材料科学
无定形固体
化学工程
基质(化学分析)
涂层
纳米技术
复合材料
结晶学
工程类
化学
作者
Alexander Thewes,Lars Bröcker,Phillip Marvin Reinders,Hanno Paschke,Tristan Brückner,Wolfgang Tillmann,Julia Urbanczyk,Nelson Filipe Lopes Dias,Michael Paulus,Christian Sternemann
标识
DOI:10.1002/admi.202400644
摘要
Abstract A Ti‐Si‐C‐N coating is deposited on AISI H11 hot working steel by plasma‐enhanced chemical vapor deposition (PECVD) to investigate its micro‐ and nanostructure as well as its mechanical and thermal properties. Instead of a nanocomposite structure consisting of randomly oriented nanocrystalline (nc‐) grains < 10 nm surround by an amorphous (a‐) matrix, as usually found for these systems, this Ti‐Si‐C‐N coating shows much larger Ti(C,N)‐grains with a preferred (200) orientation identify by X‐ray diffraction analysis. The strong texturing and grain sizes > 10 nm of the coating are confirmed by high‐resolution transmission electron microscopy images. The coating's hardness is 46.3 GPa, making it equally hard to, e.g., nanocomposite Ti‐Si‐N coatings. These hardness values can only be achieved by a strong interface between a‐matrix and nc‐grains and small grain size. Despite 41.1 at.% carbon content, no significant quantity of a‐C is found, as evidenced by Raman spectroscopy analysis. In order to investigate the oxidation behavior of the coatings, X‐ray diffraction experiments are carried out at room temperature and in‐situ in ambient atmosphere at elevated temperatures. The room temperature measurement shows a strong texturing of the Ti(C,N) lattice and yielded additional information on an anisotropic grain size.
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