Tailored Hollow Mesoporous Carbon Nanospheres from Soft Emulsions Enhance Kinetics in Sodium Batteries

JACS Au Pub Date : 2024-07-02 DOI:10.1021/jacsau.4c00421

Lu Liu, Sicheng Fan, Wendi Wang, Sixing Yin, Zirui Lv, Jie Zhang, Jingyu Zhang, Lanhao Yang, Yuzhu Ma, Qiulong Wei, Dongyuan Zhao, Kun Lan

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Abstract

Mesoporous materials endowed with a hollow structure offer ample opportunities due to their integrated functionalities; however, current approaches mainly rely on the recruitment of solid rigid templates, and feasible strategies with better simplicity and tunability remain infertile. Here, we report a novel emulsion-driven coassembly method for constructing a highly tailored hollow architecture in mesoporous carbon, which can be completely processed on oil–water liquid interfaces instead of a solid rigid template. Such a facile and flexible methodology relies on the subtle employment of a 1,3,5-trimethylbenzene (TMB) additive, which acts as both an emulsion template and a swelling agent, leading to a compatible integration of oil droplets and composite micelles. The solution-based assembly process also shows high controllability, endowing the hollow carbon mesostructure with a uniform morphology of hundreds of nanometers and tunable cavities from 0 to 130 nm in diameter and porosities (mesopore sizes 2.5–7.7 nm; surface area 179–355 m² g^–1). Because of the unique features in permeability, diffusion, and surface access, the hollow mesoporous carbon nanospheres exhibit excellent high rate and cycling performances for sodium-ion storage. Our study reveals a cooperative assembly on the liquid interface, which could provide an alternative toolbox for constructing delicate mesostructures and complex hierarchies toward advanced technologies.

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来自软乳液的定制中空介孔碳纳米球可提高钠电池的动力学性能

具有中空结构的介孔材料因其集成功能而提供了大量机会；然而，目前的方法主要依赖于固态刚性模板的招募，而具有更好的简易性和可调性的可行策略仍然是不可行的。在此，我们报告了一种新型的乳液驱动共组装方法，用于在介孔碳中构建高度定制的空心结构，这种结构可以完全在油-水-液界面上处理，而不是使用固体刚性模板。这种简便灵活的方法依赖于 1,3,5-三甲基苯（TMB）添加剂的巧妙运用，它既是乳液模板，又是溶胀剂，从而实现了油滴与复合胶束的兼容整合。基于溶液的组装工艺还显示出很高的可控性，使中空碳介体结构具有数百纳米的均匀形貌，以及 0 至 130 纳米直径的可调空腔和孔隙率（介孔尺寸为 2.5-7.7 纳米；表面积为 179-355 平方米 g-1）。由于中空介孔碳纳米球在渗透性、扩散性和表面通路方面的独特特性，它在钠离子存储方面表现出卓越的高速率和循环性能。我们的研究揭示了在液体界面上的合作组装，这为构建精细的介质结构和复杂的层次结构提供了另一种工具箱，有助于实现先进技术。

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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JACS Au

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