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When a liquid is subdivided into a fine droplet dispersion in order to isolate nucleation catalysts, substantial undercooling may be observed before solidification as demonstrated by thermal analysis in the current work. At high undercooling, alloy solidification is rapid and can result in the suppression of the usual reactions to yield amorphous phases and nonequilibrium crystalline phases with distinct and novel microstructures. In a complimentary approach, the intense deformation of an elemental layered array drives an atomic scale mixing at the layer interfaces to yield alloying and in some systems an amorphization reaction. In both cases attention to the relevant metastable phase equilibria and reaction kinetics is necessary for the interpretation of the precessing pathway and microstructure that can guide alloy design and control structure synthesis. In studies on Al-base amorphous alloys an enhanced control has been achieved for primary crystallization. This microstructure is characterized by an ultrahigh number density (10(exp 21)/cu m of Al nanocrystals (20nm in diameter) in an amorphous matrix with a high thermal stability (250 deg C) as reflected by a relatively high glass transition temperature, T(sub g). From complimentary rapid solidification and deformation induced amorphization, a critical factor in controlling primary crystallization has been identified as the quenched-in nuclei that are generated during melt quenching. A novel strategy to control and enhance the nanocrystal density has been discovered based upon the introduction of nucleants to catalyze nanocrystalline Al and increase the number density to 10(exp 21)/cu m. Alternatively, by avoiding quenched-in nuclei through deformation processing, bulk glass formation may be achieved in Al-base alloys The basic information that the structure synthesis studies yield also has a broad application to many aspects of solidification and deformation processing of ultrafine microstructures.
At high undercooling, solidification is rapid and can result in the suppression of the usual reactions to yield amorphous phases and nonequilibrium crystalline phases with novel microstructures. In a complimentary approach, the intense deformation of an elemental layered array drives an atomic scale mixing at the interfaces to yield alloying and in some systems an amorphization reaction. Similarly, deformation of amorphous ribbons can drive instabilities that result in the development of nanocrystal dispersions without annealing. In studies on Al-base amorphous alloys an enhanced control has been achieved for the nanometer-scale microstructure formation processes that operate during primary crystallization. This microstructure is characterized by an ultrahigh number density (10EXP 21 - 10EXP 22 cubic m) of Al nanocrystals (20nm in diameter) in an amorphous matrix with a high thermal stability as reflected by a relatively high glass transition temperature, T(sub g). In order to elucidate the nature of the quenched-in atomic configurations, a novel application of nuclear magnetic resonance and fluctuation microscopy has allowed for the identification of medium range ordered regions that will be analyzed further. A novel strategy to control and enhance the nanocrystal density has been discovered based upon the introduction of nucleants to catalyze nanocrystalline Al. Alternatively, by avoiding quenched-in nuclei through deformation processing, bulk glass formation may be achieved in Al-base alloys. The combination of microcalorimetry and careful size distribution analysis has established the non-steady state nature of primary crystallization. The analysis and modeling of the kinetics is central to devising strategies for reproducible control of primary crystallization including the modification of the crystallization path by exploiting multicomponent diffusion behavior in systems with large differences in component diffusivities.
At high undercooling, the solidification of alloys can result in the suppression of the usual crystallization reactions and in the formation of nonequilibrium phases with distinct and novel microstructures. When a liquid is subdivided into a fine droplet dispersion in order to isolate nucleation catalysis, substantial undercooling may he observed before the onset of solidification, as demonstrated by the current work, An improved droplet technique has been applied to investigate the phase selection kinetics, nucleation catalysis reactions and thermal history that control microstructural evolution during solidification of highly undercooled melts. New developments involving droplet population and single droplet experiments in the application of nucleation catalysis to control undercooling have been used to Identify specific active nucleants. In studies on Al-base alloys, an enhanced control and reproducibility of fine scale microstructure formation processes has been achieved in elevated temperature alloys and the new class of amorphous Al alloys. A continuing development of droplet methods to treat copper alloys and cast iron has been pursued along with the application of particle incorporated droplets to examine composite solidification processing. Throughout the experimental work, attention will is given to the evaluation of the relevant metastable phase equilibria and reaction kinetics which are quite useful for the interpretation of solidification microstructure and in the identification of alloy design strategies. In addition, processing models have been developed further with the aim to formulate microstructure maps for high undercooling solidification in order to guide the control of microstructure synthesis. An assessment of the undercooling and thermal history of the solidification products is provided by calorimetric measurements, controlled upquenching.
The undercooling of liquid metals is a fairly common observation, but the amount of undercooling is limited usually by the action of heterogeneous catalysts. When a liquid is subdivided into a fine droplet dispersion in order to isolate nucleation catalysis, substantial undercooling may be observed before the onset of solidification, as demonstrated by the increased undercooling limits established in the current work. At high undercooling, the solidification of alloys can result in the suppression of the usual crystallization reactions and in the formation of nonequilibrium phases with distinct and novel microstructures. A number of processing variables have been established to control undercooling including: droplet size. melt superheat, cooling rate and droplet surface chemistry. The application of thermal analysis together with x- ray diffraction and microstructural examination methods has allowed for an evaluation of the kinetic competition during phase selection, for the determination of the decomposition and melting temperatures of metastable phases and for the assessment of metastable phase diagrams. New advances have also been made in the understanding and control of heterogeneous nucleation and in probing the thermal history of rapidly solidifying samples by upquenching studies as well as in the development of new experimental capacity to study composites. The understanding developed from droplet undercooling studies has a direct application to Rapid Solidification Processing (RSP) and allows for an assessment of RSP treatment in terms of the influence of undercooling and metastable phase equilibria on phase selection and novel solidification microstructure development. The basic information that droplet studies yield also has a broad application to many aspects of solidification processing.
All metallic materials are prepared from the liquid state as their parent phase. Solidification is therefore one of the most important phase transformation in daily human life. Solidification is the transition from liquid to solid state of matter. The conditions under which material is transformed determines the physical and chemical properties of the as-solidified body. The processes involved, like nucleation and crystal growth, are governed by heat and mass transport. Convection and undercooling provide additional processing parameters to tune the solidification process and to control solid material performance from the very beginning of the production chain. To develop a predictive capability for efficient materials production the processes involved in solidification have to be understood in detail. This book provides a comprehensive overview of the solidification of metallic melts processed and undercooled in a containerless manner by drop tube, electromagnetic and electrostatic levitation, and experiments in reduced gravity. The experiments are accompanied by model calculations on the influence of thermodynamic and hydrodynamic conditions that control selection of nucleation mechanisms and modify crystal growth development throughout the solidification process.
"SCIENCE AND TECHNOLOGY OF '!HE UNDEROLED MELT" This title was chosen as the topical headline of the Advanced Research Workshop (ARW) from March 17 to 22 1985, held at the Castle of Theuern. The usual term "Rapid Solidification" is an overlapping description. Due to the fact that nucleation is so eminently important for the undercooling of a melt and this, in turn, is an important characteristic of rapid solidifi cation, undercooling plays an essential role in "rapid solidification." The undercooled melt has caused an "accelerated evolution" (if not a revolution) in materials science during the last decade. Several rather exciting concepts with interesting potential for novel applications are being pursued presently in various laboratories and companies. They concern not only new processes and ha~ware developments, but also present chal lenging perspectives for ventures, including the founding of new companies; or they promise growth possibilities with established larger and smaller industrial establishments.
This volume will summarize the most recent development in experimentation, computation, and theory on chemistry of glass forming melt, including melt structure modeling and melt structure and characterizations. This volume provides a timely update on the advances in glass basic science research and development.