Elucidating the intrinsic core-shell structure of carbon nanospheres from glucose hydrothermal carbonization

IF 3.4 3区工程技术 Q2 CHEMISTRY, PHYSICAL Journal of Supercritical Fluids Pub Date : 2024-04-23 DOI:10.1016/j.supflu.2024.106290

Yilun Luo , Taotao Lu , Shi Jin , Kai Ye , Shaoming Yu , Xianlong Zhang , Xueping Wu , Peiyong Ma , Jefferson W. Tester , Kui Wang

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Abstract

This study explores the core-shell structure formation mechanisms of primary carbon nanospheres (PCNs) through hydrothermal carbonization (HTC) of glucose at 200 °C, focusing on key phase-change polymerization reactions. Colloidal carbon nanoparticles in the aqueous phase filtrate self-assembled into secondary carbon nanospheres (SCNs) with intrinsic hollow structures during room temperature storage. FTIR results revealed similar functional groups on the surfaces of PCNs and SCNs due to esterification reactions during HTC cooling. XPS and ¹³ C NMR analyses identified HMF aldol condensation and etherification as dominant reactions for PCNs, while esterification and aldol condensation with levulinic acid were dominant for SCNs. The hypothesis suggests that PCNs initially formed hollow microframeworks but collapsed due to consumption of encapsulated organics, resulting in hydrophobic cores. These cores grew through aggregation (linear) and surface reactions (exponential), internalizing hydrophilic surfaces into hydrophobic cores, forming the final core-shell structure of PCNs.

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阐明葡萄糖水热碳化产生的碳纳米球的固有核壳结构

本研究以关键的相变聚合反应为重点，探讨了葡萄糖在 200 ℃ 水热碳化（HTC）过程中一次碳纳米球（PCNs）的核壳结构形成机理。水相滤液中的胶体碳纳米颗粒在室温储存过程中自组装成具有内在空心结构的二级碳纳米球（SCN）。傅立叶变换红外光谱（FTIR）结果显示，由于在 HTC 冷却过程中发生了酯化反应，PCNs 和 SCNs 表面具有相似的官能团。XPS 和 13 C NMR 分析表明，HMF 醛醇缩合和醚化反应是 PCNs 的主要反应，而酯化反应和与乙酰丙酸的醛醇缩合反应则是 SCNs 的主要反应。这一假设表明，PCNs 最初形成中空的微框架，但由于封装有机物的消耗而坍塌，从而形成疏水核心。这些核心通过聚集（线性）和表面反应（指数）生长，将亲水性表面内化为疏水性核心，最终形成多氯化萘的核壳结构。

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来源期刊

Journal of Supercritical Fluids 工程技术-工程：化工

CiteScore

7.60

自引率

10.30%

发文量

236

审稿时长

56 days

期刊介绍： The Journal of Supercritical Fluids is an international journal devoted to the fundamental and applied aspects of supercritical fluids and processes. Its aim is to provide a focused platform for academic and industrial researchers to report their findings and to have ready access to the advances in this rapidly growing field. Its coverage is multidisciplinary and includes both basic and applied topics. Thermodynamics and phase equilibria, reaction kinetics and rate processes, thermal and transport properties, and all topics related to processing such as separations (extraction, fractionation, purification, chromatography) nucleation and impregnation are within the scope. Accounts of specific engineering applications such as those encountered in food, fuel, natural products, minerals, pharmaceuticals and polymer industries are included. Topics related to high pressure equipment design, analytical techniques, sensors, and process control methodologies are also within the scope of the journal.