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Main Authors: Tertuliano, Ottman A., DePond, Philip J., Lee, Andrew C., Hong, Jiho, Doan, David, Capaldi, Luc, Brongersma, Mark, Gu, X. Wendy, Matthews, Manyalibo J., Cai, Wei, Lew, Adrian J.
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.05174
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author Tertuliano, Ottman A.
DePond, Philip J.
Lee, Andrew C.
Hong, Jiho
Doan, David
Capaldi, Luc
Brongersma, Mark
Gu, X. Wendy
Matthews, Manyalibo J.
Cai, Wei
Lew, Adrian J.
author_facet Tertuliano, Ottman A.
DePond, Philip J.
Lee, Andrew C.
Hong, Jiho
Doan, David
Capaldi, Luc
Brongersma, Mark
Gu, X. Wendy
Matthews, Manyalibo J.
Cai, Wei
Lew, Adrian J.
contents The widespread application of metal additive manufacturing (AM) is limited by the ability to control the complex interactions between the energy source and the feedstock material. Here we develop a generalizable process to introduce nanoscale grooves to the surface of metal powders which increases the powder absorptivity by up to 70% during laser powder bed fusion. Absorptivity enhancements in copper, copper-silver, and tungsten enables energy efficient manufacturing, with printing of pure copper at relative densities up to 92% using laser energy densities as low as 82 J/mm^3. Simulations show the enhanced powder absorptivity results from plasmon-enabled light concentration in nanoscale grooves combined with multiple scattering events. The approach taken here demonstrates a general method to enhance the absorptivity and printability of reflective and refractory metal powders by changing the surface morphology of the feedstock without altering its composition.
format Preprint
id arxiv_https___arxiv_org_abs_2312_05174
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle High Absorptivity Nanotextured Powders for Additive Manufacturing
Tertuliano, Ottman A.
DePond, Philip J.
Lee, Andrew C.
Hong, Jiho
Doan, David
Capaldi, Luc
Brongersma, Mark
Gu, X. Wendy
Matthews, Manyalibo J.
Cai, Wei
Lew, Adrian J.
Optics
Materials Science
The widespread application of metal additive manufacturing (AM) is limited by the ability to control the complex interactions between the energy source and the feedstock material. Here we develop a generalizable process to introduce nanoscale grooves to the surface of metal powders which increases the powder absorptivity by up to 70% during laser powder bed fusion. Absorptivity enhancements in copper, copper-silver, and tungsten enables energy efficient manufacturing, with printing of pure copper at relative densities up to 92% using laser energy densities as low as 82 J/mm^3. Simulations show the enhanced powder absorptivity results from plasmon-enabled light concentration in nanoscale grooves combined with multiple scattering events. The approach taken here demonstrates a general method to enhance the absorptivity and printability of reflective and refractory metal powders by changing the surface morphology of the feedstock without altering its composition.
title High Absorptivity Nanotextured Powders for Additive Manufacturing
topic Optics
Materials Science
url https://arxiv.org/abs/2312.05174