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Multiscale microstructure modelling for nickel based superalloys
H.C. Basoalto
, J.W. Brooks
, I. Di Martino
Metallurgy and Materials
Research output
:
Contribution to journal
›
Article
›
peer-review
13
Citations (Scopus)
Overview
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Dive into the research topics of 'Multiscale microstructure modelling for nickel based superalloys'. Together they form a unique fingerprint.
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Keyphrases
Microstructure
100%
Nickel-based Superalloy
100%
Hot Forming
100%
Microstructure Modeling
100%
Bimodal Microstructure
100%
Mechanical Properties
50%
Recrystallization
50%
Heat Treatment
50%
Processing Route
50%
Neural Network
50%
Microstructural Evolution
50%
Forming Operations
50%
Deformation Characteristics
50%
Modeling Approach
50%
Grain Size Distribution
50%
Heat Processing
50%
New Physics
50%
Creep Forming
50%
Superalloy
50%
Alloy 718
50%
Micro-macro
50%
High Temperature Deformation
50%
CMSX-4
50%
Deformation Model
50%
Temperature Evolution
50%
Multiphysics
50%
Forming Behavior
50%
Property Prediction
50%
High Temperature Applications
50%
Polycrystalline Superalloy
50%
Macroscopic Response
50%
Multiscale Modeling Approach
50%
Damage Mechanics
50%
Engineering
Multiscale
100%
Hot Working
100%
Microscale
50%
Polycrystalline
50%
Heat Treatment
50%
Creep
50%
Deformation Characteristic
50%
Microstructural Evolution
50%
Special Attention
50%
Deformation Model
50%
Macroscale
50%
Multiscale Modeling
50%
High Temperature Applications
50%
Damage Mechanic Approach
50%
Material Science
Nickel-Based Superalloys
100%
Superalloys
100%
Microstructure Modeling
100%
Creep
50%
Heat Treatment
50%
Grain Size
50%
Microstructural Evolution
50%
Damage Mechanics
50%