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irregular eutectics
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Image
Published: 27 April 2016
Fig. 19 Growth of irregular eutectics. (a) Schematic of branching of the faceted phase at λ br , termination at λ min , and the corresponding shape of the solid-liquid interface. (b) Iron-carbon eutectic alloy directionally solidified at R = 0.017 μm/s. Branching was induced by a rapid
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Image
in Computational Models for Prediction of Solidification Microstructure
> Cast Iron Science and Technology
Published: 31 August 2017
Book Chapter
Book: Alloy Phase Diagrams
Series: ASM Handbook
Volume: 3
Publisher: ASM International
Published: 27 April 2016
DOI: 10.31399/asm.hb.v03.a0006225
EISBN: 978-1-62708-163-4
.... The article describes the aluminum-silicon eutectic system and the lead-tin eutectic system. It discusses eutectic morphologies in terms of lamellar and fibrous eutectics, regular and irregular eutectics, and the interpretation of eutectic microstructures. The article examines the solidification of a binary...
Abstract
This article begins with a schematic illustration of a eutectic system in which the two components of the system have the same crystal structure. Eutectic systems form when alloying additions cause a lowering of the liquidus lines from both melting points of the pure elements. The article describes the aluminum-silicon eutectic system and the lead-tin eutectic system. It discusses eutectic morphologies in terms of lamellar and fibrous eutectics, regular and irregular eutectics, and the interpretation of eutectic microstructures. The article examines the solidification of a binary alloy of exactly eutectic composition. It concludes with a discussion on terminal solid solutions.
Image
Published: 01 December 2004
Fig. 41 Coupled eutectic zones. (a) Symmetric coupled zone (regular eutectics. (b) Asymmetric coupled zone (irregular eutectics). Source: Ref 1
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in The Liquid State and Principles of Solidification of Cast Iron
> Cast Iron Science and Technology
Published: 31 August 2017
Fig. 24 Coupled eutectic zones. (a) Symmetric coupled zone (regular eutectics). (b) Asymmetric coupled zone (irregular eutectics). Source: Ref 8
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Published: 27 April 2016
coupled zone in an irregular eutectic. In both cases, the widening of the coupled zone near the eutectic temperature is observed only in directional solidification (positive thermal gradient). Source: Ref 6
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Image
Published: 27 April 2016
Fig. 14 Irregular “Chinese script” eutectic consisting of faceted Mg 2 Sn phase (dark) in a magnesium matrix. Etched with glycol. Original magnification: 250×. Source: Ref 6
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Image
Published: 01 December 1998
Fig. 8 Irregular “Chinese script” eutectic consisting of faceted Mg 2 Sn phase (dark) in a magnesium matrix. Etched with glycol. 250×
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Book: Casting
Series: ASM Handbook
Volume: 15
Publisher: ASM International
Published: 01 December 2008
DOI: 10.31399/asm.hb.v15.a0005212
EISBN: 978-1-62708-187-0
... versus irregular eutectic structure : If both phases in the eutectic structure are nonfaceted, the eutectic will exhibit a regular morphology. In this case, the microstructure is made up of either lamellae or fibers that have a high degree of regularity and periodicity. However, if one phase is faceted...
Abstract
This article illustrates the equilibrium phase diagram for an aluminum-silicon system, showing the metastable extensions of liquidus and solidus lines. It describes the classification and microstructure of the aluminum-silicon eutectic. The article presents the theories of solidification and chemical modification of the aluminum-silicon eutectic.
Series: ASM Handbook
Volume: 1A
Publisher: ASM International
Published: 31 August 2017
DOI: 10.31399/asm.hb.v01a.a0006314
EISBN: 978-1-62708-179-5
..., the theory of eutectic growth was developed by Jackson and Hunt (JH theory) in 1966 ( Ref 5 ), but an analytical treatment accounting for the irregular nature of iron-carbon eutectic was not published until 1987 ( Ref 6 ). As for the growth of divorced eutectic, occurring in spheroidal graphite iron...
Abstract
The microstructure that develops during the solidification stage of cast iron largely influences the subsequent solid-state transformations and mechanical properties of the cast components. This article provides a brief introduction of methods that can be used for simulating the solidification microstructure of cast iron. Analytical as well as numerical models describing solidification phenomena at both macroscopic and microscopic scales are presented. The article introduces macroscopic transport equations and presents analytical microscopic models for solidification. These models include the dendrite growth models and the cooperative eutectic growth models. The article provides some solutions using numerical models to simulate the kinetics of microstructure formation in cast iron. It concludes with a discussion on cellular automaton (CA) technique that can handle complex topology changes and reproduce most of the solidification microstructure features observed experimentally.
Book: Casting
Series: ASM Handbook
Volume: 15
Publisher: ASM International
Published: 01 December 2008
DOI: 10.31399/asm.hb.v15.a0005211
EISBN: 978-1-62708-187-0
... approximately 30% ( Fig. 3 ), and the lamellar structure typically occurs when V F of the minor phase is greater than approximately 30% ( Fig. 3 ). The irregular or anomalous eutectic structure forms when one of the solid phases has high entropy of fusion (α > 2) (nonfaceted/faceted-type growth...
Abstract
This article presents the binary eutectic phase diagram to understand the various structures that evolve in a binary eutectic system during solidification. It describes the various classifications and solidification principles of the eutectic structures. The formation of halos in eutectic microstructures of most alloy systems is also discussed.
Image
Published: 01 December 2004
Fig. 40 Eutectic microstructures. (a) Regular nonfaceted/nonfaceted eutectic (Al-Al 2 Cu). (b) Irregular faceted/nonfaceted eutectic (Mg-Mg 2 Sn). The dark phase is the faceted Mg 2 Sn. Ref 22 . (c) Rod faceted/nonfaceted eutectic (Ni-NbC). Ref 23 . (d) Divorced eutectic (Fe-spheroidal
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Series: ASM Handbook
Volume: 9
Publisher: ASM International
Published: 01 December 2004
DOI: 10.31399/asm.hb.v09.a0003724
EISBN: 978-1-62708-177-1
... interface during growth are illustrated. The article also describes the solidification structures of pure metals, solid solutions, eutectics, peritectics, and monotectics. constitutional undercooling curvature undercooling eutectics interface stability kinetic undercooling monotectics nucleation...
Abstract
This article provides information on four different length scales at which surface morphology can be viewed: macro, meso, micro and nanoscale. Elementary thermodynamics demonstrates that a liquid cannot solidify unless some undercooling below the equilibrium (melting) temperature occurs. The article details five types of solidification undercooling, namely, kinetic, thermal, constitutional (solutal), curvature, and pressure undercooling. It explains the types of nucleation which occur in the melt during solidification. The effects of local instabilities at the solid/liquid interface during growth are illustrated. The article also describes the solidification structures of pure metals, solid solutions, eutectics, peritectics, and monotectics.
Series: ASM Handbook
Volume: 1A
Publisher: ASM International
Published: 31 August 2017
DOI: 10.31399/asm.hb.v01a.a0006311
EISBN: 978-1-62708-179-5
... eutectics. If one of the phases is nonfaceted, the morphology becomes irregular, because the faceted phase grows preferentially in a direction determined by specific atomic planes. This is the case of lamellar graphite iron, where austenite is nonfaceted and graphite is faceted. In this case, one solid...
Abstract
Solidification processing is one of the oldest manufacturing processes, because it is the principal component of metal casting processing. This article discusses the fundamentals of solidification of cast iron. Undercooling is a basic condition required for solidification. The article describes various undercooling methods, including kinetic undercooling, thermal undercooling, constitutional undercooling, and pressure undercooling. For solidification to occur, nuclei must form in the liquid. The article discusses the various types of nucleation: homogeneous nucleation, heterogeneous nucleation, and dynamic nucleation. It reviews the classification of eutectics based on their growth mechanism: cooperative growth and divorced growth. The article concludes with a discussion on the solidification structures of peritectics.
Image
in Microstructure Evolution during the Liquid/Solid Transformation in Cast Iron
> Cast Iron Science and Technology
Published: 31 August 2017
Fig. 20 Schematic representation of models for growth mechanisms of various graphite morphologies. (a) Lamellar graphite (LG)/austenite eutectic grain. Source: Ref 79 . (b) Compacted graphite (CG)/austenite eutectic grain. Source: Ref 79 . (c) CG developing out of LG. Source: Ref 80 . (d
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Book Chapter
Book: Alloy Phase Diagrams
Series: ASM Handbook
Volume: 3
Publisher: ASM International
Published: 27 April 2016
DOI: 10.31399/asm.hb.v03.a0006227
EISBN: 978-1-62708-163-4
... for irregular than for regular monotectic composites (with the exception of the aluminum-bismuth alloy) and approximately one order of magnitude higher for regular monotectic composites than for regular eutectics. The differences come from the controlling mechanism. For irregular fibrous eutectics...
Abstract
Monotectic alloys can be classified based on the difference between the critical temperature and the monotectic temperature. This article begins with a schematic illustration of monotectic reaction in copper-lead system. It discusses the solidification structures of monotectics and illustrates the monotectic solidification for low-dome alloys. The forming mechanism of the banded structure of copper-lead alloy in upward directional solidification is also described.
Image
in Metallography and Microstructures of Magnesium and Its Alloys
> Metallography and Microstructures
Published: 01 December 2004
Fig. 12 Microstructures of (a) AM60 and (b) AZ91D high-pressure die cast specimens after etching with acetic-picral. The matrix appears light, with the eutectic phase slightly darker. Areas of interdendritic microporosity due to solidification shrinkage are indicated with arrows. The large
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Image
Published: 01 January 1987
Fig. 1083 Tensile-overload fracture in a specimen of a superplastic eutectic alloy containing 67% Al and 33% Cu. The material was cast, and the as-cast ingot was extruded at 430 °C (805 °F). Testing was performed at 0.025 mm/s (0.001 in./s) and at a controlled temperature of 450 °C (840 °F
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Image
Published: 01 December 2004
Fig. 33 Peritectic transformation of an Sb-14Ni alloy that was slowly cooled to 650 °C (1200 °F) and held 1 h, then cooled to 615 °C (1140 °F) and held 10 min (peritectic temperature: 626 °C, or 1159 °F). An irregular layer of NiSb 2 crystals (dark) is formed around the coarse primary NiSb
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Image
Published: 27 April 2016
Fig. 11 Peritectic transformation of an Sb-14Ni alloy that was slowly cooled to 650 °C (1200 °F) and held 1 h, then cooled to 615 °C (1140 °F) and held 10 min (peritectic temperature: 626 °C, or 1159 °F). An irregular layer of NiSb 2 crystals (dark) is formed around the coarse primary NiSb
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