构建梯度多层结构以同时增强和增韧Ti/Mo纳米多层材料

Materials Science eJournal Pub Date : 2020-04-15 DOI:10.2139/ssrn.3566587

S. Yu, T.T. Li, Y. Hu, W.S. Wang, C.X. Wang, T. Wang, L.J. Bai, G. Zhang

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摘要

大多数纳米级金属多层材料具有超高的硬度，但韧性有限。为了使Ti/Mo纳米材料增韧，通过控制各层厚度(h)沿薄膜生长方向的梯度分布，构建了梯度多层(GM)结构。由此产生的GM结构显著提高了Ti/Mo纳米材料的韧性，但没有降低其峰值硬度。显微组织非均质性加剧导致塑性不相容而产生的高背应力是硬度和韧性空前协同的主要原因。我们的研究结果为同时强化和强化nmm提供了一种有希望的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Architecting a Gradient Multilayered Structure to Concurrently Strengthen and Toughen Ti/Mo Nanoscale Multilayers

Most nanoscale metallic multilayers (NMMs) exhibit ultra-high hardness but limited toughness. To toughen Ti/Mo NMMs, a gradient multilayered (GM) structure was architected via manipulating individual layer thickness (h) gradient distribution along the film growth direction. The resulting GM structure significantly raises the toughness of Ti/Mo NMMs without reducing their peak hardness. High back stress developed from the plastic incompatibilities stemmed from aggravated microstructural heterogeneity is primarily responsible for the unprecedented synergy of hardness and toughness. Our findings provide a promising approach to concurrently strengthen and toughen NMMs.

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Materials Science eJournal

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