Synthesis and Characterizations of Fe-based Metallic Glassy Systems

Shah, Zulfiqar Hussain

January 2011

This thesis is a study of tailoring amorphous Fe-B-Si based alloy to produce bulk glassy rods by adding Nb. We have prepared rapid quenched thin ribbons (thickness ~12 µm) by melt spinning, and glassy rods of diameter ~1mm by Cu-mold casting based on compositions (Fe0.78B0.13Si0.9)100-xNbx (x=0, 4, 8, 12), and studied their different physical properties. The melt-spun ribbons are found to be X-ray amorphous, whereas some nano-crystallinity is observed in the case of rods. All the ribbons show high saturation magnetization and low coercivity, which are the desirable characteristics of a soft ferromagnet. These ribbons are thus suitable for designing high frequency transformers, and sensors from an applications point of view. With increasing Nb content their saturation magnetization, ferromagnetic Curie temperature, and resistivity are found to decrease as expected. The temperature dependence of electrical resistivity shows small positive temperature co-efficient that is expected for a metallic disordered material. We have also studied the modification of the properties on thermal annealing the (Fe0.78B0.13Si0.9)96 Nb4 ribbon at different temperatures in a neutral atmosphere.

melt spun ribbon

soft magnetic properties

crystallization

Curie temperature

electrical resistivity

Other Materials Engineering

Annan materialteknik

Mécanismes de frottement aux interfaces polymères liquides / solide : propriétés de glissement et structure interfaciale / Friction mechanisms at solid / liquid polymers interfaces : wall slip and interfacial structure

Grzelka, Marion

12 December 2019

Le but de ce travail de thèse est d'identifier les mécanismes moléculaires mis en jeu lors du frottement de polymères liquides sur une paroi solide.Dans une première partie, nous avons étudié l'influence de la température T sur le glissement de fondus. Grâce à la technique de vélocimétrie par photoblanchiment, nous avons mesuré la longueur de glissement de PDMS pour plusieurs températures et vérifié l'hypothèse de Navier, qui permet de définir le coefficient de frottement interfacial k comme le rapport entre la viscosité et la longueur de glissement. Loin de la température de transition vitreuse, k augmente exponentiellement avec 1/T, tendance que nous avons vérifiée par une mesure indépendante pour des lentilles de PDMS réticulé. Ainsi, le mécanisme de frottement d'un fondu de polymère est un processus thermiquement activé. La comparaison des énergies d'activation du frottement et de la viscosité prédit le sens de variation de la longueur de glissement avec la température.Le second volet de notre travail s'est focalisé sur l'identification des mécanismes moléculaires du frottement de solutions semi-diluées de polymère. Les expériences de glissement pour des solutions de PS dans le DEP nous ont permis de mettre en évidence un régime transitoire de glissement des solutions, correspondant à une mise en glissement du fluide. Nous avons proposé un modèle de glissement d'un fluide de Maxwell en accord quantitatif avec les expériences.Dans le régime de glissement stationnaire, nous avons étudié l'influence de la fraction volumique φ en polymère sur le frottement des solutions. En régime newtonien, la loi d'échelle mesurée pour k φ en fonction de la fraction volumique met en évidence la dépendance du coefficient de frottement interfacial avec l'écart à la température de transition vitreuse des solutions. Nous attribuons le frottement des solutions de PS dans le DEP au frottement des blobs sur la paroi et non à la formation d'une couche déplétée en polymère.Enfin des expériences de réflectivité de neutrons nous ont permis d'observer directement l'interface solide / solution de polymère. Nous avons mis en évidence l'existence d'une couche adsorbée en polymère. Nous avons mesuré son profil de concentration en fonction de la distance à la paroi. L'interdigitation des chaînes libres et de surface affecte le glissement des solutions. / The aim of this work is to identify the molecular mechanisms driving the friction of liquid polymers on a solid substrate.First, we studied the effect of the temperature T on the slippage properties of PDMS melts. Using a velocimetry technique based on photobleaching, we measured the temperature dependence of the slip length of PDMS and checked the validity of Navier’s hypothesis, which defines the friction coefficient k as the ratio between the bulk viscosity to the slip length. Far above the glass transition temperature, k(T) increases exponentially with 1/T, a result that we confirmed with an independent measurement of k for the friction of crosslinked PDMS lenses. The friction mechanism of melts is a thermally activated process. The comparison of the activation energies for the friction and for the viscosity allows one to predict if the slip length increases or deacreases with temperature.We then focused our work on the identification of the friction mechanisms of semi diluted polymer solutions. Based on slip experiments of PS in DEP solutions, we evidenced a transient onset of slippage regime. Considering the viscoelasticity of the fluid and its friction properties, we developed a mechanical model of friction of a Maxwell-like fluid that well describes our experimental data.In the stationary slippage regime, we studied the influence of the polymer volume fraction φ on the slippage of solutions of polymer. In the Newtonian regime, the measured scaling law for k φ as a function of the volume fraction highlights the dependence of the friction coefficient on the distance to the glass transition temperature of the solution. Thus, the friction of the PS in DEP solutions can be attributed to the friction of blobs on the surface, rather than to the existence of a depletion layer.We directly observed the solid / polymer solution interface thanks to neutron reflectivity: these experiments reveal the formation of an adsorbed polymer layer and we could measure its concentration profile close to the solid wall. The interdigitation between volume and surface polymer chains plays a key role in the slippage of the solutions.

Glissement

Frottement

Solution de polymère

Polymères fondus

Structre d'interface

Slippage

Friction

Solutions of polymer

Melt

Interfacial structure

The Effects of Elevation and Vegetation Type on Snow Accumulation and Melt in Logan Canyon, Utah

Thies, Paul R.

01 May 1973

Snow accumulation and melt characteristics were studied in Logan Canyon, Utah. Three replications of aspen, conifer, and open field types at 6300, 7100,and 8000 feet were measured for snow depth and water content during 1972. Elevation was found to have the greatest effect on snow water content. The gradient of increasing water content with rise ln elevation was found to be .51 inches/100 feet in the zone from 6300 to 7100 feet and 1.9 inches/100 feet from 7100 to 8000 feet. The cooler temperatures at higher elevations partially account for the 8000 foot zone beginning to melt 40 days after the 7100 foot zone, and the 7100 foot zone trailing the 6300 foot zone by 20 days. Although the snow at the 8000 foot elevation began melting later than the lower zones, it melted at twice the rate. Vegetation cover type has no significant effect on the amount of snow deposited. However, the conifer type protects the snowpack from solar radiation causing the snowpack to have a significantly lower density than the snowpack assocaited with either aspen or open field. The snowpack under the conifer canopy melts 30 percent slower and remains 17 days longer.

Elevation

Vegetation

Snow

Accumulation

Melt

Logan

Canyon

Utah

Life Sciences

Other Life Sciences

DEVELOPMENT OF AN AMORPHOUS BASED SUSTAINED RELEASE TABLET OF MELT EXTRUDED IBRUTINIB A BRUTON’S TYROSINE KINASE INHIBITOR

Alshahrouri, Bayan, 0000-0002-5808-314X

January 2021

Ibrutinib is the first Bruton`s tyrosine kinase (BTK) inhibitor for oral administration approved by FDA in 2014. It is the first-line treatment for B-cell malignancies, which are the most common hematologic neoplasia. Ibrutinib is a relatively safe alternative for currently used treatment modalities that are associated with long-term toxicity and resistance. However, ibrutinib is considered as BCS class II drug and has very low solubility in an aqueous medium (13 μg/ml at PH 8.0) and has six different polymorphic forms. Furthermore, recommended daily dose of ibrutinib is about 420 mg to 560 mg, which causes severe GI disturbances, with poor patient compliance. This represent a major critical concern because drug is used chronically. Increasing drug solubility and controlling rate of drug release may improve both bioavailability at significantly lower daily administered doses and by implication could minimize GI side effects and improve patient compliance.The objective of this study is to utilize Hot Melt Extrusion (HME) to develop a stable amorphous solid dispersion (ASD) of ibrutinib using Copovidone (PlasdoneTM S-630 Ultra) as a carrier for inclusion into a hydrating matrix for sustained release delivery. Development of ASD based on HME is an efficient method to overcome poor solubility problem and stabilize the drug`s metastable polymorphic states. It is known that amorphous systems are energetically at a higher thermodynamic state and can dissolve to a much greater extent relative to their crystalline counterpart. A stable sustained-release ASD based system may offer many advantages, including reduction in frequency of administration and GI disturbances with propensity to enhance solubilization while suppressing recrystallization. The ASD systems prepared in this study was stable, amorphous, and single-phase systems up to 60% API load as confirmed by X-ray powder diffraction (XRPD), modulated differential scanning calorimetry (mDSC), and rheological analysis. Supersaturated micro-dissolution testing of melt-extruded powder in fasted state simulated intestinal fluid demonstrated up to 70% increase in supersaturation solubility than the saturation solubility of crystalline counterparts. In addition, dissolution data based on the standard USP paddle method for the formulated SR tablets demonstrated a prolonged release up to six hours and a maximum of 53% higher drug release than crystalline ibrutinib. In conclusion, the results of this study indicate that ibrutinib amorphous solid dispersion developed utilizing hot-melt extrusion technology and Copovidone (PlasdoneTM S-630 Ultra) as a carrier is able to produce stable and homogeneous single-phase ASD system with enhanced solubility and desirable sustained drug release rate. / Pharmaceutical Sciences

Pharmaceutical sciences

Copovidone

Hot-melt extrusion

Ibrutinib

Sustained release matrix tablet

Materials cleanliness assessment in rheocasting : An investigation in the melt quality in aluminum alloy casting

Hellberg, Gustav

January 2022

The use of aluminum is a key factor in creating an Eco-friendlier automotive industry. The material has good properties and the ability to reuse the material. The requirement on the material in this industry is very high, due to the exposed working environments. The usage of aluminum will reduce the vehicle’s weight, which in turn will reduce emissions.    Aluminum casting is not free from obstacles. The properties can be altered with different casting methods and the design of the casting to a great extent. This master will focus on how the melt quality will have an impact on the material properties and how it is changed during the process. To fully understand what happens to the melt during the casting process, samples are received at different stages for further investigation. Different data is collected to be able to analyze what happens during the process. A quality measurement called the Quality index is used to determine the change in the quality in the different stages. With data from bifilm and density index, conclusions can be made on how and where the impurities are entering the melt and their effect. A conclusion is made that the degassing harms the quality of the melt.

Melt quality

Density index

Bifilms index

RheoMetal casting

Aluminum casting

Degassing.

Materials Engineering

Materialteknik

IMPACTS OF CLIMATE CHANGE ON THE QUANTITY AND TIMING OF RIVER FLOW IN THE UPPER INDUS BASIN, KARAKORAM-HIMALAYA, PAKISTAN / パキスタン国力ラコルム・ヒマラヤ山脈インダス川上流城における河川流量と流出時期に及ぼす気候変動の影響

BAIG, MUHAMMAD SOHAIB

26 July 2021

京都大学 / 新制・課程博士 / 博士(工学) / 甲第23429号 / 工博第4884号 / 新制||工||1763(附属図書館) / 京都大学大学院工学研究科社会基盤工学専攻 / (主査)教授 田中 茂信, 准教授 田中 賢治, 准教授 佐山 敬洋 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Upper Indus River Basin

Karakoram-Himalaya

Climate Change

River Flow

Pakistan

Glacier Melt

Hydrology

500

Extensional-flow-induced Crystallization of Polypropylene

Bischoff White, Erica E

01 January 2011

A filament stretching extensional rheometer was used to investigate the effect of uniaxial flow on the crystallization of polypropylene. Samples were heated to a temperature above the melt temperature to erase their thermal and mechanical histories. The Janeschitz-Kriegl protocol was applied and samples were stretched at various extension rates to a final strain of e = 3.0. Differential scanning calorimetry was applied to crystallized samples to measure the degree of crystallinity. The results showed that a minimum extension rate, corresponding to a Weissenberg number of approximately Wi = 1, is required for an increase in percent crystallization to occur. Below this Weissenberg number, the flow is not strong enough to align the tubes of constrained polymer chains and as a result there is no change in the final percent crystallization. An extension rate was also found for which percent crystallization is maximized. The increase in crystallinity is likely due to flow-induced orientation and alignment of tubes of constrained polymer chains. Polarized-light microscopy verified an increase in number and decrease in size of spherulites with increasing extension rate. Small angle X-ray scattering showed a 7% decrease in inter-lamellar spacing at the transition to flow-induced increase in crystallization. Crystallization kinetics were examined by observing the time required for melts to crystallize under uniaxial flow. The crystallization time decreased with increasing extension rate, even for extension rates where no increase in percent crystallization was observed. These results demonstrate that the speed of crystallization kinetics is greatly enhanced by the application of extensional flow.

Extensional flow

flow-induced

crystallization

polymer melt

polypropylene

Engineering

Mechanical Engineering

Structure-Property Relationships of Alicyclic Polyesters

Thompson, Tiffany Nikia

27 July 2023

Polyesters are an important class of polymers in many applications ranging from common-use objects—such as packaging containers, clothing, and upholstery—to more advanced applications, such as lightweight strength materials in construction, electronics, and automotive parts. Poly(ethylene terephthalate) (PET), a semicrystalline aromatic polyester, is commercially the most common and widely used polyester. However, the inability to reuse polyesters such as PET over multiple reprocessing cycles in the same application remains a challenge due to the susceptibility of the polymer to thermal, hydrolytic, and oxidative degradation during melt processing. The various degradation modes result in a drop in molecular weight, loss of key physical properties, and release of volatile compounds. Furthermore, the vast issue of plastic accumulation and pollution in diverse ecosystems, landfills, and waste streams underscores the burgeoning need to create a closed loop—responsible materials management from the cradle to the grave—through these materials' continual reuse and recycling. Additionally, most feedstock monomers used in polyester synthesis primarily come from fossil fuels. Fossil fuel extraction processes release gases and particulate matter that adversely affect health, climate, and the environment, so finding alternative sources for polyester monomers is paramount. This dissertation addresses key polyester challenges by designing and synthesizing alicyclic polyesters. First, we synthesized a series of alicyclic polyesters using various ratios of two regioisomers of a previously unexplored alicyclic monomer, bicyclohexyldimethanol (BCD). We learned from this alicyclic polyester series that we could tailor properties such as morphology and elongation while raising the glass transition temperatures (Tg) and lower melting temperatures (Tm) of the polymers based on the regioisomer composition. Furthermore, the regioisomer that led to polymers with semicrystalline morphologies inspired us to apply it to PET as a copolymer, with the goal of increasing PET's stability under melt processing conditions by lowering Tm. Next, we synthesized a series of alicyclic copolyesters with different BCD compositions in the polymer. The results showed that the presence of the alicyclic rings of BCD lowers the melting temperature and enhances the stability of the polymer in the melt compared to PET. These results directed us toward synergistically combining the benefits of alicyclic monomers with sustainable biobased monomers to enhance polyester properties, thereby decoupling fossil fuels from polymer feedstock production. Accordingly, we explored naturally ubiquitous, structurally diverse, and chemically modifiable terpenes present in the resin exudate of conifers. Specifically, we derived alicyclic diacid and diol monomers from the terpene verbenone and used them to synthesize a series of biobased alicyclic polyesters. The polymer series exhibited a range of morphologies, Tg's, as well as enhanced stabilities. The semicrystalline composition exhibited higher Tg and slightly lower Tm than PET while possessing exceptional stability in the melt over PET. / Doctor of Philosophy / Polyesters are important materials widely used today. They are very large molecules composed of a basic chemical unit linked together in a repeating fashion to make a long chain. The nature of the links between the basic units is referred to as an ester link, and materials are described as polyester when the number of these links is large. The applications of polyesters range from common-use objects—such as packaging containers, clothing, and upholstery—to more advanced applications in construction, transportation, and defense—such as body armor, seat belts, and lightweight strength materials and coatings in construction. The properties of its basic structural unit enable the wide breadth of applications of polyesters. A significant challenge that faces polyesters is the inability to reuse the material in the same application multiple times. The material must be reprocessed by melting at high temperatures to be reused. This melting breaks down the polyester chain, weakening the material and rendering it unsuitable for continued use. The need to reuse polyesters is an important area of concern because of the growing problem of plastic accumulation and pollution in diverse ecosystems and landfills. If these materials are continually reused, they will not accumulate as environmental waste. Furthermore, the basic starting unit that makes up polyesters largely comes from fossil fuels. Fossil fuel extraction processes release gases and particulate matter that adversely affect health, climate, and the environment. The issues of polyester breakdown in the melt and fossil fuel use to make the polyester can be addressed in two ways. First, reinforcing the polyester through changes to the basic structural unit can prevent the breakdown of the material when melted, thereby enabling its reuse over multiple cycles. Second, reducing the dependence on fossil fuels to make the basic structural unit of the polyester can be accomplished by using more renewable biobased sources instead. This dissertation seeks to address these two challenges. In the first approach, we investigate the effect of using a special cyclic structure in the polyester make-up to reinforce its stability when melted and enable its reuse. Next, we use plant materials to derive these unique structures to reduce the dependence on fossil fuels and mitigate the environmental, climate, and health effects of fossil fuel use.

biobased polyesters

structure-property relationships

alicyclic monomers

alicyclic copolyesters

melt-phase polymerization

Tectonic setting and heat source of an ultrahigh-temperature metamorphic terrane constrained from prograde pressure-temperature-time-melting evolution: an example from Rundvågshetta, Lützow-Holm Complex, East Antarctica / 昇温期変成温度－圧力－時間－溶融履歴の構築による超高温変成岩体の形成テクトニクスおよび熱源の制約：東南極リュツォ・ホルム岩体ルンドボークスヘッタにおける例

Suzuki, Kouta

23 March 2023

京都大学 / 新制・課程博士 / 博士(理学) / 甲第24430号 / 理博第4929号 / 新制||理||1704(附属図書館) / 京都大学大学院理学研究科地球惑星科学専攻 / (主査)准教授 河上 哲生, 教授 下林 典正, 教授 田上 高広 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

ultrahigh-temperature metamorphism

prograde metamorphism

petrochronology

melt inclusion

piston-cylinder

400

Synthesis and Characterization of Linear and Branched Polylactic Acid for Use in Food Packaging Applications

Bentz, Kyle C

01 June 2011

Polylactic acid (PLA) resins of various molecular weights and molecular weight distributions were synthesized. Linear, narrow molecular weight distribution (MWD) PLA resins were synthesized, as well as resins containing both high molecular weight branched structures and low molecular weight chains and oligomers. Narrow MWD resins were synthesized for use as adhesives for corrugated paperboard and broad MWD resins were synthesized for use as a waterborne coating. PLA resins were dispersed for use as a waterborne coating. Success has been made at forming films utilizing various plasticizers and surfactants as well as polyvinyl alcohol as dispersing agents. A cold dispersion procedure realized the most success, as a 15% PLA waterborne formulation was achieved. Standard test methods show a high degree of grease resistance for the formulated coatings. A hot melt adhesive was also formulated utilizing blends of narrow MWD resins of various molecular weights. The hot melt adhesive showed a high degree of success as failure occurred at the substrate for the materials tested.

polylactic acid

packaging

polymers

polymer synthesis

waterborne

hot melt

Polymer Chemistry