TY - JOUR
AU1 - Sajadifar, Seyed Vahid
AU2 - Hosseinzadeh, Ali
AU3 - Richter, Julia
AU4 - Krochmal, Marcel
AU5 - Wegener, Thomas
AU6 - Bolender, Artjom
AU7 - Heidarzadeh, Akbar
AU8 - Niendorf, Thomas
AU9 - Yapici, Guney Guven
AB - IntroductionExcellent corrosion resistance and superior mechanical properties of 316 L stainless steel qualify this alloy for various applications from biomedical to petrochemical industries.[1–4] Due to the addition of molybdenum, the corrosion performance of 316 L stainless steel was found to be even better than that of the 304 L alloy.[5–7] 316 L stainless steel is also characterized by high strain hardening, pointing at good workability, as well as acceptable weldability, broadening the number of potential engineering applications.[8–11] However, the material (especially in the as‐cast condition) suffers from poor yield strength (YS) like numerous austenitic alloys.[12] A promising technology to overcome this strength–ductility trade‐off is additive manufacturing (AM). Among different AM methods, laser‐based powder bed fusion of metals (PBF‐LB/M) combines the fabrication of near‐net‐shape components of complex geometry with excellent mechanical properties.[4,13–16] The PBF‐LB/M process is based on the consecutive consolidation of metallic powders by a laser and the repetitive fusing of thin layers on top of each other.[17–19]For years, the processability and the corresponding mechanical properties of 316 L stainless steel parts fabricated via PBF‐LB/M have been in the focus of investigations.[4,20–22] Most of these research works tried to optimize AM parameters (e.g., laser power, hatch spacing, and building direction) to directly design superior 
TI - On the Friction Stir Processing of Additive‐Manufactured 316L Stainless Steel
JF - Advanced Engineering Materials
DO - 10.1002/adem.202200384
DA - 2022-10-01
UR - https://www.deepdyve.com/lp/wiley/on-the-friction-stir-processing-of-additive-manufactured-316l-07Afrpyyi4
VL - 24
IS - 10
DP - DeepDyve
ER -