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Author: Simon Hechler
Publisher:
Published: 2018
Total Pages:
ISBN-13:
DOWNLOAD EBOOKAuthor: Mark Lyell Johnson
Publisher:
Published: 2015
Total Pages: 291
ISBN-13:
DOWNLOAD EBOOKOver the last 60 years, bulk metallic glasses have emerged as a new class of materials with highly desirable material properties. Their high strength, high elasticity, and corrosion resistance are attractive properties for viable commercial products. At its core, material properties are directly related to the underlying microstructure. By understanding the structural and chemical order in the liquid and undercooled liquid and their relationship to thermophysical properties such as viscosity, a greater understanding of bulk metallic glass formation can be achieved. In this dissertation, electrostatic levitation techniques are used to study the liquid in a containerless environment using a combination of X-ray and neutron scattering techniques. An X-ray diffraction study of liquid and glass Ni-Nb(-Ta) alloys reveals that an acceleration in the rate of structural ordering must take place near the glass transition, providing the framework for a structural description of fragility. X-ray diffraction and thermophysical property measurements of Zr-Ni binary alloys further characterize the structural connection to viscosity, and reveal signatures of chemical ordering in the liquid. By combining X-ray and neutron scattering measurements, the topological and chemical order in Zr80Pt20 and Zr77Rh23 liquids is characterized. Very different chemical order is found between these alloys, despite their remarkable similarity in topological order. Due to this structural similarity, a new metastable phase is predicted and later identified emerging from a deeply supercooled Zr77Rh23 liquid. Zr77Rh23 is found to have many metastable crystallization pathways, which are further characterized here. Through simultaneous wide-angle and small-angle X-ray scattering, the devitrification behavior of a bulk metallic glass (Vitreloy 105) is investigated and is found to decompose into two distinct compositions during crystallization. By understanding crystallization pathways in good glass-forming alloys, a better understanding of glass formation and its connections to structural and thermophysical properties can be achieved.
Author: Matthew E. Blodgett
Publisher:
Published: 2015
Total Pages: 464
ISBN-13:
DOWNLOAD EBOOKMetallic glasses (and glasses in general) offer unique material properties compared to their crystalline counterparts. Yet the physics of the glass transition remain poorly understood. By examining the evolution of properties in the liquid as it is cooled toward the glass transition we hope to discern how they relate to glass formation. Of particular interest is the concept of kinetic fragility, first defined in terms of the viscosity behavior near the glass transition, and what it means for a high temperature liquid to be "fragile" or "strong." This dissertation presents several studies of metallic liquids using the electrostatic levitation technique. A method for determining the evaporation rate of samples is developed, an important factor for consideration in many experiments and industrial applications. It may also yield further insights when coupled with surface tension measurements, a technique for which is also developed here, with encouraging preliminary results. A method of extracting additional structural information from X-ray diffraction on a related set of alloys is presented and applied to liquid Cu-Zr alloys; this is the first time to this author's knowledge that this technique has been applied to liquids. The high-temperature viscosity of a large set of alloys is measured and it is found that they obey a simple universal curve with only two parameters. These parameters are closely related to fundamental properties of the liquid, the infinite temperature viscosity limit and the glass transition temperature. The relationship of glass-formability to kinetic and thermodynamic properties is examined in CuZrAl alloys. The existence of a structural crossover temperature is examined in the Vit106 alloy and microgravity experiment designs are presented for upcoming experiments on the International Space Station. Finally, a new procedure for acquiring and analyzing surface tension data with the oscillating drop method is developed to account for the effect of sample rotation, with results presented for a variety of samples, creating intriguing possibilities for future research.
Author: Isabella Gallino
Publisher: Springer
Published: 2024-11-06
Total Pages: 0
ISBN-13: 9783031715358
DOWNLOAD EBOOKThis book deepens the current understanding of the thermodynamics and kinetics of metallic glass-forming liquids, and their connection with the glass-formation process in terms of fundamental physical metallurgy concepts. It surveys and reports on the progress made in the last few decades to access the ultra-viscous liquid state of thermally stable bulk metallic glass (BMG) forming alloys and study the changes in atomic structure, viscosity, and enthalpy during the vitrification including physical aging. Featuring a comprehensive look at the physical properties of the undercooled liquid in the ultra-viscous state at temperatures near the glass transition, the book reports on detailed investigations of the thermodynamic functions, viscosity, volume, relaxation time, and structural ordering in the undercooled liquid. Additionally, it introduces state-of-the-art in-situ characterization tools such as chip-calorimetry, synchrotron x-ray diffraction, and x-ray photon correlation spectroscopy as applied to novel studies of liquid–liquid transitions in the supercooled liquid and in the vicinity of the glass transition, and establishes these common, if not universal, phenomena in BMG-forming alloys. This book is intended for researchers, graduate students, and professionals in the fields of materials science, physical metallurgy, and condensed matter physics, who are interested in the thermodynamics and kinetics of metallic glass-forming liquids and their connection with the glass formation process.
Author:
Publisher:
Published: 2005
Total Pages: 11
ISBN-13:
DOWNLOAD EBOOKThree properties of bulk metallic glasses were investigated: (1) atomic motions; (2) characteristics of bonding and electronic states; (3) fracture. Atomic motion in glassy PdNiCuP was investigated by NMR over a wide temperature range from below the glass transition temperature Tg to above the liquidus temperature Tliq. This study reveals the temperature in the supercooled liquid region, below which motions of different elements begin to diverge. It sheds light on the nature of the crossover temperature Tc proposed by mode coupling theory. Also, hopping was shown to persist below Tg. The electronic states of various metallic glasses were studied by NMR including CuZrAl, Ce-based, and Y-based alloys. Results established some correlation between the glass forming ability and the characteristics of electronic states. This sheds light on the structure and formation of metallic glasses. Finally, we studied the fracture surfaces of various bulk metallic glasses including the brittle Mg-based bulk metallic glass. We established a clear correlation between the fracture toughness and plastic process zone size for various glasses. The results indicate that the fracture in brittle metallic glassy materials might also proceed through the local softening mechanism but at different length scales.
Author: Rongrong Dai
Publisher:
Published: 2020
Total Pages: 136
ISBN-13:
DOWNLOAD EBOOKMetallic glasses have drawn significant attention due to their unique properties, such as high strength, excellent elastic energy storage capacity, and versatile processability. However, why some liquids can easily form metallic glasses while others don't is still unclear. Since metallic glasses are formed when liquids are cooled fast enough to bypass crystallization, we hope to better understand glass formation by investigating the structural evolution and thermophysical properties of the liquids as they are cooled toward the glass transition. Multiple molecular dynamics simulations suggest a crossover temperature for the dynamics near the liquidus temperature, which corresponds to the onset of cooperative structural rearrangements and may be the beginning of the glass transition. In this dissertation, a possible structural signature of this onset of cooperativity is first identified using high-energy synchrotron X-ray scattering studies and viscosity measurements on electrostatically levitated liquids. We also address the practical question of how to predict glass formation from properties of the high temperature liquids. A method to accurately predict the glass transition temperature in metallic glasses from properties of the equilibrium liquids is proposed. It uses the viscosity and the thermal expansion coefficient for the equilibrium liquid. Using the predicted glass transition temperature and a fragility parameter developed from the liquid properties, a new prediction formula is generated, which only uses the liquid properties. While the prediction formula works for most cases, in some cases, it fails. The analysis of these anomalous cases demonstrates that the structural similarity between the liquid and crystal phases plays an important role in the glass formability. This is the first demonstration of this important controlling factor for glass formability. We also used machine learning (Lasso regression and Random Forest) to predict the glass formability and identify important predictors. The identified important predictors are in good agreement with those from the empirical rules. Finally, the evolution of the Cu46Zr54 liquid structure is investigated by elastic neutron scattering (with isotopic substitution) and synchrotron X-ray scattering studies. The experimental results show that the number of Cu-Cu and Zr-Zr atom pairs increases as the temperature decreases, while the number of Cu-Zr atom pairs decreases on cooling. This result disagrees with predictions from previous molecular dynamics studies, suggesting that the potentials used in the molecular dynamics simulations should be reassessed.
Author: Behrooz Movahedi
Publisher: BoD – Books on Demand
Published: 2016-08-17
Total Pages: 180
ISBN-13: 9535125117
DOWNLOAD EBOOKMetallic glasses and amorphous materials have attracted much more attention in the last two decades. A noncrystalline solid produced by continuous cooling from the liquid state is known as a glass. From the other point of view, a noncrystalline material, obtained by any other process, for example, vapor deposition or solid-state processing methods such as mechanical alloying, but not directly from the liquid state, is referred to as an amorphous material. At this moment, bulk metallic glasses (BMG) are appearing as a new class of metallic materials with unique physical and mechanical properties for structural and functional usage. Extreme values of strength, fracture toughness, magnetic properties, corrosion resistance, and other properties have been registered in BMG materials.
Author: Benjamin A. Legg
Publisher:
Published: 2006
Total Pages: 138
ISBN-13:
DOWNLOAD EBOOKThis study utilizes differential scanning calorimetry (DSC) to characterize the thermodynamics, kinetics and crystallization b processes of a new Pt57.3Cu14.6Ni5.3P22.8 bulk metallic glass forming alloy. The heat capacity of the alloy is measured for the crystalline, glassy, and supercooled liquid phases. This data is used to obtain thermodynamic driving forces for crystallization and quantify the thermodynamic fragility. Kinetic properties of the alloy are investigated by observing the glass transition under different heating rates. The heating rate dependence of the glass transition is then used to calculate the kinetic fragility and estimate how the material's viscosity varies with temperature. DSC is also used to observe the crystallization event at variety of temperatures and generate a Time-Temperature-Transformation (TTT) diagram for crystallization. The crystallization results and TTT diagram are compared with thermodynamic and kinetic data using classical nucleation theory, and different models for crystallization are discussed.
Author: David C. Riegner
Publisher:
Published: 2016
Total Pages:
ISBN-13:
DOWNLOAD EBOOKMetallic glasses, a class of metal alloys which lack a periodic crystal structure, exhibit exceptional property combinations not accessible by other classes of materials. In spite of promise for widespread application, metallic glasses are difficult to synthesize and understanding of their structure and behavior is limited compared to crystalline alloys. There is no predictive criterion for determining if a particular alloy is capable of forming glass. Numerous glass-forming alloys have been reported, spanning a wide range of possible properties largely through trial and error. Engineering of these materials is difficult, as the connection between atomic structure and macroscopic behavior is not sufficiently developed to exploit particular behaviors in any intentional capacity. Using Molecular Dynamics (MD) simulations, three metallic glass-forming systems, Al-La, Cu-Zr and Cu-Ti-Zr were investigated and compared with the intention of connecting structure to properties and illuminating differences in glass-forming behavior in different alloys. From these simulations a specific mechanism occurring in the liquid, the changing of nearest neighbor environments, was identified and correlated to liquid viscosity. The change in viscosity with temperature, called fragility, was connected to this atomic-scale behavior allowing glass formers and non-glass formers in the Al-La alloys system to be separated from each other. The structure of each glass is readily available from these simulations, and the changes to neighbor environments in Al-La and Cu-Zr alloys, were found to be very similar when comparing the smaller atom type (Al, Cu). Differences in system-wide behavior for Al-La and Cu-Zr can be described based upon the behavior of the larger atom type (La, Zr), where Zr causes a major change in behavior as the majority component not exhibited by even very La-rich alloys. This dissimilarity between La and Zr provides a plausible explanation for Cu-Zr’s superior glass-forming ability compared to Al-La. Experimental data indicated that Cu-Ti-Zr achieve maximum glass-forming ability near Cu51.7Zr36.7Ti11.6. The addition of Ti to the Cu-Zr binary system causes a decrease in nearest-neighbor-switching events and stabilizes structures formed in the liquid, rather than destroying them. Cu51.7Zr36.7Ti11.6 also divides two compositional regions of hardness dependence: above 37% Zr the hardness scales with the concentration of Cu, while below 37% Zr the hardness scales with the concentration of Ti. Based on concepts developed for Al-La and Cu-Zr it was revealed that removing Cu drastically reduced the number of efficiently-packed Cu-centered structures. Below 37% Zr this effect is compensated by an increase in other dense structures but above 37% the effect is both more potent and uncompensated. The loss of these structures is responsible for the changes in yield behavior, and has an effect on the GFA. Finally, extension of these simulations to additional systems requires new multi-component EAM potentials, an essential input for MD simulations. The Rapid Alloy Method for the Production of Accurate General Empirical Potentials (RAMPAGE) was developed to create new multi-component potentials from elemental potentials available in the literature. Using RAMPAGE, the characteristics identified in glass-forming systems can be investigated in other metallic systems.
Author: Justin Cheney
Publisher:
Published: 2004
Total Pages: 322
ISBN-13:
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