氨基酸嵌段共聚物模板对介孔碳物理化学和电化学特性的增强作用

Energy Storage Pub Date : 2024-10-25 DOI:10.1002/est2.70061
M. Sivanantham, Chetna Tewari, Ramsankar Senthamaraikannan, Young Nam Kim, Diksha Bhatt, Ramesh Padamati, Nanda Gopal Sahoo, Yong Chae Jung
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引用次数: 0

摘要

氨基酸基嵌段共聚物(BCPs)具有二级结构形成、手性、两性性质、无毒性和生物降解性等显著特征,使其有别于其他 BCPs。这表明氨基酸基 BCP 可能会表现出独特的自组装行为。尽管氨基酸基 BCP 具有这些优点,但它们尚未被用作合成介孔碳 (MC) 的模板。在此,我们首次研究了两种不同的聚乙二醇(PEG)共轭氨基酸基 BCP 模板(PEG-聚(β-苄基-l-天冬氨酸)(PEG-PBLA)和 PEG-聚(γ-苄基-l-谷氨酸)(PEG-PBLG))的疏水性对 MC 材料构建的影响,以及它们的物理化学和电化学特性。以 PEG-PBLA 和 PEG-PBLG 为模板制得的 MC 分别标记为 CPBLA 和 CPBLG。利用基于氨基酸的 BCP 体系,无需外加氮掺杂剂,即可获得氮掺杂量接近 1 at% 的 MC 材料。理化分析表明,与 CPBLG 相比,CPBLA 的粒径更小、比表面积更大、孔径更大、亲水性更强,这是因为氧和氮的含量增加了。PEG-PBLA 的亲水性较高,因此形成的 CPBLA MC 颗粒尺寸较小,比表面积为 602 m2g-1,孔径为 7.8 nm。循环伏安法表明,CPBLA 比 CPBLG 具有更高的电荷存储能力(1 mv s-1 时的比电容为 147 F g-1),这归功于其更好的物理化学特性。这些充满希望的研究结果表明,氨基酸基 BCP 系统不仅可以作为模板,还可以作为碳源和氮源,为高性能电化学储能装置提供了潜力。
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Amino Acid–Based Block Copolymer Templates-Dependent Enhancement of Physicochemical and Electrochemical Characteristics of Mesoporous Carbons

Amino acid–based block copolymers (BCPs) have distinct features such as secondary structure formation, chirality, amphoteric nature, non-toxicity, and biodegradability, setting them apart from other BCPs. This suggests that amino acid–based BCPs may exhibit unique self-assembly behaviors. Despite these advantages, they have not yet been utilized as templates for mesoporous carbons (MCs) synthesis. Here, we investigate, for the first time, the effect of hydrophobicity of two different poly(ethylene glycol) (PEG) conjugated amino acid–based BCP templates (PEG-poly(β-benzyl-l-aspartate) (PEG-PBLA) and PEG-poly(γ-benzyl-l-glutamate) (PEG-PBLG)) on the construction of MC materials and also their physicochemical and electrochemical characteristics. MCs produced using PEG-PBLA and PEG-PBLG as templates are labeled CPBLA and CPBLG, respectively. Utilizing amino acid–based BCP systems enabled achieving MC materials with nearly 1 at% nitrogen doping without external nitrogen dopants. Physicochemical analysis showed CPBLA had a smaller particle size, higher specific surface area, pore size, and hydrophilicity due to increased oxygen and nitrogen contents, as well as a higher defective structure than CPBLG. The higher hydrophilicity of PEG-PBLA led to the formation of CPBLA MC particles with smaller size and higher specific surface area of 602 m2g−1 and pore size of 7.8 nm. Cyclic voltammetry demonstrated that CPBLA had superior charge-storing capacity (specific capacitance of 147 F g−1 at 1 mv s−1) than CPBLG, attributed to its better physicochemical properties. These promising findings suggest that amino acid–based BCP systems can serve not only as templates but also as carbon and nitrogen sources, offering potential for high-performance electrochemical energy storage devices.

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