Design and Fabrication of Nano-Particles with Customized Properties using Self-Assembly of Block-Copolymers

arXiv - PHYS - Applied Physics Pub Date : 2024-08-04 DOI:arxiv-2408.01912

Changhuang Huang, Kechun Bai, Yanyan Zhu, David Andelman, Xingkun Man

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Abstract

Functional nanoparticles (NPs) have gained significant attention as a promising application in various fields, including sensor, smart coating, drug delivery, and more. Here, we propose a novel mechanism assisted by machine-learning workflow to accurately predict phase diagram of NPs, which elegantly achieves tunability of shapes and internal structures of NPs using self-assembly of block-copolymers (BCP). Unlike most of previous studies, we obtain onion-like and mesoporous NPs in neutral environment and hamburger-like NPs in selective environment. Such novel phenomenon is obtained only by tailoring the topology of a miktoarm star BCP chain architecture without the need for any further treatment. Moreover, we demonstrate that the BCP chain architecture can be used as a new strategy for tuning the lamellar asymmetry of NPs. We show that the asymmetry between A and B lamellae in striped ellipsoidal and onion-like particles increases as the volume fraction of the A-block increases, beyond the level reached by linear BCPs. In addition, we find an extended region of onion-like structure in the phase diagram of A-selective environment, as well as the emergence of an inverse onion-like structure in the B-selective one. Our findings provide a valuable insight into the design and fabrication of nanoscale materials with customized properties, opening up new possibilities for advanced applications in sensing, materials science, and beyond.

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利用嵌段聚合物自组装设计和制造具有定制特性的纳米颗粒

功能性纳米粒子（NPs）在传感器、智能涂层、药物输送等多个领域的应用前景广阔，因而备受关注。在此，我们提出了一种由机器学习工作流程辅助的新机制，以准确预测纳米粒子的相图，从而利用嵌段聚合物（BCP）的自我组装实现了纳米粒子形状和内部结构的可调节性。与以往大多数研究不同的是，我们在中性环境中获得了洋葱状和介孔状 NPs，在选择性环境中获得了汉堡包状 NPs。这种新现象只需对米克托臂星型 BCP 链结构的拓扑结构进行裁剪即可获得，无需任何进一步处理。此外，我们还证明了 BCP 链结构可以作为一种新的策略来调整 NPs 的片层不对称性。我们发现，随着 A 嵌段体积分数的增加，条纹状椭圆形颗粒和洋葱状颗粒中 A 和 B 嵌段之间的不对称性也会增加，超过了线性 BCP 所达到的水平。此外，我们还发现在 A 选择性环境的相图中出现了洋葱状结构的延伸区域，以及在 B 选择性环境中出现了反洋葱状结构。我们的发现为设计和制造具有定制特性的纳米级材料提供了宝贵的见解，为传感、材料科学等领域的先进应用开辟了新的可能性。

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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arXiv - PHYS - Applied Physics

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