Solving Strength–Toughness Dilemma in Superhard Transition-Metal Diborides via a Distinct Chemically Tuned Solid Solution Approach  被引量：2

作　　者：Xinlei Gu Chang Liu Xinxin Gao Kan Zhang Weitao Zheng Changfeng Chen 

机构地区：[1]State Key Laboratory of Superhard Materials,Department of Materials Science and Key Laboratory of Automobile Materials,MOE,Jilin University,Changchun 130012,China [2]International Center for Computational Methods&Software,College of Physics,Jilin University,Changchun 130012,China [3]Department of Physics and Astronomy,University of Nevada,Las Vegas,NV 89154,USA

出　　处：《Research》2023年第3期473-483,共11页研究（英文）

基　　金：the National Natural Science Foundation of China(grant no.51972139);the China Postdoctoral Science Foundation(grant no.2020M681031);the Science and Technology Development Program of jilin province(grant no.20210101062JC).

摘　　要：Solid solution strengthening enhances hardness of metals by introducing solute atoms to create local distortions in base crystal lattice,which impedes dislocation motion and plastic deformation,leading to increased strength but reduced ductility and toughness.In sharp contrast,superhard materials comprising covalent bonds exhibit high strength but low toughness via a distinct mechanism dictated by brittle bond deformation,showcasing another prominent scenario of classic strength–toughness tradeoff dilemma.Solving this less explored and understood problem presents a formidable challenge that requires a viable strategy of tuning main load-bearing bonds in these strong but brittle materials to achieve concurrent enhancement of the peak stress and related strain range.Here,we demonstrate a chemically tuned solid solution approach that simultaneously enhances hardness and toughness of superhard transition-metal diboride Ta_(1−x)Zr_(x)B_(2).This striking phenomenon is achieved by introducing solute atom Zr that has lower electronegativity than solvent atom Ta to reduce the charge depletion on the main load-bearing B–B bonds during indentation,leading to prolonged deformation that gives rise to notably higher strain range and the corresponding peak stress.This finding highlights the crucial role of properly matched contrasting relative electronegativity of solute and solvent atoms in creating concurrent strengthening and toughening and opens a promising avenue for rational design of enhanced mechanical properties in a large class of transition-metal borides.This strategy of concurrent strength–toughness optimization via solute-atom-induced chemical tuning of the main load-bearing bonding charge is expected to work in broader classes of materials,such as nitrides and carbides.

关 键 词：TOUGHNESS deformation strengthening 

分 类 号：TG1[金属学及工艺—金属学]