Operando Time and Space-Resolved Liquid-Phase Diagnostics Reveal the Plasma Selective Synthesis of Nanographenes

IF 5.8 3区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY Nanoscale Pub Date : 2024-07-01 DOI:10.1039/d4nr01280a

Darwin Kurniawan, Francesca Caielli, Karthik Thyagajaran, Kostya Ken Ostrikov, Wei-Hung Chiang, David Z. Pai

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Abstract

Coupling atmospheric-pressure low-temperature plasmas to electrochemical reactors enables the generation of highly reactive species at plasma-liquid interfaces. This type of plasma electrochemical reactor (PEC) has been used to synthesize fluorescent nitrogen-doped graphene quantum dots (NGQDs),1 which are usable for multifunctional applications in a facile, simple, and sustainable way. However, the synthesis mechanism remains poorly understood, as well as the location of synthesis. To research these questions, we present an in situ diagnostics study on liquid phase chemistry during the PEC synthesis of NGQDs from chitosan. Monitoring of the photoluminescence and UV-VIS absorption at different depths in the reaction medium during plasma treatment reveals that the NGQDs are produced at the plasma-liquid interface but accumulate at a few millimetres depth below the interface, where the liquid ceases to flow convectively, as determined by particle image velocimetry. Our study provides insights into the plasma synthesis of fluorescent GQDs/NGQDs from carbon precursors that may prove useful for achieving the scalability of PEC processes up to continuous-flow or array reactors.

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操作时和空间分辨液相诊断揭示了纳米石墨烯的等离子选择性合成过程

将常压低温等离子体与电化学反应器耦合，可在等离子体-液体界面生成高活性物种。这种等离子体电化学反应器（PEC）已被用于合成荧光氮掺杂石墨烯量子点（NGQDs）1 ，这种量子点可以方便、简单和可持续地用于多功能应用。然而，人们对其合成机理以及合成位置仍知之甚少。为了研究这些问题，我们对壳聚糖 PEC 合成 NGQDs 过程中的液相化学进行了现场诊断研究。通过监测等离子体处理过程中反应介质不同深度的光致发光和紫外-可见吸收，我们发现 NGQDs 是在等离子体-液体界面产生的，但在界面下几毫米处聚集，根据粒子图像测速仪的测定，液体在该处停止对流。我们的研究为利用等离子体从碳前驱体合成荧光 GQDs/NGQDs 提供了见解，这可能有助于将 PEC 过程扩展到连续流或阵列反应器。

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来源期刊

Nanoscale CHEMISTRY, MULTIDISCIPLINARY-NANOSCIENCE & NANOTECHNOLOGY

CiteScore

12.10

自引率

3.00%

发文量

1628

审稿时长

1.6 months

期刊介绍： Nanoscale is a high-impact international journal, publishing high-quality research across nanoscience and nanotechnology. Nanoscale publishes a full mix of research articles on experimental and theoretical work, including reviews, communications, and full papers.Highly interdisciplinary, this journal appeals to scientists, researchers and professionals interested in nanoscience and nanotechnology, quantum materials and quantum technology, including the areas of physics, chemistry, biology, medicine, materials, energy/environment, information technology, detection science, healthcare and drug discovery, and electronics.