Remarkable wear resistance in ceramic-metal composites with composition gradients and regionalized heterostructures

IF 6.1 1区 工程技术 Q1 ENGINEERING, MECHANICAL
Guanyu He , Yilong Liang , Peng Chen
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引用次数: 0

Abstract

Ceramic–metal composites undergo a predominant mode of wear failure known as brittle intergranular fracture caused by strain localization. In this work, we report for the first time the employment of heterostructures to alter the failure mode of frictional interfaces within such composites. We achieve this by integrating fine-grained tungsten carbide (WC)/graphene nanoplates (GNPs) into the surface layer of coarse-grained WC–11 wt%Co cemented carbides, constructing a gradient heterostructure that simultaneously possessed fine-grained, binder phase, GNPs composition gradients, and regionalized heterostructure of coarse and fine grains. This structure yielded extraordinary wear resistance, outperforming gradient-structured cemented carbides and decreasing the wear rate of the WC-11 wt% Co cemented carbides surface by an order of magnitude. The multi-typed gradient structure improved the resistance of the composite to frictional loads along with fracture resistance. During dry sliding, the heterostructure facilitated strain hardening and transfer by activating dislocations and stacking fault networks. Moreover, the pilling ups of high-density geometrically necessary dislocations of types a, c, and a+c within the constrained coarse-grained WC increased the strain tolerance and promoted plastic deformation uniformity. This synergistic effect enabled the frictional interface to accommodate elastoplastic deformation induced by frictional stresses, thereby preventing localized brittle fractures. The proposed approach paves a novel pathway for designing wear-resistant ceramic–metal composites.
具有成分梯度和区域化异质结构的陶瓷-金属复合材料的显著耐磨性
陶瓷-金属复合材料的主要磨损失效模式是应变局部化导致的脆性晶间断裂。在这项研究中,我们首次报道了利用异质结构改变此类复合材料摩擦界面失效模式的方法。为此,我们将细粒碳化钨(WC)/石墨烯纳米板(GNPs)整合到粗粒 WC-11 wt%Co 硬质合金的表层中,构建了一种梯度异质结构,同时具有细粒、粘合剂相、GNPs 成分梯度,以及粗粒和细粒的区域化异质结构。这种结构具有优异的耐磨性,性能优于梯度结构硬质合金,并将 WC-11 wt% Co 硬质合金表面的磨损率降低了一个数量级。多梯度结构提高了复合材料的抗摩擦载荷能力和抗断裂能力。在干滑动过程中,异质结构通过激活位错和堆叠断层网络促进了应变硬化和转移。此外,a、c 和 a+c 三种类型的高密度几何必要位错在受约束的粗粒 WC 中堆积,提高了应变耐受性并促进了塑性变形的均匀性。这种协同效应使摩擦界面能够适应摩擦应力引起的弹塑性变形,从而防止局部脆性断裂。所提出的方法为设计耐磨陶瓷-金属复合材料开辟了一条新途径。
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来源期刊
Tribology International
Tribology International 工程技术-工程:机械
CiteScore
10.10
自引率
16.10%
发文量
627
审稿时长
35 days
期刊介绍: Tribology is the science of rubbing surfaces and contributes to every facet of our everyday life, from live cell friction to engine lubrication and seismology. As such tribology is truly multidisciplinary and this extraordinary breadth of scientific interest is reflected in the scope of Tribology International. Tribology International seeks to publish original research papers of the highest scientific quality to provide an archival resource for scientists from all backgrounds. Written contributions are invited reporting experimental and modelling studies both in established areas of tribology and emerging fields. Scientific topics include the physics or chemistry of tribo-surfaces, bio-tribology, surface engineering and materials, contact mechanics, nano-tribology, lubricants and hydrodynamic lubrication.
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