Formation of lamellar microstructure in Ti-48Al-7Nb-2.5V-1Cr alloy

Yonghao Yu; Hongchao Kou; William Yi Wang; Yichao Wang; Fengming Qiang; Chengxiong Zou; Jinshan Li

doi:10.1016/j.matdes.2022.111342

Formation of lamellar microstructure in Ti-48Al-7Nb-2.5V-1Cr alloy

Yonghao Yu, Hongchao Kou, William Yi Wang, Yichao Wang, Fengming Qiang, Chengxiong Zou, Jinshan Li

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

The reasonable design and application of phase transformation is an efficient approach to coordinate the microstructure and properties of alloys. The sequence of compositional and structural transformation determines the type and mechanism of phase transformation. Because of their low density and excellent high-temperature properties, TiAl alloys that contain fully lamellar microstructure have been applied to low-pressure turbine engine blades. However, there is no consensus on the mechanism of lamellar formation. Here, we propose a new mechanism that is dominated by spinodal decomposition, in which compositional transformation occurs prior to structural transformation during lamellar formation. Transitional lamellae with fcc-based long-period superstructures are introduced to prove the mechanism of sequentially spinodal decomposition, shear transformation, compositional modulation and ordering.

Original language	English
Article number	111342
Journal	Materials and Design
Volume	224
DOIs	https://doi.org/10.1016/j.matdes.2022.111342
State	Published - Dec 2022

Keywords

Compositional modulation
Lamellar microstructure
Long-period superstructure
Spinodal decomposition
TiAl alloy

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10.1016/j.matdes.2022.111342

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title = "Formation of lamellar microstructure in Ti-48Al-7Nb-2.5V-1Cr alloy",

abstract = "The reasonable design and application of phase transformation is an efficient approach to coordinate the microstructure and properties of alloys. The sequence of compositional and structural transformation determines the type and mechanism of phase transformation. Because of their low density and excellent high-temperature properties, TiAl alloys that contain fully lamellar microstructure have been applied to low-pressure turbine engine blades. However, there is no consensus on the mechanism of lamellar formation. Here, we propose a new mechanism that is dominated by spinodal decomposition, in which compositional transformation occurs prior to structural transformation during lamellar formation. Transitional lamellae with fcc-based long-period superstructures are introduced to prove the mechanism of sequentially spinodal decomposition, shear transformation, compositional modulation and ordering.",

keywords = "Compositional modulation, Lamellar microstructure, Long-period superstructure, Spinodal decomposition, TiAl alloy",

author = "Yonghao Yu and Hongchao Kou and {Yi Wang}, William and Yichao Wang and Fengming Qiang and Chengxiong Zou and Jinshan Li",

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doi = "10.1016/j.matdes.2022.111342",

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TY - JOUR

T1 - Formation of lamellar microstructure in Ti-48Al-7Nb-2.5V-1Cr alloy

AU - Yu, Yonghao

AU - Kou, Hongchao

AU - Yi Wang, William

AU - Wang, Yichao

AU - Qiang, Fengming

AU - Zou, Chengxiong

AU - Li, Jinshan

PY - 2022/12

Y1 - 2022/12

N2 - The reasonable design and application of phase transformation is an efficient approach to coordinate the microstructure and properties of alloys. The sequence of compositional and structural transformation determines the type and mechanism of phase transformation. Because of their low density and excellent high-temperature properties, TiAl alloys that contain fully lamellar microstructure have been applied to low-pressure turbine engine blades. However, there is no consensus on the mechanism of lamellar formation. Here, we propose a new mechanism that is dominated by spinodal decomposition, in which compositional transformation occurs prior to structural transformation during lamellar formation. Transitional lamellae with fcc-based long-period superstructures are introduced to prove the mechanism of sequentially spinodal decomposition, shear transformation, compositional modulation and ordering.

AB - The reasonable design and application of phase transformation is an efficient approach to coordinate the microstructure and properties of alloys. The sequence of compositional and structural transformation determines the type and mechanism of phase transformation. Because of their low density and excellent high-temperature properties, TiAl alloys that contain fully lamellar microstructure have been applied to low-pressure turbine engine blades. However, there is no consensus on the mechanism of lamellar formation. Here, we propose a new mechanism that is dominated by spinodal decomposition, in which compositional transformation occurs prior to structural transformation during lamellar formation. Transitional lamellae with fcc-based long-period superstructures are introduced to prove the mechanism of sequentially spinodal decomposition, shear transformation, compositional modulation and ordering.

KW - Compositional modulation

KW - Lamellar microstructure

KW - Long-period superstructure

KW - Spinodal decomposition

KW - TiAl alloy

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U2 - 10.1016/j.matdes.2022.111342

DO - 10.1016/j.matdes.2022.111342

M3 - 文章

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SN - 0264-1275

VL - 224

JO - Materials and Design

JF - Materials and Design

M1 - 111342

ER -

Formation of lamellar microstructure in Ti-48Al-7Nb-2.5V-1Cr alloy

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