机构地区:[1]Additive Manufacturing Institute,Shenzhen University,Shenzhen 518060,Guangdong,China [2]School of Mechanical Engineering,Dongguan University of Technology,Dongguan 523808,Guangdong,China [3]Shenzhen Engineering Laboratory of Phosphorene and Optoelectronics,International Collaborative Laboratory of 2D Materials for Optoelectronics Science and Technology of Ministry of Education,Institute of Microscale Optoelectronics,Engineering,Shenzhen University,Shenzhen 518060,Guangdong,China [4]Department of Bio‑Chemistry,Quaid-I-Azam University,Islamabad 45320,Pakistan [5]School of Chemistry and Chemical Engineering,University of South China,Hengyang 421001,Hunan,China [6]School of Chemical and Biomolecular Engineering,The University of Sydney,Sydney,NSW 2006,Australia [7]School of Science,The Royal Melbourne Institute of Technology University,Melbourne,VIC 3000,Australia [8]Department of Mechanical Engineering,City University of Hong Kong,83 Tat Chee Avenue,Kowloon,Hong Kong,China
出 处:《Electrochemical Energy Reviews》2024年第1期700-786,共87页电化学能源评论(英文)
摘 要:Unsustainable fossil fuel energy usage and its environmental impacts are the most significant scientific challenges in the scientific community.Two-dimensional(2D)materials have received a lot of attention recently because of their great potential for application in addressing some of society’s most enduring issues with renewable energy.Transition metal-based nitrides,carbides,or carbonitrides,known as“MXenes”,are a relatively new and large family of 2D materials.Since the discovery of the first MXene,Ti_(3)C_(2) in 2011 has become one of the fastest-expanding families of 2D materials with unique physiochemical features.MXene surface terminations with hydroxyl,oxygen,fluorine,etc.,are invariably present in the so far reported materials,imparting hydrophilicity to their surfaces.The current finding of multi-transition metal-layered MXenes with controlled surface termination capacity opens the door to fabricating unique structures for producing renewable energy.MXene NMs-based flexible chemistry allows them to be tuned for energy-producing/storage,electromagnetic interference shielding,gas/biosensors,water distillation,nanocomposite reinforcement,lubrication,and photo/electro/chemical catalysis.This review will first discuss the advancement of MXenes synthesis methods,their properties/stability,and renewable energy applications.Secondly,we will highlight the constraints and challenges that impede the scientific community from synthesizing functional MXene with controlled composition and properties.We will further reveal the high-tech implementations for renewable energy storage applications along with future challenges and their solutions.
关 键 词:Recent development in synthesis Structures Properties of MXenes nanomaterials Propose approaches of diverse MXene-based nanoplatforms MXenes for renewable energy applications Optimization strategies and mechanisms to enhance MXenes compatibility Current challenges and probable progress for MXenes in renewable energy applications
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