Laser additive manufacturing of metallic glasses: issues in vitrification and mechanical properties

IF 2.9 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
S. Madge, A. Greer
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引用次数: 4

Abstract

Bulk metallic glasses (BMGs), on account of their attractive properties, have now begun to witness a few commercial applications, e.g. in coatings and micro-gears. Additive manufacturing (AM) or 3D printing, although established for crystalline alloys, has only recently been used for synthesising BMG components. The issues arising in 3D printing of BMGs are of current relevance, and this review focuses on the key scientific aspects, namely vitrification (or crystallisation) during printing, mechanical properties of printed glassy alloys and the use of AM in identifying newer BMGs. Available data on crystallisation during printing of a variety of BMGs are analysed in terms of schematic TTT diagrams and the complex interplay between thermal cycles, the presence of quenched-in nuclei in the glass and oxygen contamination in a way that is hoped to be broadly applicable to most alloy systems. Also reviewed are three key factors influencing mechanical properties of printed BMGs, i.e. porosity, crystallinity and oxygen contamination and thereby potential strategies for improvement are suggested. The review concludes with a discussion on the use of AM for combinatorial alloy development aimed at identifying better glass-forming compositions, which may in turn facilitate greater use of AM in manufacturing glassy components with desired properties.
金属玻璃的激光增材制造:玻璃化和机械性能问题
大块金属玻璃(BMG)由于其诱人的性能,现在已经开始出现一些商业应用,例如在涂层和微型齿轮中。增材制造(AM)或3D打印,尽管是为晶体合金而建立的,但直到最近才被用于合成BMG成分。BMG 3D打印中出现的问题具有当前的相关性,本综述侧重于关键的科学方面,即打印过程中的玻璃化(或结晶)、打印玻璃合金的机械性能以及AM在识别新BMG中的使用。根据TTT示意图和热循环之间的复杂相互作用、玻璃中晶核中淬火的存在和氧污染,分析了各种BMG印刷过程中结晶的可用数据,希望这种方法能广泛应用于大多数合金系统。综述了影响印刷BMG力学性能的三个关键因素,即孔隙率、结晶度和氧污染,并提出了潜在的改进策略。综述最后讨论了AM在组合合金开发中的应用,旨在确定更好的玻璃成型成分,这反过来可能有助于AM在制造具有所需性能的玻璃部件中的更多应用。
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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来源期刊
CiteScore
3.60
自引率
0.00%
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0
审稿时长
7 weeks
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