Effect of Cooling Rate on Nano-Eutectic Formation in Laser Surface Remelted and Rare Earth Modified Hypereutectic Al-20Si Alloys

Kayitmazbatir, Metin; Lien, Huai-Hsun; Mazumder, Jyoti; Wang, Jian; Misra, Amit

doi:10.3390/cryst12050750

Cited by 6 publications

(1 citation statement)

References 46 publications

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“…In the former case, thermal treatments are perhaps the most important routes, and they have attracted much attention in recent years [1]. According to Nikanorov et al [2] and Kayitmazbatir [3], accurate control of the solidification rate may be highly beneficial in modifying some mechanical properties of Al-Si structures, irrespective of Si concentration. Magnetic fields are attracting growing attention as an atypical and promising method capable of modulating the mechanical properties of Al-Si-based quaternary alloys, with positive effects on microhardness [4].…”

Section: Introductionmentioning

confidence: 99%

Dy–Al–Si System: Experimental Study of the Liquid–Solid Phase Equilibria in the Al-Rich Corner

Cardinale

Parodi

2023

Crystals

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The Dy–Al–Si ternary system has been experimentally studied, as the effect of the dysprosium addition on the constitution and topology of the liquidus surface, focusing on the (Al) rich part. The system has been investigated in a composition range of up to about 58 at% silicon. The alloys constitution and the liquidus surface projection have been determined by means of scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (EDXS), X-ray powder diffraction (XRPD), and differential thermal analysis (DTA). This work is part of a research framework on the properties and solid–liquid phase equilibria of the R Al–Si (R: rare earth) systems. These data, along with the ternary systems isothermal section, are needed to outline the design, plan, and development of new Al–Si-based alloys. In the Dy–Al–Si system, four primary crystallization fields have been experimentally detected: (Si), DyAlxSi(2−x) (orthorhombic form), Dy2Al3Si2 (Τ2), and DyAl(3−x)Six. The following three invariant equilibria have been identified: at 566 °C the ternary eutectic L ⇆ DyAl2Si2 + (Al) + (Si), at 630 °C the U1 L+ DyAl3 ⇆ Dy2Al3Si2 + (Al), and at 562 °C the U2: L+ Dy2Al3Si2 ⇆ DyAl2Si2 +(Al) reactions. A comparison with other known R Al–Si systems has been conducted.

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