TY - BOOK ID - 134016875 TI - MOFs for Advanced Applications AU - Bedia, Jorge AU - Belver, Carolina PY - 2022 PB - Basel MDPI - Multidisciplinary Digital Publishing Institute DB - UniCat KW - Technology: general issues KW - History of engineering & technology KW - Materials science KW - Metal–organic framework KW - Lewis acid KW - fructose KW - 5-hydroxymethyl furfural KW - biomass KW - Metal-organic frameworks (MOFs) KW - photocatalysis KW - carbon dioxide reduction KW - renewable energy KW - heterogeneous catalysis KW - metal organic framework KW - surface modification KW - Zinc glutarate KW - CO2 fixation KW - polycarbonate KW - Mn-MOF-74 KW - modification KW - water resistance KW - NH3-SCR performance KW - environmental pollution KW - filter KW - gas sorption KW - sensor KW - hydrogen storage KW - electrospinning KW - one-pot hydrothermal KW - immobilizing recombinant KW - His-hCA II KW - Ni-BTC nanorods KW - metal–organic frameworks KW - polyoxometalates KW - hybrid materials KW - synthesis KW - catalysis KW - heterogeneous catalyst KW - aerobic oxidation KW - cyclohexene KW - metal organic frameworks KW - NH2-MIL-125(Ti) KW - water stability KW - purification KW - layered coordination polymer KW - oxidative desulfurization KW - denitrogenation extraction KW - hydrogen peroxide KW - lanthanides KW - MOF KW - catalyst KW - microreactor KW - kinetic studies KW - metal organic frame works KW - CO2 adsorption KW - pre combustion KW - gas membrane separation KW - metal halide perovskites KW - metal-organic framework KW - fuel cell KW - oxygen reduction reaction (ORR) KW - metal organic frameworks (MOFs) KW - hydrothermal synthesis KW - coordination polymers KW - crystal structures KW - metal-organic frameworks KW - carboxylate ligands KW - olefin paraffin separations KW - propyne KW - propylene KW - adsorption isotherms KW - dynamic breakthrough KW - n/a KW - Metal-organic framework UR - https://www.unicat.be/uniCat?func=search&query=sysid:134016875 AB - Metal organic frameworks (MOFs) are a class of porous materials with a modular structure. This allows for very wide structural diversity and the possibility of synthesizing materials with tailored properties for advanced applications. Thus, MOF materials are the subject of intense research, with strong relevance to both science and technology. MOFs are formed by the assembly of two components: cluster or metal ion nodes, which are also called secondary building units (SBUs), and organic linkers between the SBUs, usually giving rise to crystalline structures with an open framework and significant porous texture development. The main aim of this Special Issue of Catalysts (ISSN 2073-4344) is to present the most relevant and recent insights in the field of the synthesis and characterization of MOFs and MOF-based materials for advanced applications, including adsorption, gas storage/capture, drug delivery, catalysis, photocatalysis, and/or chemical sensing. ER -