Zhao, TongTongZhaoCai, WangcanWangcanCaiDahmen, MariusMariusDahmenSchaible, JonathanJonathanSchaibleHong, ChenChenHongGasser, AndresAndresGasserWeisheit, AndreasAndreasWeisheitBiermann, TimTimBiermannKelbassa, IngomarIngomarKelbassaZhang, HanHanZhangGu, DongdongDongdongGuSchleifenbaum, Johannes HenrichJohannes HenrichSchleifenbaum2022-04-212022-04-212018-10-01Vacuum 158: 121-125 (2018-12-01)http://hdl.handle.net/11420/12308The use of aluminium alloys containing Sc and Zr in additive manufacturing (AM) provides new solutions for lightweight design. Representative thin-wall structured parts were additively fabricated with a commercially available Al-4.55Mg-0.51Mn-0.65Sc-0.30Zr alloy in Laser Metal Deposition (LMD) process. A bi-directional and a uni-directional scan strategy were applied and laser power from 500 W to 600 W was used. Nanohardness tests were conducted on specimens aged at 300 °C for up to 19 h to observe the ageing responses. Fine-grained microstructures with few micro-sized precipitates containing Sc- and Zr were found in the last track of every specimen. The area formed by the track-overlapping was the opposite, but an apparent hardening was observed only after the ageing. AM-processes with local remelting are facing the challenge to exert the potential strengthening effect of aluminium alloys containing Sc. The mushy state must be suppressed to prevent the waste of the expensive rare elements.en0042-207X2018121125Elsevier Sciencehttps://creativecommons.org/licenses/by/4.0/Additive manufacturingAluminium scandium alloysGrain refinementMushy statePrecipitationThermal historyPhysikJournal Article10.15480/882.429510.1016/j.vacuum.2018.09.05210.15480/882.4295Other