Phase patterning of metallic glasses through superfast quenching of ion irradiation-induced thermal spikes

IF 13.4 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Nano Convergence Pub Date : 2023-11-21 DOI:10.1186/s40580-023-00400-7

Hyosim Kim, Tianyao Wang, Jonathan Gigax, Arezoo Zare, Don A. Lucca, Zhihan Hu, Yongchang Li, Trevor Parker, Lin Shao

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Abstract

Amorphous metallic glasses (MGs) convert to crystalline solids upon annealing at a high temperature. Such a phase change, however, does not occur with the local melting caused by damage cascades introduced by ion irradiation, although the resulting thermal spikes can reach temperatures > 1000 K. This is because the quenching rate of the local melting zone is several orders of magnitude higher than the critical cooling rate for MG formation. Thus the amorphous structure is sustained. This mechanism increases the highest temperature at which irradiated MG sustains amorphous phase. More interestingly, if an irradiated MG is pre-annealed to form a polycrystalline structure, ion irradiation can locally convert this crystalline phase to an amorphous phase if the grains are nanometers in size and comparable to the damage cascade volume size. Combining pre-annealing and site selective ion irradiation, patterned crystalline-amorphous heterogeneous structures have been fabricated. This finding opens new doors for various applications.

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离子辐照致热尖峰的超快猝灭对金属玻璃相的影响。

非晶金属玻璃(mg)在高温退火后转变为结晶固体。然而，这种相变不会发生在由离子辐照引入的损伤级联引起的局部熔化中，尽管由此产生的热峰值可以达到1000 K的温度。这是因为局部熔化区的淬火速率比MG形成的临界冷却速率高几个数量级。因此无定形结构得以维持。这一机制提高了辐照MG维持非晶相的最高温度。更有趣的是，如果辐照MG预退火形成多晶结构，如果晶粒尺寸为纳米级且与损伤级联体积大小相当，离子辐照可以局部将该晶相转化为非晶相。采用预退火和选择性离子辐照相结合的方法，制备了无定形晶体非晶非均相结构。这一发现为各种应用打开了新的大门。

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

Nano Convergence Engineering-General Engineering

CiteScore

15.90

自引率

2.60%

发文量

审稿时长

13 weeks

期刊介绍： Nano Convergence is an internationally recognized, peer-reviewed, and interdisciplinary journal designed to foster effective communication among scientists spanning diverse research areas closely aligned with nanoscience and nanotechnology. Dedicated to encouraging the convergence of technologies across the nano- to microscopic scale, the journal aims to unveil novel scientific domains and cultivate fresh research prospects. Operating on a single-blind peer-review system, Nano Convergence ensures transparency in the review process, with reviewers cognizant of authors' names and affiliations while maintaining anonymity in the feedback provided to authors.