Fengkun Li , Pingze Zhang , Dongbo Wei , Rajdeep Singh Rawat , Bo Ouyang , Rongqing Liang , Hepeng Jia , Rongjian Tai
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Furthermore, the presence of residual compressive stress (−1255.9 MPa), stress concentrations at interfaces between different phases and gradient structure contributed to the high surface fracture toughness of the coated substrate. Wear testing indicated that the lower nanomechanical properties of pristine substrate combined with the dynamic cyclic generation of oxide film during high temperature friction caused to an increase in specific wear rate at loads of 4.2 N and 6.2 N. However, post-oxidation hardness elevation as well as the lubrication and supportive effect of extensively covered oxide film reduced the wear rate as load increased to 8.2 N. The transition from residual compressive stress to tensile stress along with the formation of oxides at grain boundaries reduced the surface fracture toughness of the coated substrate. Meanwhile, the rapid formation and spalling of oxide film resulted in an increase in the specific wear rate of the coated substrate with increasing load. Nevertheless, coated substrate exhibited better wear resistance than pristine substrate owing to its higher surface mechanical properties. The specific wear rates of the coated substrate were 3.7, 6.0 and 19.5 × 10<sup>−5</sup> mm<sup>3</sup>N<sup>−1</sup> m<sup>−1</sup> at loads of 4.2, 6.2 and 8.2 N, respectively, reflecting reductions of 88.9 %, 84.3 %, and 34.6 % compared to the pristine substrate.</div></div>","PeriodicalId":22009,"journal":{"name":"Surface & Coatings Technology","volume":"494 ","pages":"Article 131512"},"PeriodicalIF":5.3000,"publicationDate":"2024-10-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Investigation on the high temperature tribological behaviors of pristine and plasma-based Mo-Si-Ti coated γ-TiAl\",\"authors\":\"Fengkun Li , Pingze Zhang , Dongbo Wei , Rajdeep Singh Rawat , Bo Ouyang , Rongqing Liang , Hepeng Jia , Rongjian Tai\",\"doi\":\"10.1016/j.surfcoat.2024.131512\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><div>A Mo-Si-Ti coated γ-TiAl substrate was fabricated using plasma alloying technology to enhance its high temperature wear resistance. 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引用次数: 0
摘要
利用等离子合金化技术制作了钼-硅-钛涂层γ-钛铝基片,以增强其高温耐磨性。涂层基底由沉积层和扩散层组成,晶粒尺寸从基底向涂层方向递减,形成梯度结构。XRD 和 TEM 分析表明,沉积层包括 (Ti,Mo)5Si3、TiSi 和 MoSi2,而扩散层包括 γ-TiAl、TiSi 和 Al8Mo3。纳米压痕测试结果表明,涂层基底具有高硬度(19.6 GPa)、高抗塑性变形能力和承载能力。此外,残余压应力(-1255.9 兆帕)的存在、不同相界面处的应力集中以及梯度结构也是涂层基底表面断裂韧性高的原因。磨损测试表明,原始基底的纳米力学性能较低,加上高温摩擦时氧化膜的动态循环生成,导致在 4.2 N 和 6.2 N 负载下的比磨损率增加。然而,氧化后硬度的提高以及广泛覆盖的氧化膜的润滑和支撑作用降低了负载增加到 8.2 N 时的磨损率。同时,氧化膜的快速形成和剥落导致涂层基底的比磨损率随着载荷的增加而增加。尽管如此,由于表面机械性能较高,涂层基底的耐磨性仍优于原始基底。在负载为 4.2、6.2 和 8.2 N 时,涂层基底的比磨损率分别为 3.7、6.0 和 19.5 × 10-5 mm3N-1 m-1,与原始基底相比分别降低了 88.9 %、84.3 % 和 34.6 %。
Investigation on the high temperature tribological behaviors of pristine and plasma-based Mo-Si-Ti coated γ-TiAl
A Mo-Si-Ti coated γ-TiAl substrate was fabricated using plasma alloying technology to enhance its high temperature wear resistance. The coated substrate was composed of a deposition layer and a diffusion layer, with the grain size decreasing from the substrate toward the coating, forming a gradient structure. XRD and TEM analysis revealed that the deposition layer included the (Ti, Mo)5Si3, TiSi and MoSi2, while the diffusion layer consisted of the γ-TiAl, TiSi and Al8Mo3. Nanoindentation results showed that the coated substrate exhibited high hardness (19.6 GPa), as well as high plastic deformation resistance and load-bearing capacity. Furthermore, the presence of residual compressive stress (−1255.9 MPa), stress concentrations at interfaces between different phases and gradient structure contributed to the high surface fracture toughness of the coated substrate. Wear testing indicated that the lower nanomechanical properties of pristine substrate combined with the dynamic cyclic generation of oxide film during high temperature friction caused to an increase in specific wear rate at loads of 4.2 N and 6.2 N. However, post-oxidation hardness elevation as well as the lubrication and supportive effect of extensively covered oxide film reduced the wear rate as load increased to 8.2 N. The transition from residual compressive stress to tensile stress along with the formation of oxides at grain boundaries reduced the surface fracture toughness of the coated substrate. Meanwhile, the rapid formation and spalling of oxide film resulted in an increase in the specific wear rate of the coated substrate with increasing load. Nevertheless, coated substrate exhibited better wear resistance than pristine substrate owing to its higher surface mechanical properties. The specific wear rates of the coated substrate were 3.7, 6.0 and 19.5 × 10−5 mm3N−1 m−1 at loads of 4.2, 6.2 and 8.2 N, respectively, reflecting reductions of 88.9 %, 84.3 %, and 34.6 % compared to the pristine substrate.
期刊介绍:
Surface and Coatings Technology is an international archival journal publishing scientific papers on significant developments in surface and interface engineering to modify and improve the surface properties of materials for protection in demanding contact conditions or aggressive environments, or for enhanced functional performance. Contributions range from original scientific articles concerned with fundamental and applied aspects of research or direct applications of metallic, inorganic, organic and composite coatings, to invited reviews of current technology in specific areas. Papers submitted to this journal are expected to be in line with the following aspects in processes, and properties/performance:
A. Processes: Physical and chemical vapour deposition techniques, thermal and plasma spraying, surface modification by directed energy techniques such as ion, electron and laser beams, thermo-chemical treatment, wet chemical and electrochemical processes such as plating, sol-gel coating, anodization, plasma electrolytic oxidation, etc., but excluding painting.
B. Properties/performance: friction performance, wear resistance (e.g., abrasion, erosion, fretting, etc), corrosion and oxidation resistance, thermal protection, diffusion resistance, hydrophilicity/hydrophobicity, and properties relevant to smart materials behaviour and enhanced multifunctional performance for environmental, energy and medical applications, but excluding device aspects.