金属有机骨架薄膜的逐层组装:制造和先进应用

IF 6.1 Q2 CHEMISTRY, PHYSICAL Chemical physics reviews Pub Date : 2023-03-01 DOI:10.1063/5.0135019
Dong-Hui Chen, H. Gliemann, C. Wöll
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引用次数: 7

摘要

金属有机骨架(mof)是一类由无机节点和有机连接体组装而成的晶体多孔配位材料。许多应用,如气体储存,分子分离,催化,光学传感和电荷传输,受益于MOF材料的卓越性能。更先进的应用,例如在电子和光电子领域,需要均匀和单片的MOF薄膜。最近的研究表明,表面贴装mof (surmof)非常适合满足mof集成到器件中的要求。作为一种厚度可调的晶体薄膜材料,SURMOFs已广泛应用于生色团叠加、电输运、刺激响应等方面的优化。surmof薄膜的制备采用一层接一层(LbL)组装技术,可以得到取向明确、厚度可调、晶体异质结构可编辑的MOF薄膜。我们总结了用于SURMOF制造的LbL组装方法和先进SURMOF架构的实现,包括光学和电子应用以及光敏SURMOF和SURMOF衍生材料在技术器件中的集成。我们最后讨论了SURMOF材料的挑战和未来的预测。
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Layer-by-layer assembly of metal-organic framework thin films: Fabrication and advanced applications
Metal-organic frameworks (MOFs) are a class of crystalline porous coordination materials, which are assembled from inorganic nodes and organic linkers. Numerous applications, such as gas storage, molecule separation, catalysis, optical sensing, and charge transport, benefit from the outstanding properties of MOF materials. More advanced applications, e.g., in the electronics and optoelectronics area, demand homogeneous and monolithic MOF thin films. Recent studies demonstrated that surface-mounted MOFs (SURMOFs) are well suited to fulfill the requirements for the integration of MOFs into devices. As a crystalline thin-film material with tunable thickness, SURMOFs have been widely used in the optimization of chromophore stacking, electrical transport, stimuli-response, etc. The fabrication of SURMOFs is carried out employing a layer-by-layer (LbL) assembly technique, and it can yield MOF thin films with a well-defined orientation, tunable thickness, and editable crystalline heterostructure. We summarize the LbL assembly methods for SURMOF fabrication and the realization of advanced SURMOF architectures, including optical and electronic applications as well as the integration of photoactive SURMOFs and SURMOF-derived materials in technical devices. We conclude with a discussion of the challenges and prediction of the future of SURMOF materials.
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