Qui Thanh Hoai Ta, Jianbin Mao, Ngo Thi Chau, Ngoc Hoi Nguyen, Dieu Linh Tran, Thi My Huyen Nguyen, Manh Hoang Tran, Hoang Van Quy, Soonmin Seo, Dai Hai Nguyen
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引用次数: 0
Abstract
MXene-based functional 2D materials hold significant potential for addressing global challenges related to energy and water crises. Since their discovery in 2011, Ti3C2T x MXenes have demonstrated promising applications due to their unique physicochemical properties and distinctive morphology. Recent advancements have explored innovative strategies to enhance Ti3C2T x into multifunctional materials, enabling applications in gas sensing, electromagnetic interference shielding, supercapacitors, batteries, water purification, and membrane technologies. Unlike previous reviews that primarily focused on the synthesis, properties, and individual applications of MXenes, this work provides a fundamental discussion of their role in wastewater treatment, recent advancements in energy harvesting, and their broader implications. Additionally, this review offers a comparative analysis of MXene-based systems with other state-of-the-art materials, providing new insights into their future development and potential applications.
基于mxene的功能2D材料在解决与能源和水危机相关的全球挑战方面具有巨大潜力。自2011年发现以来,由于其独特的物理化学性质和独特的形态,Ti3C2T x MXenes展现出了广阔的应用前景。最近的进展探索了将ti3c2tx增强为多功能材料的创新策略,使其在气体传感、电磁干扰屏蔽、超级电容器、电池、水净化和膜技术方面的应用成为可能。与以往主要关注MXenes的合成、性质和单独应用的综述不同,本研究对其在废水处理中的作用、能量收集的最新进展及其更广泛的意义进行了基本的讨论。此外,本综述还提供了基于mxene的系统与其他先进材料的比较分析,为其未来的发展和潜在应用提供了新的见解。
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