Modification of graphene-based nanomaterials with gamma irradiation as an eco-friendly approach for diverse applications: A review

IF 5.9 3区材料科学 Q2 CHEMISTRY, PHYSICAL

FlatChem Pub Date : 2024-04-21 DOI:10.1016/j.flatc.2024.100662

Nkosingiphile E. Zikalala , Shohreh Azizi , Force T. Thema , Karen J. Cloete , Ali.A. Zinatizadeh , Touhami Mokrani , Nomvano Mketo , Malik M. Maaza

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Abstract

Graphene-based nanomaterials (GBNMs) are versatile due to their large surface area, great mechanical, chemical strength, and excellent electrical properties. The versatility of graphene has increased its applicability therefore several synthesis methods to produce high quality graphene simpler, faster, and cost-effectively are actively explored. The conventional synthesis methods however employ toxic chemicals, high temperatures, and lengthy synthesis times. On the other hand, the gamma (γ) irradiation approach is facile, occurs under ambient conditions and produces graphene composites of high purity. Noteworthy, this technique enables the user to control the synthesis time and total dose, hence minimising the aggregation of the nanomaterial, the main drawback hindering the commercial production of GBNMs. γ-radiolysis synthesized GBNMs exhibit superior optical and electrical properties and hence improved supercapacitance, catalytic, and sensing abilities. Although other reviews addressed the γ-ray synthesis of metallic nanomaterials, polymers, as well as usage of a variety of radiation techniques to fabricate graphene composites, this review focuses solely on the synthesis and modifications of GBNMs via the γ-synthesis technique. Properties of graphene and conventional methods used to reduce graphene oxide (GO) to graphene as well as their shortcomings are highlighted. This is followed by detailing the γ-radiation synthesis technique, its advantages over the conventional methods and the principles thereof. Effects of γ-irradiation and the conditions required for the structural modification of graphene to obtain different graphene composites are detailed. The influence of operational parameters on the fabricated graphene-based composites are discussed followed by summaries of recent developments in the applicability of γ-irradiated GBNMs in catalysis, energy, sensing, and biomedical fields. In addition, this paper presents insights into the challenges posed and provides future research directions and prospects in the field of γ-irradiated GBNMs.

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利用伽马辐照对石墨烯基纳米材料进行改性，将其作为一种生态友好型方法用于多种应用：综述

石墨烯基纳米材料（GBNMs）具有大表面积、高机械强度、化学强度和优异的电气性能，因此用途广泛。石墨烯的多功能性提高了它的适用性，因此人们正在积极探索几种合成方法，以更简单、更快速、更具成本效益地生产出高质量的石墨烯。然而，传统的合成方法需要使用有毒化学品、高温和较长的合成时间。另一方面，伽马（γ）辐照法简便易行，可在环境条件下进行，并能生产出高纯度的石墨烯复合材料。值得注意的是，这种技术使用户能够控制合成时间和总剂量，从而最大限度地减少纳米材料的聚集，而这正是阻碍 GBNM 商业化生产的主要缺点。γ-射线分解合成的GBNM具有优异的光学和电学特性，因此提高了超级电容、催化和传感能力。虽然其他综述涉及金属纳米材料、聚合物的γ射线合成，以及使用各种辐射技术制造石墨烯复合材料，但本综述只关注通过γ合成技术合成和改性 GBNM。重点介绍了石墨烯的特性和用于将氧化石墨烯（GO）还原成石墨烯的传统方法及其缺点。随后详细介绍了 γ 辐射合成技术、与传统方法相比的优势及其原理。详细介绍了γ-辐照的影响以及对石墨烯进行结构改性以获得不同石墨烯复合材料所需的条件。本文讨论了操作参数对制备的石墨烯基复合材料的影响，随后总结了γ-辐照 GBNM 在催化、能源、传感和生物医学领域应用的最新进展。此外，本文还深入探讨了γ-辐照 GBNM 领域所面临的挑战，并提供了未来的研究方向和前景。

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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来源期刊

FlatChem Multiple-

CiteScore

8.40

自引率

6.50%

发文量

104

审稿时长

26 days

期刊介绍： FlatChem - Chemistry of Flat Materials, a new voice in the community, publishes original and significant, cutting-edge research related to the chemistry of graphene and related 2D & layered materials. The overall aim of the journal is to combine the chemistry and applications of these materials, where the submission of communications, full papers, and concepts should contain chemistry in a materials context, which can be both experimental and/or theoretical. In addition to original research articles, FlatChem also offers reviews, minireviews, highlights and perspectives on the future of this research area with the scientific leaders in fields related to Flat Materials. Topics of interest include, but are not limited to, the following: -Design, synthesis, applications and investigation of graphene, graphene related materials and other 2D & layered materials (for example Silicene, Germanene, Phosphorene, MXenes, Boron nitride, Transition metal dichalcogenides) -Characterization of these materials using all forms of spectroscopy and microscopy techniques -Chemical modification or functionalization and dispersion of these materials, as well as interactions with other materials -Exploring the surface chemistry of these materials for applications in: Sensors or detectors in electrochemical/Lab on a Chip devices, Composite materials, Membranes, Environment technology, Catalysis for energy storage and conversion (for example fuel cells, supercapacitors, batteries, hydrogen storage), Biomedical technology (drug delivery, biosensing, bioimaging)