Nature Communications (Feb 2024)

Pore evolution mechanisms during directed energy deposition additive manufacturing

  • Kai Zhang,
  • Yunhui Chen,
  • Sebastian Marussi,
  • Xianqiang Fan,
  • Maureen Fitzpatrick,
  • Shishira Bhagavath,
  • Marta Majkut,
  • Bratislav Lukic,
  • Kudakwashe Jakata,
  • Alexander Rack,
  • Martyn A. Jones,
  • Junji Shinjo,
  • Chinnapat Panwisawas,
  • Chu Lun Alex Leung,
  • Peter D. Lee

DOI
https://doi.org/10.1038/s41467-024-45913-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 14

Abstract

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Abstract Porosity in directed energy deposition (DED) deteriorates mechanical performances of components, limiting safety-critical applications. However, how pores arise and evolve in DED remains unclear. Here, we reveal pore evolution mechanisms during DED using in situ X-ray imaging and multi-physics modelling. We quantify five mechanisms contributing to pore formation, migration, pushing, growth, removal and entrapment: (i) bubbles from gas atomised powder enter the melt pool, and then migrate circularly or laterally; (ii) small bubbles can escape from the pool surface, or coalesce into larger bubbles, or be entrapped by solidification fronts; (iii) larger coalesced bubbles can remain in the pool for long periods, pushed by the solid/liquid interface; (iv) Marangoni surface shear flow overcomes buoyancy, keeping larger bubbles from popping out; and (v) once large bubbles reach critical sizes they escape from the pool surface or are trapped in DED tracks. These mechanisms can guide the development of pore minimisation strategies.