Effects of initial microstructure on the grain boundary network during grain boundary engineering in Hastelloy N alloy

Cao, Wu; Xia, Shuang; Bai, Qingshun; Zhang, Wenzhu; Zhou, Bangxin; Li, Zhijun; Jiang, Li

doi:10.1016/j.jallcom.2017.02.009

Cited by 43 publications

(10 citation statements)

References 29 publications

(31 reference statements)

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“…This figure reveals that the alloy rolled at high rolling temperature has large grain sizes after solution treatment. Grain growth is caused by GB migration . However, grain growth is not obvious because the solution temperature is close to the temperature of the three‐phase region.…”

Section: Resultsmentioning

confidence: 99%

“…Grain growth is caused by GB migration. [30] However, grain growth is not obvious because the solution temperature is close to the temperature of the threephase region. A certain amount of α 2 phases exists at the GB and inside the grain, and the pronounced pinning effect of α 2 relative to the GB [31] inhibits the migration of GBs and results in the slow increase in grain size.…”

Section: Effects Of Solution Treatment On Microstructuresmentioning

confidence: 99%

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Microstructure Evolution and Mechanical Properties of a Powder Metallurgy Ti‐22Al‐25Nb Alloy Processed through Isothermal Rolling and Solution and Aging Treatment

et al. 2019

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Isothermal rolling is conducted at 1050 °C (α2 + B2 phase region) and 1100 °C (B2 phase region) for a spark plasma sintering (SPS)‐processed Ti‐22Al‐25Nb alloy. The effects of rolling temperature, pass, reduction per pass, and solution and aging on microstructure evolution, phase transformation, and tensile property at ambient temperature are systematically investigated. The results show that as the alloy is rolled at 1050 °C for 1 pass (P), the optimal tensile strength (TS) and the yield strength (YS) are 964.78 and 935.16 MPa, respectively, and the elongation (δ) reaches 23.65%. Then, followed by a subsequent solution and aging at 940 °C/30 min/water quenching (WQ) + 760 °C/24 h/air cooling (AC), it exhibits a decrease in mechanical properties. Moreover, a mixed fracture mechanism dominated by ductile fracture is shown for the as‐rolled alloy. However, after a solution and aging, it is transformed to a mixed fracture mechanism dominated by brittle fracture, which attributes to the void aggregation and the development of the discontinuous brittle α2 precipitates along B2 matrix grains during the solution and aging treatment. Finally, fracture models of the as‐rolled alloy and the solution and aging‐treated alloy are established.

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Section: Resultsmentioning

confidence: 99%

Section: Effects Of Solution Treatment On Microstructuresmentioning

confidence: 99%

Microstructure Evolution and Mechanical Properties of a Powder Metallurgy Ti‐22Al‐25Nb Alloy Processed through Isothermal Rolling and Solution and Aging Treatment

et al. 2019

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“…22) As a special low-energy boundary, twin boundaries (∑3 n boundaries) occupying a larger area fraction in austenitic stainless steel are active interfaces relative to the regular crystal structure. 23,24) When the multiple twins meet together, ∑3 boundaries can grow up and form between them due to the effect of interface migration. A twin relationship (60°< 111 > ) of {111} < 110 > and {111} < 112 > orientations constitutes twin boundaries, endowed with high migration rate due to low energy, which is beneficial to the nucleation of {111} < 110 > and {111} < 112 > components.…”

Section: Grain Boundarymentioning

confidence: 99%

Roles of Inclusion, Texture and Grain Boundary in Corrosion Resistance of Low-Nickel Austenite Stainless Steel Containing Ce

et al. 2019

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The roles of inclusion, texture and grain boundary in corrosion resistance of low-nickel austenite stainless steel containing Ce was investigated by using SEM, TEM, EBSD, XRD and testing technology of electrochemistry. The results revealed that the variation in corrosion resistance of 205 stainless steels containing Ce was higher than specimen without Ce, which depended on ∑3 n boundaries and Ce modifying inclusion treatment. Ce addition to steels was prone to forming fine and dispersive Ce multi-phase inclusions containing CeAlO 3 , CeS and Ce 2 O 2 S. When addition of Ce was up to 0.016 wt.%, its textures were characterized by pronounced γ-fiber textures comprising {111} < 110 > and {111} < 112 > components, as well as the frequency of ∑3 n boundaries related to {111} < 112 > , {111} < 110 > and {112} < 110 > components was significantly improved, which was in favor of corrosion resistance improvement. While adding 0.023 wt.%Ce element was detrimental to corrosion resistance of stainless steel.

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“…Different ways to achieve a high amount of

normalΣ

3‐GBs have been developed, as have various ways to describe the microstructure, such as by GB character distributions by TJs or by so‐called “twin‐related‐domains” …”

Section: The Selected Annealing Temperatures (Isochronal Annealing) Umentioning

confidence: 99%

Characterization of Special Grain Boundaries and Triple Junctions in Cu_xNi_1‐x Alloys upon Deformation and Annealing

Emeis¹,

Leuthold²,

Spangenberg³

et al. 2019

Adv Eng Mater

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We compare two quantities to describe a microstructure: the length fraction of normalΣ3/normalΣ9‐grain boundaries and the number fraction of normalΣ3‐x‐x/normalΣ3‐normalΣ3‐normalΣ9‐triple junctions using Cu, Ni and four of their alloys in several microstructural states. The fractions of normalΣ3‐grain boundaries show similar tendencies as the respective fractions of normalΣ3‐x‐x‐triple junctions in relation to the grain size upon deformation and annealing. However, the fraction of normalΣ9‐grain boundaries stagnates at certain grain sizes, while there is still a considerable change of normalΣ3‐normalΣ3‐normalΣ9‐triple junctions during grain growth, meaning that the normalΣ3‐normalΣ3‐normalΣ9‐triple junction microstructure is still evolving. To analyze the evolution of the triple junction microstructure, a program, such as pythorient, is necessary.

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Effects of initial microstructure on the grain boundary network during grain boundary engineering in Hastelloy N alloy

Cited by 43 publications

References 29 publications

Microstructure Evolution and Mechanical Properties of a Powder Metallurgy Ti‐22Al‐25Nb Alloy Processed through Isothermal Rolling and Solution and Aging Treatment

Microstructure Evolution and Mechanical Properties of a Powder Metallurgy Ti‐22Al‐25Nb Alloy Processed through Isothermal Rolling and Solution and Aging Treatment

Roles of Inclusion, Texture and Grain Boundary in Corrosion Resistance of Low-Nickel Austenite Stainless Steel Containing Ce

Characterization of Special Grain Boundaries and Triple Junctions in Cu_xNi_1‐x Alloys upon Deformation and Annealing

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Effects of initial microstructure on the grain boundary network during grain boundary engineering in Hastelloy N alloy

Cited by 43 publications

References 29 publications

Microstructure Evolution and Mechanical Properties of a Powder Metallurgy Ti‐22Al‐25Nb Alloy Processed through Isothermal Rolling and Solution and Aging Treatment

Microstructure Evolution and Mechanical Properties of a Powder Metallurgy Ti‐22Al‐25Nb Alloy Processed through Isothermal Rolling and Solution and Aging Treatment

Roles of Inclusion, Texture and Grain Boundary in Corrosion Resistance of Low-Nickel Austenite Stainless Steel Containing Ce

Characterization of Special Grain Boundaries and Triple Junctions in CuxNi1‐x Alloys upon Deformation and Annealing

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Characterization of Special Grain Boundaries and Triple Junctions in Cu_xNi_1‐x Alloys upon Deformation and Annealing