Light Impact Deformation to Create a Near-Surface Nano- and Microstructured Layer in AISI 316L Stainless Steel

IF 0.9 Q3 Engineering

Surface Engineering and Applied Electrochemistry Pub Date : 2025-03-04 DOI:10.3103/S1068375524700327

D. Z. Grabko, A. A. Prisacaru, D. E. Topal, O. A. Shikimaka

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Abstract

A nano- and microstructured surface layer (NMSSL) was created on an AISI 316L stainless-steel sample by impact loading. As a result of the impacts, a change in the microstructure of the test sample was observed: a decrease in the size of the grains, an increase in their misorientation, the appearance of slip bands inside the grains, and the appearance of rounded shapes of different sizes (0.1–15 μm) and with different densities on the surface of the sample. Moreover, these nanomicrocrystalline grains had random crystallographic orientation. The microhardness of the deformed surface was assessed using the Vickers and Berkovich methods. The hardness imprints had an approximately equiaxial shape, but the sides of the imprints were often distorted. The microhardness on the impact-deformed surface ranged as Н = 2.7–4.2 GPa depending on the number of impacts, increasing with their growth and decreasing with the distance from the impact surface. The microhardness of the undeformed sample was 2.0 GPa. The main patterns of formation of the deformed layer depending on the number of impacts have been revealed.

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轻冲击变形在aisi316l不锈钢中形成近表面纳米和微结构层

通过冲击加载在aisi316l不锈钢试样上形成纳米微结构表面层（NMSSL）。在冲击作用下，试样的微观结构发生了变化：晶粒尺寸减小，取向偏差增加，晶粒内部出现滑移带，试样表面出现不同尺寸（0.1 ~ 15 μm）、不同密度的圆形形状。此外，这些纳米微晶颗粒具有随机的晶体取向。采用维氏法和伯氏法测定变形表面的显微硬度。硬度压痕具有近似等轴形状，但压痕的侧面常发生畸变。随着冲击次数的增加，冲击变形表面的显微硬度变化范围为Н = 2.7 ~ 4.2 GPa，随着冲击次数的增加而增大，随着距离冲击表面的距离而减小。未变形试样的显微硬度为2.0 GPa。根据撞击次数揭示了变形层形成的主要模式。

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来源期刊

Surface Engineering and Applied Electrochemistry Engineering-Industrial and Manufacturing Engineering

CiteScore

1.60

自引率

22.20%

发文量

期刊介绍： Surface Engineering and Applied Electrochemistry is a journal that publishes original and review articles on theory and applications of electroerosion and electrochemical methods for the treatment of materials; physical and chemical methods for the preparation of macro-, micro-, and nanomaterials and their properties; electrical processes in engineering, chemistry, and methods for the processing of biological products and food; and application electromagnetic fields in biological systems.