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peritectic reaction
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Published: 01 March 2012
Fig. 6.2 Typical peritectic phase diagrams. (a) Peritectic reaction α + liquid → β and peritectoid reaction α + β → γ. (b) Peritectic formation of intermetallic phases from a high-melting intermetallic. (c) Peritectic cascade between high- and low-melting components. Adapted from Ref 6.1
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in Solidification, Segregation, and Nonmetallic Inclusions
> Metallography of Steels: Interpretation of Structure and the Effects of Processing
Published: 01 August 2018
Fig. 8.21 (a) Equilibrium phase diagram Fe-C in the region of the peritectic reaction. The dashed line indicates the composition of 0.14% C. The two-phase field without identification in this diagram is δ + γ. (b) Volume change during equilibrium solidification (without segregation) of a steel
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Image
Published: 01 March 2012
Fig. 6.18 Nickel distribution after peritectic reaction in a steel containing 4 wt% Ni. The temperature gradient was 60 K/cm. Calculations were made at different solidification rates. The dotted line shows the nickel distribution at the start of the peritectic reaction. δ, primary ferrite; γ
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Image
Published: 01 March 2012
Fig. 6.20 Three stages of a peritectic reaction in a unidirectionally-solidified high-speed steel. (a) First-stage structure. Dark gray is austenite; white is ferrite. The mottled structure is quenched liquid. (b) Subsequent peritectic transformation of (a). (c) Further peritectic
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Image
Published: 01 March 2012
Fig. 10.24 Three-phase equilibria in a ternary system with a peritectic reaction. Adapted from Ref 10.3
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Published: 01 March 2012
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Published: 01 March 2012
Fig. 6.6 Mechanisms of peritectic reaction and transformation. (a) Lateral growth of a β layer along the α-liquid interface during peritectic reaction by liquid diffusion. (b) Thickening of a β layer by solid-state diffusion during peritectic transformation. The solid arrows indicate growth
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Image
Published: 01 March 2012
Fig. 6.9 Start of the peritectic reaction in a directionally-solidified Cu-20Sn alloy. Primary α dendrites (white) are covered by peritectically-formed β layer (gray) shortly after the temperature reaches T p . Matrix (dark) is a mixture of tin-rich phases. Original magnification: 40
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Published: 01 June 2008
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in Introduction to Solidification and Phase Diagrams[1]
> Titanium: Physical Metallurgy, Processing, and Applications
Published: 01 January 2015
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in Introduction to Solidification and Phase Diagrams[1]
> Titanium: Physical Metallurgy, Processing, and Applications
Published: 01 January 2015
Fig. 2.15 Constitutional diagram with peritectic reaction ( Y is hypoperitectic in composition)
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in Introduction to Solidification and Phase Diagrams[1]
> Titanium: Physical Metallurgy, Processing, and Applications
Published: 01 January 2015
Fig. 2.16 Constitutional diagram with peritectic reaction ( Z is hyperperitectic in composition)
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 March 2012
DOI: 10.31399/asm.tb.pdub.t53420117
EISBN: 978-1-62708-310-2
... structures in iron-base alloys and multicomponent systems. microstructure peritectic systems peritectic transformation SIMILAR TO THE EUTECTIC group of invariant transformations is a group of peritectic reactions, in which a liquid and solid phase decomposes into a new solid phase on cooling...
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Published: 01 March 2012
Fig. 6.19 The transition from a peritectic to a eutectic reaction as a function of chromium and molybdenum content in a stainless steel containing 11.9% Ni. Source: Ref 6.10 as published in Ref 6.4
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Published: 01 August 2005
Fig. 2.34 An alloy microstructure characteristic of a peritectic transformation. The alloy contains four constituents: aluminum, copper, nickel, and silicon. The primary phase is totally surrounded by a rim of a second phase as a result of the peritectic reaction failing to maintain
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Published: 01 April 2004
Fig. 2.38 An alloy microstructure characteristic of a peritectic transformation. The alloy contains four constituents: aluminum, copper, nickel, and silicon. The primary phase is totally surrounded by a rim of a second phase as a result of the peritectic reaction failing to maintain
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 June 2008
DOI: 10.31399/asm.tb.emea.t52240075
EISBN: 978-1-62708-251-8
.... The major eutectic systems include the aluminum-silicon eutectic system and the lead-tin eutectic system. The chapter discusses the construction of eutectic phase diagrams from free energy curves. It also provides information on peritectic, monotectic, and solid-state reactions in alloy systems...
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in Intermetallic Phases in Aluminum-Silicon Technical Cast Alloys
> Aluminum-Silicon Casting Alloys: Atlas of Microstructures
Published: 01 December 2016
Fig. 2.26 (a) Al-Zr equilibrium phase diagram. (b) Zirconium concentration in both liquid and solid solutions at peritectic reaction point (LT). Source: Ref 4 , 50
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Published: 01 December 2008
Fig. 4.6 An example of modifying an erroneous phase diagram ( Exercise 4.3 ). Point 5 (■) indicates a peritectic reaction (γ + L → α), and large supercooling can be caused easily. On the other hand, point 3 ( ⊙ ) indicates a eutectic reaction (L → α +β); it can make progress with small
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in Intermetallic Phases in Aluminum-Silicon Technical Cast Alloys
> Aluminum-Silicon Casting Alloys: Atlas of Microstructures
Published: 01 December 2016
Fig. 2.22 (a) Al-Ti equilibrium phase diagram. HT, high temperature; LT, low temperature. (b) Titanium concentration in both liquid and solid solutions in peritectic reaction point. Source: Ref 45 – 47
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