Your search keyword '"Nelson Weker, Johanna"' showing total 3 results

1. Melt-Pool Dynamics and Microstructure of Mg Alloy WE43 under Laser Powder Bed Fusion Additive Manufacturing Conditions.

Author

Soderlind, Julie, Martin, Aiden A., Calta, Nicholas P., DePond, Philip J., Wang, Jenny, Vrancken, Bey, Schäublin, Robin E., Basu, Indranil, Thampy, Vivek, Fong, Anthony Y., Kiss, Andrew M., Berry, Joel M., Perron, Aurélien, Nelson Weker, Johanna, Stone, Kevin H., Tassone, Christopher J., Toney, Michael F., Van Buuren, Anthony, Löffler, Jörg F., and Risbud, Subhash H.

Subjects

BONE mechanics, BIOABSORBABLE implants, MICROSTRUCTURE, X-ray imaging, MICROSCOPY, MAGNESIUM alloys

Abstract

Magnesium-based alloy WE43 is a state-of-the-art bioresorbable metallic implant material. There is a need for implants with both complex geometries to match the mechanical properties of bone and refined microstructure for controlled resorption. Additive manufacturing (AM) using laser powder bed fusion (LPBF) presents a viable fabrication method for implant applications, as it offers near-net-shape geometrical control, allows for geometry customization based on an individual patient, and fast cooling rates to achieve a refined microstructure. In this study, the laser–alloy interaction is investigated over a range of LPBF-relevant processing conditions to reveal melt-pool dynamics, pore formation, and the microstructure of laser-melted WE43. In situ X-ray imaging reveals distinct laser-induced vapor depression morphology regimes, with minimal pore formation at laser-scan speeds greater than 500 mm/s. Optical and electron microscopy of cross-sectioned laser tracks reveal three distinct microstructural regimes that can be controlled by adjusting laser-scan parameters: columnar, dendritic, and banded microstructures. These regimes are consistent with those predicted by the analytic solidification theory for conduction-mode welding, but not for keyhole-mode tracks. The results provide insight into the fundamental laser–material interactions of the WE43 alloy under AM-processing conditions and are critical for the successful implementation of LPBF-produced WE43 parts in biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2022

2. Laser‐Induced Keyhole Defect Dynamics during Metal Additive Manufacturing.

Author

Kiss, Andrew M., Fong, Anthony Y., Calta, Nicholas P., Thampy, Vivek, Martin, Aiden A., Depond, Philip J., Wang, Jenny, Matthews, Manyalibo J., Ott, Ryan T., Tassone, Christopher J., Stone, Kevin H., Kramer, Matthew J., van Buuren, Anthony, Toney, Michael F., and Nelson Weker, Johanna

Subjects

MANUFACTURING processes, X-ray imaging, CONFIDENCE intervals, METALS

Abstract

Laser powder bed fusion (LPBF) metal additive manufacturing provides distinct advantages for aerospace and biomedical applications. However, widespread industrial adoption is limited by a lack of confidence in part properties driven by an incomplete understanding of how unique process parameters relate to defect formation and ultimately mechanical properties. To address that gap, high‐speed X‐ray imaging is used to probe subsurface melt pool dynamics and void‐formation mechanisms inaccessible to other monitoring approaches. This technique directly observes the depth and dynamic behavior of the vapor depression, also known as the keyhole depression, which is formed by recoil pressure from laser‐driven metal vaporization. Also, vapor bubble formation and motion due to melt pool currents is observed, including instances of bubbles splitting before solidification into clusters of smaller voids while the material rapidly cools. Other phenomena include bubbles being formed from and then recaptured by the vapor depression, leaving no voids in the final part. Such events complicate attempts to identify defect formation using surface‐sensitive process‐monitoring tools. Finally, once the void defects form, they cannot be repaired by simple laser scans, without introducing new defects, thus emphasizing the importance of understanding processing parameters to develop robust defect‐mitigation strategies based on experimentally validated models. [ABSTRACT FROM AUTHOR]

Published

2019

3. Cooling dynamics of two titanium alloys during laser powder bed fusion probed with in situ X-ray imaging and diffraction.

Author

Calta, Nicholas P., Thampy, Vivek, Lee, Duncan R.C., Martin, Aiden A., Ganeriwala, Rishi, Wang, Jenny, Depond, Philip J., Roehling, Tien T., Fong, Anthony Y., Kiss, Andrew M., Tassone, Christopher J., Stone, Kevin H., Nelson Weker, Johanna, Toney, Michael F., Van Buuren, Anthony W., and Matthews, Manyalibo J.

Subjects

*X-ray imaging, *X-ray diffraction, *TITANIUM alloys, *FLUID dynamics, *LASER welding, *LASERS

Abstract

Metal parts produced by laser powder bed fusion (LPBF) additive manufacturing exhibit characteristic microstructures comparable to those observed in laser welding. The primary cause of this characteristic microstructure is rapid, localized heating and cooling cycles, which result in extreme thermal gradients where material solidification is followed by fast cooling in the solid state. The final microstructure and mechanical performance are also influenced by pore formation caused by melt pool fluid dynamics. Here, we use high speed, in situ X-ray diffraction to probe the kinetics of cooling and solid-solid phase transitions after laser melting in two aerospace titanium alloys: Ti-6Al-4V, an α + β alloy; and Ti-5Al-5V-5Mo-3Cr, a near-β alloy. We complement these diffraction studies with in situ X-ray imaging to probe melt pool dynamics and pore formation. From these two complementary probes, we quantify pore formation during melting and the subsequent microstructural evolution as the material rapidly cools after solidification. These results are critical for understanding defect formation and residual stress development in different titanium alloys under LPBF conditions and can help inform process models to predict final part performance. Unlabelled Image • Direct comparison of materials dynamics in two titanium alloys using in situ X-ray imaging and diffraction during additive manufacturing. • High speed X-ray imaging quantifies fluid dynamics and pore formation during laser melting for both alloys. • In situ X-ray diffraction quantifies cooling rates and residual stress evolution after solidification. • Comparison to thermomechanical modeling provides mechanistic insight into behavior observed by X-ray diffraction. [ABSTRACT FROM AUTHOR]

Published

2020