The scalable integration of two-dimensional(2D)lamellar nanomaterials into flexible films opens up innovative possibilities for enhancing the performance and functionality of energy storage devices.However,a significa...The scalable integration of two-dimensional(2D)lamellar nanomaterials into flexible films opens up innovative possibilities for enhancing the performance and functionality of energy storage devices.However,a significant challenge lies in balancing mechanical strength with optimal energy storage properties.Achieving the necessary flexibility while maintaining high energy density and durability is complex due to the inherent trade-off between these properties.To address this issue and improve the overall performance of such nanomaterial films,researchers are exploring novel approaches such as hybridization with other materials,optimization of layer structures,and innovative fabrication techniques.In this vein,the emergence of hybrid nanomaterials composed of metal-organic frameworks(MOFs)and 2D MXene sheets offers exciting opportunities in the development of advanced materials for diverse applications.These MOF/MXene hybrid architectures exhibit a unique synergy that combines the exceptional surface area and tunable porosity of MOFs with the high electrical conductivity and mechanical strength of MXenes.This integration leads to the creation of versatile,multifunctional materials with promising capabilities in electrochemical energy storage and conversion,as well as environmental remediation.Hence,the present review delves into the various synthesis techniques employed to produce MOF/MXene hybrids,along with their diverse morphologies and properties,and examines the latest advancements in tailoring these nanoarchitectures for enhanced performance and efficiency.Additionally,the challenges and opportunities for future research are discussed in order to highlight the potential of these hybrid materials in pushing the boundaries of technological innovation across multiple scientific disciplines.展开更多
基金the Deanship of Scientific Research at King Khalid University for funding this work through the Large Group Research Project[grant number RGP2/300/46]。
文摘The scalable integration of two-dimensional(2D)lamellar nanomaterials into flexible films opens up innovative possibilities for enhancing the performance and functionality of energy storage devices.However,a significant challenge lies in balancing mechanical strength with optimal energy storage properties.Achieving the necessary flexibility while maintaining high energy density and durability is complex due to the inherent trade-off between these properties.To address this issue and improve the overall performance of such nanomaterial films,researchers are exploring novel approaches such as hybridization with other materials,optimization of layer structures,and innovative fabrication techniques.In this vein,the emergence of hybrid nanomaterials composed of metal-organic frameworks(MOFs)and 2D MXene sheets offers exciting opportunities in the development of advanced materials for diverse applications.These MOF/MXene hybrid architectures exhibit a unique synergy that combines the exceptional surface area and tunable porosity of MOFs with the high electrical conductivity and mechanical strength of MXenes.This integration leads to the creation of versatile,multifunctional materials with promising capabilities in electrochemical energy storage and conversion,as well as environmental remediation.Hence,the present review delves into the various synthesis techniques employed to produce MOF/MXene hybrids,along with their diverse morphologies and properties,and examines the latest advancements in tailoring these nanoarchitectures for enhanced performance and efficiency.Additionally,the challenges and opportunities for future research are discussed in order to highlight the potential of these hybrid materials in pushing the boundaries of technological innovation across multiple scientific disciplines.
