Synthesis of Porous Connected Cryoaerogel Networks from Cadmium Chalcogenide Nanoplatelet Stacks

R. Graf, D. Pluta, Adrian Hannebauer, Jakob Schlenkrich, N. Bigall
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引用次数: 0

Abstract

Cadmium chalcogenide nanoplatelets (NPLs) are not only known due to their unique optical properties but also because of their ability to self‐assemble into stacks with new collective properties. Only recently, a stacking process in an aqueous medium has been demonstrated, which opens up possible applications and methods such as gelation. Nanoparticle‐based aerogels gain a lot of attention due to their high relative surface areas and porosity and thus, high potential for catalytic applications. Herein, the positive properties of aerogels to the NPL‐stack system by cryoaerogelation of destabilized NPL dispersions are introduced. After the addition of an antisolvent to initiate the stacking, the dispersion is flash‐frozen with liquid nitrogen and freeze‐dried. By this method, porous cryoaerogel networks result in high surface areas and retained stacking of the NPLs. The formed stack‐gels are investigated by electron microscopy and physisorption measurements. Optical and photoelectrochemical measurements verify the charge carrier transport within the stack‐gel network.

Abstract Image

利用钙化镓纳米颗粒堆合成多孔连接的冷凝胶网络
铬化镉纳米小板(NPLs)不仅因其独特的光学特性而为人所知,还因为它们能够自组装成具有新的集合特性的堆栈。直到最近,在水介质中的堆积过程才被证实,这开辟了凝胶化等可能的应用和方法。基于纳米粒子的气凝胶因其相对表面积大、孔隙率高,因而在催化应用方面具有很大的潜力而备受关注。本文介绍了通过低温凝胶化失去稳定性的 NPL 分散体,气凝胶对 NPL 堆栈系统的积极特性。在加入抗溶剂启动堆叠后,用液氮对分散体进行速冻并冷冻干燥。通过这种方法,多孔的低温凝胶网络产生了高表面积,并保留了 NPL 的堆叠。通过电子显微镜和物理吸附测量对形成的叠层凝胶进行了研究。光学和光电化学测量验证了堆叠凝胶网络中的电荷载流子传输。
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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CiteScore
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