Multi-scale microstructural investigation of a laser 3D printed Ni-based superalloy

Yao Li; Kai Chen; R. Lakshmi Narayan; Upadrasta Ramamurty; Yudong Wang; Juncheng Long; Nobumichi Tamura; Xin Zhou

doi:10.1016/j.addma.2020.101220

Multi-scale microstructural investigation of a laser 3D printed Ni-based superalloy

Yao Li
, Kai Chen
, R. Lakshmi Narayan
, Upadrasta Ramamurty
, Yudong Wang
, Juncheng Long
, Nobumichi Tamura
, Xin Zhou

School of Materials Science and Engineering

Chang'an University
Xi'an Jiaotong University
Indian Institute of Technology Delhi
Nanyang Technological University
LBL
Air Force Engineering University Xian

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

69 Scopus citations

Abstract

The heterogeneous microstructure of a laser 3D printed Ni-based superalloy was examined at multiple length scales. The sub-millimeter-sized columnar crystal grains are composed of micron-sized cellular colonies. The crystal grains grow in epitaxy with the substrate under the large temperature gradient and high cooling rate. The cell boundaries, decorated with γ/γ′ eutectics, μ-phase precipitates and high density of dislocations, show enrichment of γ′ forming elements and low-angle misorientations. Dislocations trapped in the intra-cellular regions are characterized as statistically stored dislocations with no detectable contribution to lattice curvature, and are the results of the interaction between dislocations and γ′ precipitates.

Original language	English
Article number	101220
Journal	Additive Manufacturing
Volume	34
DOIs	https://doi.org/10.1016/j.addma.2020.101220
State	Published - Aug 2020

Keywords

Cellular structures
Directed energy deposition
Multi-scale microstructures
Ni-based superalloys
Non-uniform dislocation distribution

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10.1016/j.addma.2020.101220

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title = "Multi-scale microstructural investigation of a laser 3D printed Ni-based superalloy",

abstract = "The heterogeneous microstructure of a laser 3D printed Ni-based superalloy was examined at multiple length scales. The sub-millimeter-sized columnar crystal grains are composed of micron-sized cellular colonies. The crystal grains grow in epitaxy with the substrate under the large temperature gradient and high cooling rate. The cell boundaries, decorated with γ/γ′ eutectics, μ-phase precipitates and high density of dislocations, show enrichment of γ′ forming elements and low-angle misorientations. Dislocations trapped in the intra-cellular regions are characterized as statistically stored dislocations with no detectable contribution to lattice curvature, and are the results of the interaction between dislocations and γ′ precipitates.",

keywords = "Cellular structures, Directed energy deposition, Multi-scale microstructures, Ni-based superalloys, Non-uniform dislocation distribution",

author = "Yao Li and Kai Chen and Narayan, \{R. Lakshmi\} and Upadrasta Ramamurty and Yudong Wang and Juncheng Long and Nobumichi Tamura and Xin Zhou",

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year = "2020",

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doi = "10.1016/j.addma.2020.101220",

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AU - Li, Yao

AU - Chen, Kai

AU - Narayan, R. Lakshmi

AU - Ramamurty, Upadrasta

AU - Wang, Yudong

AU - Long, Juncheng

AU - Tamura, Nobumichi

AU - Zhou, Xin

PY - 2020/8

Y1 - 2020/8

N2 - The heterogeneous microstructure of a laser 3D printed Ni-based superalloy was examined at multiple length scales. The sub-millimeter-sized columnar crystal grains are composed of micron-sized cellular colonies. The crystal grains grow in epitaxy with the substrate under the large temperature gradient and high cooling rate. The cell boundaries, decorated with γ/γ′ eutectics, μ-phase precipitates and high density of dislocations, show enrichment of γ′ forming elements and low-angle misorientations. Dislocations trapped in the intra-cellular regions are characterized as statistically stored dislocations with no detectable contribution to lattice curvature, and are the results of the interaction between dislocations and γ′ precipitates.

AB - The heterogeneous microstructure of a laser 3D printed Ni-based superalloy was examined at multiple length scales. The sub-millimeter-sized columnar crystal grains are composed of micron-sized cellular colonies. The crystal grains grow in epitaxy with the substrate under the large temperature gradient and high cooling rate. The cell boundaries, decorated with γ/γ′ eutectics, μ-phase precipitates and high density of dislocations, show enrichment of γ′ forming elements and low-angle misorientations. Dislocations trapped in the intra-cellular regions are characterized as statistically stored dislocations with no detectable contribution to lattice curvature, and are the results of the interaction between dislocations and γ′ precipitates.

KW - Cellular structures

KW - Directed energy deposition

KW - Multi-scale microstructures

KW - Ni-based superalloys

KW - Non-uniform dislocation distribution

UR - https://www.scopus.com/pages/publications/85084184957

U2 - 10.1016/j.addma.2020.101220

DO - 10.1016/j.addma.2020.101220

M3 - 文章

AN - SCOPUS:85084184957

SN - 2214-8604

VL - 34

JO - Additive Manufacturing

JF - Additive Manufacturing

M1 - 101220

ER -

Multi-scale microstructural investigation of a laser 3D printed Ni-based superalloy

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Keywords

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