First-Principles Study of Structural Stability and Tensile Strengths of Light-Element-Doped ZrTi

IF 0.9 4区 物理与天体物理 Q4 PHYSICS, CONDENSED MATTER
Shouxin Cui, Wenxia Feng, Bao Zhao, Guiqing Zhang, Feng Guo, Zengtao Lv
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Abstract

ZrTi alloys have potential applications in critical parts of spacecraft. As lightweight design is a fundamental requirement for spacecraft, incorporating light elements into ZrTi alloys is a feasible approach. In this paper, we investigated the tensile deformation behavior of ZrTi doped with light element by using the plane-wave pseudopotential density functional method. Covalent Ti–Zr bonds accommodate deformation by softening and breaking at large tensions, and structural stability of ZrTi and ZrTiX (X = B, Al, Ga, and V) is determined by the strength of these Ti–Zr bonds under tension. The results show that the lower doped concentrations of light element decrease the tensile strengths. However, there is no obvious difference in tensile strengths along [11\(\bar {2}\)0] direction between ZrTi and ZrTi0.875Al0.125. The results of Mulliken overlap populations indicate that different tensile strengths of ZrTiX should be resulted from different strengths of covalent Ti–Zr bonds. The incorporation of light element dopants does not strengthen all chemical bonds and weakens strengths of covalent Ti–Zr bonds, indicating that experimental strengthening mechanism of ternary ZrTiX alloys could be ascribed to Hall–Petch effect.

Abstract Image

Abstract Image

光元素掺杂锆钛结构稳定性和拉伸强度的第一原理研究
摘要锆钛合金具有应用于航天器关键部件的潜力。轻量化设计是航天器的基本要求,因此在锆钛合金中加入轻元素是一种可行的方法。本文采用平面波伪势密度泛函法研究了掺入轻元素的锆钛合金的拉伸变形行为。共价 Ti-Zr 键在大张力下通过软化和断裂来适应变形,ZrTi 和 ZrTiX(X = B、Al、Ga 和 V)的结构稳定性取决于这些 Ti-Zr 键在张力下的强度。结果表明,轻元素掺杂浓度越低,拉伸强度越低。然而,ZrTi 和 ZrTi0.875Al0.125 沿 [11\(\bar {2}\)0]方向的拉伸强度没有明显差异。穆利肯重叠群的结果表明,ZrTiX 的不同抗拉强度应该是由 Ti-Zr 共价键的不同强度造成的。轻元素掺杂物的加入并没有强化所有化学键,反而削弱了共价 Ti-Zr 键的强度,这表明三元 ZrTiX 合金的实验强化机制可归因于霍尔-佩奇效应。
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来源期刊
Physics of the Solid State
Physics of the Solid State 物理-物理:凝聚态物理
CiteScore
1.70
自引率
0.00%
发文量
60
审稿时长
2-4 weeks
期刊介绍: Presents the latest results from Russia’s leading researchers in condensed matter physics at the Russian Academy of Sciences and other prestigious institutions. Covers all areas of solid state physics including solid state optics, solid state acoustics, electronic and vibrational spectra, phase transitions, ferroelectricity, magnetism, and superconductivity. Also presents review papers on the most important problems in solid state physics.
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