Centrifugal Atomization of Glass-Forming Alloy Al86Ni8Y4.5La1.5

Pijuan, J.; Cegarra, Sasha Alejandra; Dosta, S.; Albaladejo-Fuentes, Vicente; Riera, M. D.

doi:10.3390/ma15228159

Cited by 6 publications

(4 citation statements)

References 39 publications

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“…The surface area 𝐴𝐴(𝑟𝑟 ⃗) depends on the geometry of the nucleating phase as a consequence of thermodynamic variables such as work 𝛔𝛔𝑉𝑉 (pressure, surface tension and volume), composition, temperature, as seen from the pressure vs. temperature phase diagrams obtained from first-principles calculations found in Kapil et al [29] and from the experimental study on the ice crystal formation [30]. The initially derived model by Ferreira [18] could not predict either the decrease in crystal regularity or the crystalline-glassy transition associated with the cooling rate and composition [31,32]. Ferreira et al [19,20], by considering the volumetric and surface entropy relationship, added both effects to the formulation of nucleation,…”

Section: Mathematical Formulation Of Nucleationmentioning

confidence: 98%

On the Continuous Mechanics First and Second-Order Formulations for Nonequilibrium Nucleation: Derivation and Applications

Ferreira

Moreira

2023

Int J Thermophys

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Nucleation and growth are phenomena that can be applied to several fields of science and technology. On the other hand, nucleation depends on the cooling rate, dislocating the equilibrium, as surface energy depends on the created and deformed surface area. The crystalline/glassy transition limit dependence on the thermal gradient is also analyzed. In this paper, under continuum mechanics, first-and second-order nonequilibrium nucleation formulation models are derived, and a phase-change moving interface is considered in the thermal field. Important nucleation variables are plotted against the cooling rate for several nucleation angles. It is coupled with a theoretical model for the molar-specific heat capacity of solids to analyse its dependence on nucleation kinetics.

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Section: Mathematical Formulation Of Nucleationmentioning

confidence: 98%

On the Continuous Mechanics First and Second-Order Formulations for Nonequilibrium Nucleation: Derivation and Applications

Ferreira

Moreira

2023

Int J Thermophys

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show abstract

“…The initially derived model by Ferreira [18] could not predict either the decrease in crystal regularity and the crystalline-glassy transition associated to the cooling rate and composition [26,27]. Ferreira et al [19,20] by considering the volumetric and surface entropy relationship added both effects to the formulation of nucleation,…”

Section: Mathematical Formulation Of Nucleationmentioning

confidence: 99%

On the continuous mechanics first- and second-order formulations for non-equilibrium nucleation: Derivation and applications

Ferreira

Moreira

2023

Preprint

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Nucleation and growth are phenomena that can be applied to several fields of science and technology. On the other hand, nucleation depends on the cooling rate, dislocating the equilibrium, as surface energy depends on the created and deformed surface area. The crystalline/glassy transition limit dependence on the thermal gradient is also analyzed. In this paper, under the continuum mechanics, first- and second-order non-equilibrium nucleation formulation models are derived, and a phase-change moving interface is considering the thermal field. Nucleation important variables will be plotted against the cooling rate for several nucleation angles. It will be coupled with a theoretical model for the molar-specific heat capacity of solids to analyze its dependence on nucleation kinetics.

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“…CR = (T l − T s )/t ls (12) where T l and T s are the liquidus and solidus temperature, and t ls is the time required for each full solidification state.…”

Section: Cooling Rate Calculationmentioning

confidence: 99%

“…Some of these materials are rapidly solidified alloys, such as amorphous materials, which require strict control of the microstructure of the powder [12]. In the case of centrifugal atomization, the final microstructure of a powder is highly dependent on the thermal transport between a droplet in flight and a surrounding cooling gas once the droplet is ejected from the disk.…”

Section: Introductionmentioning

confidence: 99%

Cooling Rate Modeling and Evaluation during Centrifugal Atomization Process

Cegarra

Pijuan

Riera

2023

JMMP

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Centrifugal atomization is a rapid solidification technique involving fast cooling rates to produce high-quality powders. The final microstructure of the atomized particles is closely linked with the thermal history and cooling rates experienced during the atomization process. However, there is insufficient research on the temperature evolution of metal particles produced by this technique, and most works evaluate the thermal history of the droplet through semi-empirical correlations that lie outside the conditions where they were derived. In this work, the cooling rate of centrifugally atomized Al-4% Cu was studied via mathematical modelling and experimental validation. A heat transfer model was implemented, and the value of the convective heat transfer coefficient was obtained from the Whitaker semi-empirical correlation considering three cases of study for the thermophysical properties of the gas. The validity of the Whitaker correlation was experimentally evaluated by means of cooling rates based on the Secondary Dendrite Arm Spacing (SDAS) technique. The Whitaker correlation with the Reynolds and Prandtl numbers evaluated at the ambient temperature and the gas conductivity evaluated at the film temperature gave the best agreement with the experimental results, with cooling rates in the order of 105 K s−1 for <32.5 µm powders atomized in He atmosphere.

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Centrifugal Atomization of Glass-Forming Alloy Al86Ni8Y4.5La1.5

Cited by 6 publications

References 39 publications

On the Continuous Mechanics First and Second-Order Formulations for Nonequilibrium Nucleation: Derivation and Applications

On the Continuous Mechanics First and Second-Order Formulations for Nonequilibrium Nucleation: Derivation and Applications

On the continuous mechanics first- and second-order formulations for non-equilibrium nucleation: Derivation and applications

Cooling Rate Modeling and Evaluation during Centrifugal Atomization Process

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