Carbon-based metal-oxides and MOFs for efficient CO2 detection/reduction to chemical/fuels

IF 7.1 3区 材料科学 Q1 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Materials Today Sustainability Pub Date : 2024-08-06 DOI:10.1016/j.mtsust.2024.100952
Deepak Kumar , Pashupati Pratap Neelratan , Anshika Gupta , Neeru Sharma , Manisha Sharma , Sangeeta Shukla , Satendra Pal Singh , Jong-Sung Yu , Ajeet Kaushik , Sanjeev K. Sharma
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Abstract

This article explores nanocarbons (NCs) decorated metal oxides (MOx) and metal-organic frameworks (MOFs) hybrid nanosystems for efficient CO2 detection and conversion to energy for environment sustainability. NCs have emerged as promising low-cost sensing and catalytic materials for conversion, which are decorated MOx and MOFs to fabricate hybrid nanosystems. These systems are considered for the next generation of CO2 detection and value-added products using photo/electro/biological catalytic processes. To cater to state-of-the-art knowledge and aspects, this article summarises the research progress of functional C-based MOx and MOF hybrid materials as effective platforms for desired absorption/adsorption of CO2 and conversion technologies, which will be part of a circular economy. At the end of this article, limitations, challenges, and future perspectives of C-based materials are summarized to understand and implement the knowledge for advanced sensing devices and efficient reduction of fuel/chemical production. NCs-decorated MOx hybrid materials have shown the potential for highly selective and fast-responsive CO2 detectors due to their high carrier rates, nominal working temperature, chemical compositions, morphologies, large specific surface area, and high mechanical strength. C-based nanomaterials, such as CNTs, C60, C-QDs, and Gr, might be considered for flexible sensors that enhance stability and limit of detection (LOD). MOFs are highly recommended for CO2 detection and reduction through adsorption, owing to their interconnected linker arms, cage-like structure, and extensive internal surface area. This article contributes to the ongoing research on innovative materials and strategies for addressing global environmental challenges and energy sustainability through advanced sensing and conversion technologies.

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用于高效检测二氧化碳/将其还原为化学品/燃料的碳基金属氧化物和 MOFs
本文探讨了纳米碳元(NCs)装饰金属氧化物(MOx)和金属有机框架(MOFs)的混合纳米系统,用于高效检测二氧化碳并将其转化为能源,以实现环境的可持续发展。氮氧化物已成为有前途的低成本传感和催化转换材料,通过装饰 MOx 和 MOFs 可制造出混合纳米系统。这些系统可用于下一代二氧化碳检测和利用光/电/生物催化过程生产增值产品。为了迎合最前沿的知识和方面,本文总结了功能性 C 基 MOx 和 MOF 混合材料作为理想的二氧化碳吸收/吸附和转化技术的有效平台的研究进展,这将是循环经济的一部分。文章最后总结了C基材料的局限性、挑战和未来展望,以便理解和运用相关知识,开发先进的传感设备,并有效减少燃料/化学品的生产。由于具有高载流子速率、额定工作温度、化学成分、形态、大比表面积和高机械强度等特点,NCs 装饰的 MOx 混合材料已显示出用于高选择性和快速响应 CO2 检测器的潜力。以 C 为基础的纳米材料,如 CNT、C60、C-QDs 和 Gr,可考虑用于柔性传感器,以提高稳定性和检测限 (LOD)。MOF 因其相互连接的连接臂、笼状结构和广泛的内表面积,被强烈推荐用于通过吸附进行二氧化碳检测和还原。这篇文章为当前通过先进的传感和转换技术应对全球环境挑战和能源可持续性的创新材料和战略研究做出了贡献。
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来源期刊
CiteScore
5.80
自引率
6.40%
发文量
174
审稿时长
32 days
期刊介绍: Materials Today Sustainability is a multi-disciplinary journal covering all aspects of sustainability through materials science. With a rapidly increasing population with growing demands, materials science has emerged as a critical discipline toward protecting of the environment and ensuring the long term survival of future generations.
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