Catalytic Effect of Nanoparticles on Primary and Secondary Phase Nucleation

Michael P. de Cicco; John H. Perepezko

doi:10.4028/www.scientific.net/MSF.765.250

Paper Titles

High Speed Imaging Study of the Dynamics of Ultrasonic Bubbles at a Liquid-Solid Interface
p.230

Effect of Travelling Magnetic Fields on the Dendritic Microstructure of AlSi and AlSiMn
p.235

Material Properties of Cast Aluminium Alloys Produced by Various Casting Processes
p.241

Study of Mechanical Properties of an LM24 Composite Alloy Reinforced with Cu-CNT Nanofillers, Processed Using Ultrasonic Cavitation
p.245

Catalytic Effect of Nanoparticles on Primary and Secondary Phase Nucleation
p.250

Practical Considerations on the Application of Ultrasonic Treatment to Mg-Al Shape Castings
p.255

A Study of the Behaviour of Double Oxide Films in Al Alloy Melts
p.260

Assessment of Quality when Delivering Molten Aluminium Alloys Instead of Ingots
p.266

Effect of Ultrasonic Melt Treatment on Degassing and Structure of Aluminium Alloys
p.271

HomeMaterials Science ForumMaterials Science Forum Vol. 765Catalytic Effect of Nanoparticles on Primary and...

Catalytic Effect of Nanoparticles on Primary and Secondary Phase Nucleation

Abstract:

Nanoparticles were shown to catalyze nucleation of primary and secondary phases in metal matrix nanocomposites (MMNCs). This catalysis is important as it contributes to the mechanical property enhancement in the MMNCs. Primary aluminium grain refinement was demonstrated in A356 matrix nanocomposites. Various types and sizes of nanoparticles (SiC, TiC, γ-Al₂O₃; 10-96 nm) were used to make these MMNCs and in all cases the MMNCs had smaller, more equiaxed grains compared to the reference A356. Using the droplet emulsion technique, undercoolings were shown to be significantly reduced. Undercoolings in the MMNCs were in good general agreement with the undercooling necessary for free growth, suggesting the applicability of this model to nucleation on nanoscale catalysts. Secondary phase nucleation catalysis was demonstrated in a zinc alloy AC43A MMNC and a binary Mg-4Zn MMNC. In AC43A, secondary phase nucleation was catalyzed with the addition of various nanoparticles (TiC, SiC, γ-Al₂O₃). The secondary phase nucleation catalysis in AC43A coincided with ductility enhancement. In Mg-4Zn, SiC nanoparticle addition changed the secondary phases that formed. MgZn₂ was formed in the MMNC at relatively high temperatures consuming the Zn and reducing the amount of the low temperature Mg₂Zn₃ phase that formed in the reference alloy. The change in secondary phase formation coincided with significant enhancement in strength and ductility.

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Materials Science Forum (Volume 765)

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250-254

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https://doi.org/10.4028/www.scientific.net/MSF.765.250

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July 2013

Authors:

Michael P. de Cicco, John H. Perepezko

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Free Growth, Nanocomposite, Nucleation

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