Ghezri, AdelAdelGhezriPratama, KillangKillangPratamaScholl, Yan VincentYan VincentSchollKüenzi, Alexander MartinAlexander MartinKüenziNelis, ThomasThomasNelisBurger, JürgenJürgenBurgerBessire, CédricCédricBessire2025-02-132025-02-132024-12-12https://doi.org/10.24451/dspace/1136510.3390/jmmp8060289https://arbor.bfh.ch/handle/arbor/44541This study systematically compares the surface polishing performance and finishing results of the following two different electrolytic plasma polishing technologies on stainless steel AISI 316L: (i) plasma electrolytic polishing (PEP) and (ii) plasma electrolytic polishing jet (PEP-Jet). The two techniques are compared against an industrial standard polishing method, electropolishing (EP). For comparable energy density consumption, the samples treated with the PEP-Jet technique showed the highest removal rate, up to three times less than the initial roughness, resulting in the highest surface roughness reduction from Sa = 249 nm to Sa = 81 nm. Microstructure characterization of samples treated using PEP-Jet also showed well-defined crystalline grain boundaries with a distinct appearance of predominantly inter-crystalline structures within individual grains, which is uncommon with EP techniques. The surfaces treated using PEP-Jet exhibited the lowest corrosion rate of 6.79×10−5 mm/year, and no signs of areal corrosion were detected in the performed corrosion tests in contrast with the other samples and their respective treatments. The comparative analysis revealed that the high ionic current delivered by the electrolyte jet flow in the PEP-Jet process effectively stabilizes the plasma at the contact zone, thereby enhancing the plasma polishing of austenitic stainless steel samples. The efficacy of this method has been demonstrated in terms of reducing energy consumption and enhancing corrosion resistance in comparison with (PEP) and (EP) as state-of-the-art processes in corrosive environments of high-alloyed steel.envapor gas layerion drift velocityelectrolyte jet flowenergy consumptioncorrosion resistancesurface finishingarticle