[1] H L Li, M Eddaoudi, M O'Keeffe et al. Design and synthesis of an exceptionally stable and highly porous metal-organic framework. Nature, 402, 276-279(1999).
[2] L Jiao, J Y R Seow, W S Skinner et al. Metal-organic frameworks: structures and functional applications. Materials Today, 27, 43-68(2019).
[3] F Gándara, H Furukawa, S Lee et al. High methane storage capacity in aluminum metal-organic frameworks. Journal of the American Chemical Society, 136, 5271-5274(2014).
[4] D K Wang, Z H Li. Coupling MOF-based photocatalysis with Pd catalysis over Pd@MIL-100(Fe) for efficient N-alkylation of amines with alcohols under visible light. Journal of Catalysis, 342, 151-157(2016).
[5] Z J Chen, P H Li, R Anderson et al. Balancing volumetric and gravimetric uptake in highly porous materials for clean energy. Science, 368, 297-303(2020).
[6] D J Tranchemontagne, J R Hunt, O M Yaghi. Room temperature synthesis of metal-organic frameworks: MOF-5, MOF-74, MOF-177, MOF-199, and IRMOF-0. Tetrahedron, 64, 8553-8557(2008).
[7] C Janiak, J K Vieth. MOFs, MILs and more: concepts, properties and applications for porous coordination networks (PCNs). New Journal of Chemistry, 34, 2366-2388(2010).
[8] R S Varma, A Baul, R Wadhwa et al. Introduction to metal-organic frameworks (MOFs). Metal-Organic Frameworks (MOFs) as Catalysts, 3-42(2022).
[9] O M Yaghi, M J Kalmutzki, C S Diercks. Introduction to reticular chemistry: metal-organic frameworks and covalent organic frameworks, 57-82(2019).
[10] M Kim, J F Cahill, H H Fei et al. Postsynthetic ligand and cation exchange in robust metal-organic frameworks. Journal of the American Chemical Society, 134, 18082-18088(2012).
[11] S M Cohen. Modifying MOFs: new chemistry, new materials. Chemical Science, 1, 32-36(2010).
[12] B Gupta, N Anjum. Development of membranes by radiation grafting of acrylamide into polyethylene films: Characterization and thermal investigations. Journal of Applied Polymer Science, 82, 2629-2635(2001).
[13] N Zhao, J Peng, G Liu et al. PVP-capped CdS nanopopcorns with type-II homojunctions for highly efficient visible-light-driven organic pollutant degradation and hydrogen evolution. Journal of Materials Chemistry A, 6, 18458-18468(2018).
[14] H T Wang, H Q Jiang, R F Shen et al. Electron-beam radiation effects on the structure and properties of polypropylene at low dose rates. Nuclear Science and Techniques, 29, 87(2018).
[15] M M Nasef, E S A Hegazy. Preparation and applications of ion exchange membranes by radiation-induced graft copolymerization of polar monomers onto non-polar films. Progress in Polymer Science, 29, 499-561(2004).
[16] J P Wang, Y Z Chen, X W Ge et al. Gamma radiation-induced grafting of a cationic monomer onto chitosan as a flocculant. Chemosphere, 66, 1752-1757(2007).
[17] L H Guo, B Li, H F Wang. Effect of maleic anhydride/vinyltrimethoxysilane-co-grafting polypropylene on the properties of wood-flour/polypropylene composites by electron-beam preirradiation. Journal of Applied Polymer Science, 121, 402-409(2011).
[18] M Yu, Z Q Wang, M Lv et al. Antisuperbug cotton fabric with excellent laundering durability. ACS Applied Materials & Interfaces, 8, 19866-19871(2016).
[19] Ming YU, Ziqiang WANG, Jingye LI. Non-effluent dyeing for cotton fabric at room temperature using radiation-induced graft polymerization technology. Textile Dyeing and Finishing Journal, 42, 13-16(2020).
[20] M Yu, W X Li, Z Q Wang et al. Covalent immobilization of metal—organic frameworks onto the surface of nylon—a new approach to the functionalization and coloration of textiles. Scientific Reports, 6, 22796(2016).
[21] G Férey, C Mellot-Draznieks, C Serre et al. A chromium terephthalate-based solid with unusually large pore volumes and surface area. Science, 309, 2040-2042(2005).
[22] C H Yu, L Zhao, S J Wang et al. One-step radiation-induced construction of multi-responsive self-assemblies using simple cyclic ethers. Soft Matter, 9, 5959-5965(2013).