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lamellar eutectics
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Published: 01 December 2004
Fig. 44 Colony structure of a directionally solidified lamellar eutectic. Etchant not reported. Magnification: 200×. Source: Ref 24
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Image
Published: 01 December 2004
Fig. 46 Directionally solidified CuAl 2 -Al lamellar eutectic. As-polished. Magnification: 180×. Source: Ref 24
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Image
Published: 27 April 2016
Image
Published: 27 April 2016
Fig. 10 Example of a lamellar eutectic microstructure (Al-Al 2 Cu) with approximately equal volume fractions of the phases. Transverse section of a directionally solidified (DS) sample. As-polished. Source: Ref 6
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Image
in Computational Models for Prediction of Solidification Microstructure
> Cast Iron Science and Technology
Published: 31 August 2017
Fig. 2 Schematic representation of a lamellar eutectic microstructure showing alternating lamellae of α and β phases, the lamellar spacing λ, and the contact angles θ α and θ β at the triple-point junction. The vector V represents the growth velocity. Source: Ref 23
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Image
in Microstructure Evolution during the Liquid/Solid Transformation in Cast Iron
> Cast Iron Science and Technology
Published: 31 August 2017
Fig. 43 Schematic representation of growth of ledeburite eutectic. (a) Lamellar eutectic with cementite as the leading phase in the edgewise a -direction. Reprinted with permission from Jernkontoret—The Swedish Steel Producers’ Association. Source: Ref 116 . (b) Rodlike eutectic
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Image
Published: 01 December 2008
Fig. 31 Schematic illustrating growth of ledeburite (austenite-iron carbide) eutectic. (a) Lamellar eutectic with cementite as the leading phase in the edgewise, a , direction. (b) Rodlike eutectic in the sidewise, c , direction. Source: Ref 42
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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.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. 21 Cast zinc with 0.6% Cu and 0.14% Ti. Eutectic (zinc and titanium-zinc phases) at grain boundaries. Both etched in etchant 1, Table 1 . (a) 100×. (b) Showing the lamellar eutectic. Coarse needles of titanium-zinc phase are parallel to the polishing plane; fine needles, perpendicular
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Image
Published: 01 December 2004
solution in fine lamellar eutectic. The fine structure imparts toughness and high strength to the alloy. Compare with Fig. 14 and 15 As-polished. Etchant 2, Table 1 . 250×
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Image
Published: 01 December 2004
Fig. 45 Colony structure of a non-directionally solidified CuAl 2 -Al lamellar eutectic. As-polished. Magnification: 250×. Source: Ref 24
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Image
Published: 01 December 2004
Fig. 23 Sn-50Pb alloy. Dendrites of lead-rich solid solution (dark) in a matrix of fine lamellar eutectic consisting of lead-rich solid solution (dark) and tin (light). Etchant 7, Table 1 . 150×
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Image
Published: 01 December 2004
Fig. 12 Plumber's wiping solder (Pb-40Sn), slowly solidified. Dark dendritic grains of lead-rich solid solution in a lamellar eutectic matrix of tin-rich solid solution (white) and lead-rich solid solution (dark). 1 part acetic acid, 1 part HNO 3 , 8 parts glyercol. Original magnification 400×
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Image
Published: 01 December 2004
Fig. 13 Half-and-half solder (Pb-50Sn), slowly solidified. Dark dendritic grains of lead-rich solid solution in lamellar eutectic matrix of tin-rich solid solution (white) and lead-rich solid solution (dark). 1 part acetic acid, 1 part HNO 3 , 8 parts glyercol. Original magnification 400×
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Image
Published: 01 December 2004
Fig. 16 Silver-lead solder (Pb-1Sn-1.5Ag), as-solidified. Light dendritic grains of lead-rich solid solution in lamellar eutectic matrix of lead-rich solid solution (light) and Ag 3 Sn intermetallic phase (dark). 1 part acetic acid, 1 part HNO 3 , 8 parts glycerol. Original magnification 400×
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Series: ASM Handbook
Volume: 1A
Publisher: ASM International
Published: 31 August 2017
DOI: 10.31399/asm.hb.v01a.a0006304
EISBN: 978-1-62708-179-5
... with a discussion on the nucleation and growth of austenite dendrites. It describes the nucleation of lamellar graphite, spheroidal graphite, and austenite-iron carbide eutectic. The article reviews three main graphite morphologies crystallizing from the iron melts during solidification: lamellar (LG), compacted...
Abstract
The solidification of hypoeutectic cast iron starts with the nucleation and growth of austenite dendrites, while that of hypereutectic iron starts with the crystallization of primary graphite in the stable system or cementite in the metastable system. This article begins with a discussion on the nucleation and growth of austenite dendrites. It describes the nucleation of lamellar graphite, spheroidal graphite, and austenite-iron carbide eutectic. The article reviews three main graphite morphologies crystallizing from the iron melts during solidification: lamellar (LG), compacted or vermicular (CG), and spheroidal. It discusses the metastable solidification of austenite-iron carbide eutectic and concludes with information on gray-to-white structural transition of cast iron.
Image
Published: 01 December 2004
Fig. 25 Sn-31Pb-18Cd alloy. Structure is a lamellar ternary eutectic of solid solutions of cadmium in tin (light), tin in lead (gray), and cadmium in lead (dark). Etchant 7, Table 1 . 375×
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Image
in The Liquid State and Principles of Solidification of Cast Iron
> Cast Iron Science and Technology
Published: 31 August 2017
Fig. 5 Room-temperature eutectic grain structure in lamellar graphite iron. Original magnification: 14×. Source: Ref 10
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Image
in Microstructure Evolution during the Liquid/Solid Transformation in Cast Iron
> Cast Iron Science and Technology
Published: 31 August 2017
Fig. 32 Solidification of the eutectic in lamellar graphite iron during continuous cooling (different gray shades indicate different crystallographic orientations). (a) Eutectic iron, early solidification. (b) Eutectic iron, late solidification. (c) Hypoeutectic iron or eutectic iron at high
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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
... . In Fig. 3 , the regular or normal eutectic structure, such as the rodlike and the lamellar, will form when the two phases have low entropies of fusion (α < 2) (nonfaceted/nonfaceted-type growth). The rodlike structure typically occurs when the volume fraction, V F , of the minor phase is less than...
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.
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