Fast scanning calorimetry study of Al alloy powder for understanding microstructural development in laser powder bed fusion

Fast scanning calorimetry study of Al alloy powder for understanding microstructural development in laser powder bed fusion

[Display omitted] •Fast scanning calorimetry (FSC) was applied for the solidification of AlSi10Mg powder in a wide range of cooling rates (dT/dt).•Focus ion beam was used for microstructural characterization of rapidly solidified AlSi10Mg powder in the FSC equipment.•The secondary dendrite arm spaci...

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Bibliographic Details
Published in:Materials & design Vol. 219; p. 110830
Main Authors: Takata, Naoki, Liu, Mulin, Li, Hongmei, Suzuki, Asuka, Kobashi, Makoto
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-07-2022
Elsevier
Subjects:
Additive manufacturing
Al–Si alloy
Cooling rate
Fast scanning calorimetry
Rapid solidification
Selective laser melting
Additive manufacturing
Selective laser melting
Fast scanning calorimetry
Rapid solidification
Cooling rate
Al–Si alloy
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Summary:[Display omitted] •Fast scanning calorimetry (FSC) was applied for the solidification of AlSi10Mg powder in a wide range of cooling rates (dT/dt).•Focus ion beam was used for microstructural characterization of rapidly solidified AlSi10Mg powder in the FSC equipment.•The secondary dendrite arm spacing (λ) of the primary α-Al phase decreased in the samples solidified at a higher dT/dt.•Extrapolating the relation between λ and dT/dt can estimate the local cooling rate in melt pools of laser additive manufactured Al alloys. We examined the variation in the solidification microstructure of AlSi10Mg alloy powder over a wide range of cooling rates controlled by using the fast scanning calorimetry (FSC) technique. Two exothermic peaks derived from the primary solidification of the α-Al phases and the α-Al/Si eutectic reaction were detected. These exothermic peaks became broader and shifted to lower temperatures at higher cooling rates. Focus ion beam (FIB) milling enables microstructural characterization of AlSi10Mg powder solidified at controlled cooling rates above 102 °C·s−1 in the FSC equipment. The sample solidified at 4 × 104 °C·s−1 exhibited a fine microstructure consisting of a primary α-Al phase surrounded by lamellar-shaped Si phases. The fraction of the Si phase continuously decreased with increasing cooling rate, indicating higher content of solute Si element in the α-Al phase solidified at a higher cooling rate. The secondary dendrite arm spacing (λ) of the primary α-Al phase decreased in the sample solidified at a higher cooling rate (dT/dt). The relation follows a general equation of λ = A (dT/dt)-n (A: 38.4, n: 0.33) in wide range of cooling rate (10-1 ∼ 104 °C·s−1). The results were utilized to discuss the cooling rate of Al alloys during the laser powder bed fusion (L-PBF) process.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2022.110830