掺杂对纳米多孔金系统机械性能的影响

IF 2.5 4区材料科学 Q2 CHEMISTRY, APPLIED

Journal of Porous Materials Pub Date : 2024-04-04 DOI:10.1007/s10934-024-01587-8

R. N. Viswanath, C. Lakshmanan, T. S. Sampath Kumar

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引用次数: 0

摘要

本文报告了镝掺杂对纳米多孔金属金微观结构和机械性能的影响，纳米多孔金属金是由 Ag70Au30 和 Ag70Au29Dy1 合金通过电化学脱合金合成的。研究表明，这些脱合金纳米多孔金属材料的平均韧带直径为 5-10 纳米。纯金和掺杂镝的纳米多孔金的韧带直径随退火温度的变化影响其机械性能。纯金和掺杂镝的纳米多孔金在韧带直径为 10 nm 附近获得了较高的显微硬度值。通过分析压痕对角线与外加载荷得到的维氏硬度 HV 最大值与报告的块状金的 HV 值接近。由于纳米多孔金属材料的行为方式类似于可压缩的海绵材料，我们使用了著名的密度比例方程来测定纯纳米多孔金和掺杂镝的纳米多孔金的韧带屈服强度。最后将所得结果与文献报告进行了比较。

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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Doping effects on mechanical properties of nanoporous gold systems

We report in this article, the Dysprosium doping effects on microstructure and mechanical properties of nanoporous metallic gold, synthesized by electrochemical dealloying of Ag₇₀Au₃₀ and Ag₇₀Au₂₉Dy₁ alloys. It is shown that these dealloyed nanoporous metallic materials exhibit the mean ligament diameter in a length scale of 5–10 nm. The variation of ligament diameter in pure and Dysprosium doped nanoporous Au with annealing temperature influences their mechanical properties. Higher microhardness value has been obtained around 10 nm ligament diameter on both pure and Dysprosium doped nanoporous gold. The maximum values of Vickers hardness H_V obtained from the analysis of indentation diagonals with applied load are close to the H_V value reported for bulk gold. Since the nanoporous metallic materials behave in a way like compressible sponge materials, we used the well-known density scaling equation for the determination of ligament yield strength of pure and Dysprosium doped nanoporous gold with ligament diameter. The results obtained have been finally compared with literature reports.

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来源期刊

Journal of Porous Materials 工程技术-材料科学：综合

CiteScore

4.80

自引率

7.70%

发文量

203

审稿时长

2.6 months

期刊介绍： The Journal of Porous Materials is an interdisciplinary and international periodical devoted to all types of porous materials. Its aim is the rapid publication of high quality, peer-reviewed papers focused on the synthesis, processing, characterization and property evaluation of all porous materials. The objective is to establish a unique journal that will serve as a principal means of communication for the growing interdisciplinary field of porous materials. Porous materials include microporous materials with 50 nm pores. Examples of microporous materials are natural and synthetic molecular sieves, cationic and anionic clays, pillared clays, tobermorites, pillared Zr and Ti phosphates, spherosilicates, carbons, porous polymers, xerogels, etc. Mesoporous materials include synthetic molecular sieves, xerogels, aerogels, glasses, glass ceramics, porous polymers, etc.; while macroporous materials include ceramics, glass ceramics, porous polymers, aerogels, cement, etc. The porous materials can be crystalline, semicrystalline or noncrystalline, or combinations thereof. They can also be either organic, inorganic, or their composites. The overall objective of the journal is the establishment of one main forum covering the basic and applied aspects of all porous materials.