Tailoring absorptivity of highly reflective Ag powders by pulsed-direct current magnetron sputtering for additive manufacturing processes

Wadge, Matthew D.; Lowther, Morgan; Cooper, Timothy P.; Reynolds, William J.; Speidel, Alistair; Carter, Luke N.; Rabbitt, Daisy; Kudrynskyi, Zakhar R.; Felfel, Reda M.; Ahmed, Ifty; Clare, Adam T.; Grant, David M.; Grover, Liam M.; Cox, Sophie C.

doi:10.1016/j.jmatprotec.2023.117985

Tailoring absorptivity of highly reflective Ag powders by pulsed-direct current magnetron sputtering for additive manufacturing processes

Wadge, Matthew D.; Lowther, Morgan; Cooper, Timothy P.; Reynolds, William J.; Speidel, Alistair; Carter, Luke N.; Rabbitt, Daisy; Kudrynskyi, Zakhar R.; Felfel, Reda M.; Ahmed, Ifty; Clare, Adam T.; Grant, David M.; Grover, Liam M.; Cox, Sophie C.

Authors

Matthew D. Wadge

Morgan Lowther

Timothy P. Cooper

William J. Reynolds

Dr ALISTAIR SPEIDEL ALISTAIR.SPEIDEL@NOTTINGHAM.AC.UK
ASSISTANT PROFESSOR IN SUSTAINABLEENGINEERING

Luke N. Carter

Daisy Rabbitt

Zakhar R. Kudrynskyi

Reda M. Felfel

Professor IFTY AHMED ifty.ahmed@nottingham.ac.uk
PROFESSOR OF MATERIALS SCIENCE AND ENGINEERING

Adam T. Clare

Professor DAVID GRANT DAVID.GRANT@NOTTINGHAM.AC.UK
PROFESSOR OF MATERIALS SCIENCE

Liam M. Grover

Sophie C. Cox

Abstract

Processing of highly reflective and high thermally conductive materials (Cu, Ag, etc.) by laser powder bed fusion (LPBF) is of increasing interest to broaden the range of materials that can be additively manufactured. However, these alloys are challenged by high reflectivity resulting in unmelted particles and porosity. This is exacerbated for in-situ alloying techniques, where divergent optical properties of blended powders further narrow the stable processing window. One possible route to improved uniformity of initial melting is through coating powders with an optically absorptive layer. In-situ alloying of Ti-Ag was chosen as a model to assess this, given the potential of Ti-Ag as a novel antimicrobial biomedical alloy, facilitating an ideal model to assess this approach. High purity Ag powder was coated with Ti via physical vapour deposition. Barriers to reliable coating were investigated, with agglomeration of particles observed at a sputtering power of 100 W. In-situ laser micro calorimetry demonstrated a significant improvement in melting performance for coated Ag powder, with continuous tracks attained at 280 W vs. 320 W for uncoated powder, and absorptivity increasing from 27 % to 45 % at 320 W incident laser power. Subsequent in-situ alloying of the Ag powder when blended with commercially pure Ti powder demonstrated that improved absorptivity allowed for more uniform densification of the blended powder bed at lower energy density (0.7 ± 1.0 vs 7.1 ± 2.0 % porosity at 133 J.m-1). Ultimately, this offers a promising route to improved alloy development via LPBF, through application of a homogeneous, relevant coating.

Citation

Wadge, M. D., Lowther, M., Cooper, T. P., Reynolds, W. J., Speidel, A., Carter, L. N., Rabbitt, D., Kudrynskyi, Z. R., Felfel, R. M., Ahmed, I., Clare, A. T., Grant, D. M., Grover, L. M., & Cox, S. C. (2023). Tailoring absorptivity of highly reflective Ag powders by pulsed-direct current magnetron sputtering for additive manufacturing processes. Journal of Materials Processing Technology, 317, Article 117985. https://doi.org/10.1016/j.jmatprotec.2023.117985

Journal Article Type	Article
Acceptance Date	Apr 9, 2023
Online Publication Date	Apr 11, 2023
Publication Date	2023-08
Deposit Date	Apr 17, 2023
Publicly Available Date	Apr 19, 2023
Journal	Journal of Materials Processing Technology
Print ISSN	0924-0136
Publisher	Elsevier
Peer Reviewed	Peer Reviewed
Volume	317
Article Number	117985
DOI	https://doi.org/10.1016/j.jmatprotec.2023.117985
Keywords	Additive manufacturing; Magnetron sputtering; Laser powder bed fusion; Physical vapour deposition
Public URL	https://nottingham-repository.worktribe.com/output/19465471
Publisher URL	https://www.sciencedirect.com/science/article/pii/S0924013623001309?via%3Dihub