Micro-Mechanical Response of Ultrafine Grain and Nanocrystalline Tantalum

EngRN: Materials Chemistry (Topic) Pub Date : 2019-01-07 DOI:10.2139/ssrn.3311681

Wen Yang, C. Ruestes, Zezhou Li, O. T. Abad, T. Langdon, B. Heiland, M. Koch, E. Arzt, M. Meyers

{"title":"Micro-Mechanical Response of Ultrafine Grain and Nanocrystalline Tantalum","authors":"Wen Yang, C. Ruestes, Zezhou Li, O. T. Abad, T. Langdon, B. Heiland, M. Koch, E. Arzt, M. Meyers","doi":"10.2139/ssrn.3311681","DOIUrl":null,"url":null,"abstract":"Abstract In order to investigate the effect of grain boundaries on the mechanical response in the micrometer and submicrometer levels, complementary experiments and molecular dynamics simulations were conducted on a model bcc metal, tantalum. Microscale pillar experiments (diameters of 1 and 2 μm) with a grain size of ∼ 100-200 nm revealed a mechanical response characterized by a yield stress of ∼1,500 MPa. The hardening of the structure is reflected in the increase in the flow stress to 1,700 MPa at a strain of ∼0.35. Molecular dynamics simulations were conducted for nanocrystalline tantalum with grain sizes in the range of 20-50 nm and pillar diameters in the same range. The yield stress was approximately 6,000 MPa for all specimens and the maximum of the stress-strain curves occurred at a strain of 0.07. Beyond that strain, the material softened because of its inability to store dislocations. The experimental results did not show a significant size dependence of yield stress on pillar diameter (equal to 1 and 2 um), which is attributed to the high ratio between pillar diameter and grain size (∼10-20). This behavior is quite different from that in monocrystalline specimens where dislocation ‘starvation’ leads to a significant size dependence of strength. The ultrafine grains exhibit clear ‘pancaking’ upon being plastically deformed, with an increase in dislocation density. The plastic deformation is much more localized for the single crystals than for the nanocrystalline specimens, an observation made in both modeling and experiments. In the molecular dynamics simulations, the ratio of pillar diameter (20-50 nm) to grain size was in the range 0.2 to 2, and a much greater dependence of yield stress to pillar diameter was observed. A critical result from this work is the demonstration that the important parameter in establishing the overall deformation is the ratio between the grain size and pillar diameter; it governs the deformation mode as well as surface sources and sinks, which are only important when the grain size is of the same order as the pillar diameter.","PeriodicalId":237724,"journal":{"name":"EngRN: Materials Chemistry (Topic)","volume":"40 3 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2019-01-07","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"4","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"EngRN: Materials Chemistry (Topic)","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.2139/ssrn.3311681","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 4

Abstract

Abstract In order to investigate the effect of grain boundaries on the mechanical response in the micrometer and submicrometer levels, complementary experiments and molecular dynamics simulations were conducted on a model bcc metal, tantalum. Microscale pillar experiments (diameters of 1 and 2 μm) with a grain size of ∼ 100-200 nm revealed a mechanical response characterized by a yield stress of ∼1,500 MPa. The hardening of the structure is reflected in the increase in the flow stress to 1,700 MPa at a strain of ∼0.35. Molecular dynamics simulations were conducted for nanocrystalline tantalum with grain sizes in the range of 20-50 nm and pillar diameters in the same range. The yield stress was approximately 6,000 MPa for all specimens and the maximum of the stress-strain curves occurred at a strain of 0.07. Beyond that strain, the material softened because of its inability to store dislocations. The experimental results did not show a significant size dependence of yield stress on pillar diameter (equal to 1 and 2 um), which is attributed to the high ratio between pillar diameter and grain size (∼10-20). This behavior is quite different from that in monocrystalline specimens where dislocation ‘starvation’ leads to a significant size dependence of strength. The ultrafine grains exhibit clear ‘pancaking’ upon being plastically deformed, with an increase in dislocation density. The plastic deformation is much more localized for the single crystals than for the nanocrystalline specimens, an observation made in both modeling and experiments. In the molecular dynamics simulations, the ratio of pillar diameter (20-50 nm) to grain size was in the range 0.2 to 2, and a much greater dependence of yield stress to pillar diameter was observed. A critical result from this work is the demonstration that the important parameter in establishing the overall deformation is the ratio between the grain size and pillar diameter; it governs the deformation mode as well as surface sources and sinks, which are only important when the grain size is of the same order as the pillar diameter.

查看原文本刊更多论文

超细晶和纳米晶钽的微力学响应

摘要为了研究晶界对微米和亚微米水平力学响应的影响，对金属钽进行了互补实验和分子动力学模拟。晶粒尺寸为~ 100-200 nm的微尺度柱(直径为1 μm和2 μm)实验显示，屈服应力为~ 1,500 MPa的力学响应。在应变为~ 0.35时，流变应力增加到1,700 MPa，这反映了组织的硬化。对晶粒尺寸为20 ~ 50 nm、柱径为20 ~ 50 nm的纳米晶钽进行了分子动力学模拟。所有试样的屈服应力均在6000 MPa左右，应力-应变曲线的最大值出现在应变为0.07时。超过这个张力后，由于无法储存位错，材料就会软化。实验结果显示，屈服应力与矿柱直径(分别为1 um和2 um)之间没有显著的尺寸依赖性，这归因于矿柱直径与晶粒尺寸之间的高比值(~ 10-20)。这种行为与单晶试样中的行为完全不同，其中位错“饥饿”导致强度的显着尺寸依赖性。随着位错密度的增加，超细晶粒在塑性变形时表现出明显的“煎饼状”。在模型和实验中都观察到，单晶的塑性变形比纳米晶的塑性变形更局部化。在分子动力学模拟中，矿柱直径(20 ~ 50 nm)与晶粒尺寸之比在0.2 ~ 2之间，屈服应力与矿柱直径有较大的相关性。这项工作的一个关键结果是证明了确定整体变形的重要参数是晶粒尺寸与矿柱直径的比值;它决定了变形模式以及地表源和汇，只有当晶粒尺寸与矿柱直径在同一量级时，地表源和汇才重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

EngRN: Materials Chemistry (Topic)

自引率

0.00%

发文量