western Ontario region. The effect of grinding the straw and compounding it with polypropylene was investigated. Experiments were carried out to identify the thermal stability of the ground wheat straw with respect to their size and composition. It was important to identify a correlation between these properties in order to minimize the straw degradation by processing and also to improve the final properties of the hybrid composite. The composite samples were prepared through melt blending method using a co-rotating twin-screw extruder. Sample test bars were prepared by injection moulding. The composition of the constituents of the hybrid composite; percentages of wheat straw, clay and coupling agent, were varied in order to investigate their influence on thermal stability, water resistance and mechanical properties. The results of the study indicated that grinding the wheat straw with a hammer mill produced particles with different sizes and shapes. It was found that through the grinding system all particles, regardless of their size, had a multi-layered structure similar to the plant structure. Further hammer milling did not produce plant particles with long aspect ratios that would be expected in a defibrillation process. Analysis of the chemical composition of wheat straw particles of different sizes and shapes was used to measure the ratio of hemicelluloses: lignin and the ash content. It was found that the large particles contained more amount of lignin whereas smaller particles had larger amount of ash content. The thermal stability of the particles was found to be a function of particle size rather than the lignin content. Particle size analysis on the wheat straw particles after the extrusion process indicated a reduction in the particle length and aspect ratio. The thermal stability of the composites was found to be enhanced by the addition of clay particles at higher temperature and the addition of coupling agent at lower temperatures. Increasing the amount of wheat straw and clay content increased the flexural modulus and reduced the resistance for water absorption. Increasing the amount of coupling agent also increased the flexural modulus and resistance for water absorption. The morphological study by scanning electron microscopy revealed that coupling agent increased the interfacial interaction between the particles and the polymer matrix.

Biocomposite

Biodegradable

Natural Fiber

Natural Filler

Wheat Straw

Polypropylene

Clay

Coupling Agent

Automotive

Construction

Extrusion

Injection Molding

Particle Size

Solvent Extraction

Particle Density

Scanning Electron Microscopy

Thermo Gravimetric Analysis

Differential Scanning Calorimetry

Flexural Strength

Flexural Modulus

Water Absorption

Melt Flow Index

X-Ray Diffraction

Chemical Engineering

Wheat Straw-Clay-Polypropylene Hybrid Composites

Sardashti, Amirpouyan

23 September 2009

The preparation of polymeric hybrid composite consisting of organic and inorganic fillers is of interest for industries like automotive, construction and packaging. In order to understand and predict the physical and chemical properties of these hybrid composites, it is necessary to fully understand the nature and properties of the employed fillers. In this study, the preparation of polypropylene hybrid composite consisting of wheat straw and clay was investigated. A detailed study was performed on wheat straw from South Western Ontario region. The effect of grinding the straw and compounding it with polypropylene was investigated. Experiments were carried out to identify the thermal stability of the ground wheat straw with respect to their size and composition. It was important to identify a correlation between these properties in order to minimize the straw degradation by processing and also to improve the final properties of the hybrid composite. The composite samples were prepared through melt blending method using a co-rotating twin-screw extruder. Sample test bars were prepared by injection moulding. The composition of the constituents of the hybrid composite; percentages of wheat straw, clay and coupling agent, were varied in order to investigate their influence on thermal stability, water resistance and mechanical properties. The results of the study indicated that grinding the wheat straw with a hammer mill produced particles with different sizes and shapes. It was found that through the grinding system all particles, regardless of their size, had a multi-layered structure similar to the plant structure. Further hammer milling did not produce plant particles with long aspect ratios that would be expected in a defibrillation process. Analysis of the chemical composition of wheat straw particles of different sizes and shapes was used to measure the ratio of hemicelluloses: lignin and the ash content. It was found that the large particles contained more amount of lignin whereas smaller particles had larger amount of ash content. The thermal stability of the particles was found to be a function of particle size rather than the lignin content. Particle size analysis on the wheat straw particles after the extrusion process indicated a reduction in the particle length and aspect ratio. The thermal stability of the composites was found to be enhanced by the addition of clay particles at higher temperature and the addition of coupling agent at lower temperatures. Increasing the amount of wheat straw and clay content increased the flexural modulus and reduced the resistance for water absorption. Increasing the amount of coupling agent also increased the flexural modulus and resistance for water absorption. The morphological study by scanning electron microscopy revealed that coupling agent increased the interfacial interaction between the particles and the polymer matrix.

Biocomposite

Biodegradable

Natural Fiber

Natural Filler

Wheat Straw

Polypropylene

Clay

Coupling Agent

Automotive

Construction

Extrusion

Injection Molding

Particle Size

Solvent Extraction

Particle Density

Scanning Electron Microscopy

Thermo Gravimetric Analysis

Differential Scanning Calorimetry

Flexural Strength

Flexural Modulus

Water Absorption

Melt Flow Index

X-Ray Diffraction

Chemical Engineering