Additive manufacturing linked to Additive manufacturing, with source literature and related extracted records kept visible.
74%
Confidence
13
Literature sources
28
Linked simulants
204
Linked properties
Measurement type
Additive manufacturing
Application
Additive manufacturing
Primary source
Selective laser melting of partially amorphous regolith analog for ISRU lunar applications
Review state
needs review
Selective laser melting of partially amorphous regolith analog for ISRU lunar applications Julien Granier a, b, *, Thierry Cutard a, Patrick Pinet b, Yannick Le Maoult a, Serge Chevrel b, Th...
EXPERIMENTS GRIEMSMANN T 1 Introduction 2 Materials and Methods 2.1 The Einstein-Elevator 2.2 Boundary conditions of the EE relevant to the PBF-LB setup 2.3 Used regolith simulant 2.4 Optical prope...
microgravity 3.1. Einstein-Elevator and experimental setup 3.2. Experimental methods 3.3. Experimental results 4. Initial steps to realize PBF-LB with lunar regolith 5. Overall conclusion and outlo...
ts of different laser scanning strategies on the morphology, microstructure, and mechanical properties of lunar regolith simulant formed by laser powder bed fusion Additive Manufacturing Frontiers...
S2095-2686(25)00200-9 Towards sustainable lunar habitats with ISRU in Chang E mission: Mechanical energy evolution and damage mechanisms of LPBF-printed lunar regolith simulate International Journa...
0.1016/j.conbuildmat.2023.132051 1-s2.0-S0950061823017658 10.1016/j.conbuildmat.2023.132051 S0950-0618(23)01765-8 Additive manufacturing by laser powder bed fusion and thermal post-treatment of the...
:10.1016/j.procir.2024.08.131 1-s2.0-S2212827124004852 10.1016/j.procir.2024.08.131 S2212-8271(24)00485-2 Numerical simulation approach for Laser Melting of lunar regolith using an enthalpy-based m...
the Moon is the lunar regolith. A promising method to create construction materials from lunar regolith is powder bed fusion by laser beam (PBF-LB), which uses a guided laser beam to melt lunar reg...
L. Overmeyer, M. Raupert, M. Pusch, T. Griemsmann, A. Katterfeld, C. Lotz | 2025 | CIRP Annals
DOI 10.1016/j.cirp.2025.03.031F. Dang, J. Zhu, M. Ke, Z. Wang, S. Wen, Y. Zhou, C. Zhou, L. Ding | 2026 | Additive Manufacturing Frontiers
DOI 10.1016/j.amf.2025.200283S. Li, X. Li, Y. Gao, B. Zhou, Y. Zhou, J. Song, C. Zhou, W. Yao, L. Ding | 2026 | International Journal of Mining Science and Technology
DOI 10.1016/j.ijmst.2025.11.003R. Wang, G. Qiao, G. Song | 2023 | Construction and Building Materials
DOI 10.1016/j.conbuildmat.2023.132051J. Keuntje, T. Griemsmann, J. Patzwald, R. Staehr, P. Jaeschke, E. Stoll, S. Kaierle, L. Overmeyer | 2024 | Procedia CIRP
DOI 10.1016/j.procir.2024.08.131H. Fisher, J. Patzwald, T. Griemsmann, L. Overmeyer, E. Stoll | 2026 | Advances in Space Research
DOI 10.1016/j.asr.2026.05.036Y. Liu, X. Zhang, X. Chen, C. Wang, Y. Yu, Y. Jia, W. Yao | 2024 | Crystals
DOI 10.3390/cryst14121022W. Han, L. Ding, C. Zhou, Y. Zhou, F. Dang | 2024 | Science China Technological Sciences
DOI 10.1007/s11431-023-2675-0L. Windisch, S. Linke, M. Jütte, J. Baasch, A. Kwade, E. Stoll, C. Schilde | 2022 | Materials
DOI 10.3390/ma15238561S. Basel, C. Safety, C. Engineering | 2025 | Buildings
DOI 10.3390/buildings15142543W. Sun, F. Dang, L. Ding | 2025 | Additive Manufacturing Frontiers
DOI 10.1016/j.amf.2025.20022574%
13 sources