Scalable Reshaping of Diamond Particles via Programmable Nanosculpting

arXiv - PHYS - Mesoscale and Nanoscale Physics Pub Date : 2024-09-14 DOI:arxiv-2409.09393

Tongtong Zhang, Fuqiang Sun, Yaorong Wang, Yingchi Li, Jing Wang, Zhongqiang Wang, Kwai Hei Li, Ye Zhu, Qi Wang, Lei Shao, Ngai Wong, Dangyuan Lei, Yuan Lin, Zhiqin Chu

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Abstract

Diamond particles have many interesting properties and possible applications. However, producing diamond particles with well-defined shapes at scale is challenging because diamonds are chemically inert and extremely hard. Here, we show air oxidation, a routine method for purifying diamonds, can be used to precisely shape diamond particles at scale. By exploiting the distinct reactivities of different crystal facets and defects inside the diamond, layer-by-layer outward-to-inward and inward-to-outward oxidation produced diverse diamond shapes including sphere, twisted surface, pyramidal islands, inverted pyramids, nano-flowers, and hollow polygons. The nanosculpted diamonds had more and finer features that enabled them to outperform the original raw diamonds in various applications. Using experimental observations and Monte Carlo simulations, we built a shape library that guides the design and fabrication of diamond particles with well-defined shapes and functional value. Our study presents a simple, economical and scalable way to produce shape-customized diamonds for various photonics, catalysis, quantum and information technology applications.

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通过可编程纳米雕刻实现金刚石颗粒的可扩展重塑

然而，由于金刚石具有化学惰性和极高的硬度，要大规模生产出具有明确形状的金刚石颗粒非常困难。在这里，我们展示了空气氧化这种纯化金刚石的常规方法，可以用于大规模精确成型金刚石颗粒。通过利用金刚石内部不同晶面和缺陷的不同活性，逐层从外向内和从内向外的氧化作用产生了多种金刚石形状，包括球形、扭曲面、金字塔形岛、倒金字塔形、纳米花和空心多边形。经过纳米雕琢的金刚石具有更多更精细的特征，使其在各种应用中的性能优于原始金刚石。通过实验观察和蒙特卡洛模拟，我们建立了一个形状库，指导设计和制造具有明确形状和功能价值的金刚石颗粒。我们的研究提出了一种简单、经济和可扩展的方法来生产形状定制的金刚石，用于各种光子学、催化、量子和信息技术应用。

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arXiv - PHYS - Mesoscale and Nanoscale Physics

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