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Meeting	MS&T21: Materials Science & Technology
Symposium	Additive Manufacturing of Metals: ICME Gaps: Material Property and Validation Data to Support Certification
Presentation Title	Providing a Rigorous Measurement Foundation for Modeling-Informed Qualification and Certification of Metal AM Components
Author(s)	Lyle E. Levine, Brandon Lane, Thien Phan, Fan Zhang, Mark Stoudt, Brian Simonds, David Deisenroth
On-Site Speaker (Planned)	Lyle E. Levine
Abstract Scope	Additive manufacturing (AM) is a transformative manufacturing technology that provides new capabilities across a wide range of material systems and applications. Metal AM enables customized production of three-dimensional parts with geometries that can be too costly, difficult, or in some cases, impossible to produce using traditional manufacturing processes. In many cases, however, difficulties persist regarding throughput, reproducibility, reliability, and properties of the printed parts. Critical gaps include a lack of alloy-specific and temperature-dependent material property data, model validation data for multi-scale and multi-physics AM simulations, and a rigorous calibration chain for in situ process monitoring and control. NIST is deeply involved in all these measurement issues and I will describe our current and planned work in these crucial areas and how this work fits into the landscape of metal AM qualification and certification.

OTHER PAPERS PLANNED FOR THIS SYMPOSIUM

An Analysis of the Dislocation Density of Inconel 718 Additive Manufacturing Powder

An ICME Approach for Designing Appropriate Heat Treatments in Additively Manufactured Nitrogen Atomized 17-4PH Stainless Steel

Capturing and Analyzing In-situ Data within the Directed Energy Deposition Process with DEDSmart

CFD Modelling for AM Processes

Critical Issues and Gaps in Testing and Characterization Data for Computational Materials in Qualification and Certification of Additively Manufactured Metallic Materials

Determining Data Requirements to Quantify Porosity in the Laser Powder Bed Fusion Process

Enabling Quality Assurance by Completing the Process-Property-Performance Paradigm for Additive Manufacturing

Experimental and Numerical Investigation of Pressureless Sintering for Binder Jetted Metal Parts

High Temperature Material Properties Measurement Capabilities of the NASA MSFC Electrostatic Levitation (ESL) Laboratory

High Temperature Material Property Data and Challenges to Thermal Process Model Predictions and In-Situ/Ex-Situ Measurements for Metallic Additive Manufacturing

ICME Gap Analysis for Materials Design and Process Optimization in Additive Manufacturing

ICME Gaps for Additive Manufacturing of Metals

Laser Energy Coupling during Metal Additive Manufacturing

Lessons Learned from Calibration and Validation of Process Models for Laser Powder Bed Fusion

Methods for Improved Part-scale Thermal Process Simulations in Laser Powder Bed Fusion

On Scan Path Knowledge for Model Informed Process Planning and Material Quality Predictions

Phase Field Informed Monte Carlo Texture Evolution Models for Additive Manufacturing Microstructure Simulation and the Need for Experimental Grain Competition Data

Predicting Melt Properties Using Atomistic Simulations with a Highly Accurate Physically Informed Neural Network Interatomic Potential

Providing a Rigorous Measurement Foundation for Modeling-Informed Qualification and Certification of Metal AM Components

Transferability of Terrestrial Development of Metal Additive to Extraterrestrial Applications

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