Rostami Jowan, Benselfelt Tobias, Maddalena Lorenza, Avci Civan, Sellman Farhiya Alex, Cinar Ciftci Goksu, Larsson Per A, Carosio Federico, Akhtar Farid, Tian Weiqian, Wågberg Lars
Department of Fibre and Polymer Technology, Division of Fibre Technology, KTH Royal Institute of Technology, Stockholm, 11428, Sweden.
School of Materials Science and Engineering, Nanyang Technological University, Singapore, 639798, Singapore.
Adv Mater. 2022 Sep;34(38):e2204800. doi: 10.1002/adma.202204800. Epub 2022 Aug 16.
Metal-organic frameworks (MOFs) are hybrid porous crystalline networks with tunable chemical and structural properties. However, their excellent potential is limited in practical applications by their hard-to-shape powder form, making it challenging to assemble MOFs into macroscopic composites with mechanical integrity. While a binder matrix enables hybrid materials, such materials have a limited MOF content and thus limited functionality. To overcome this challenge, nanoMOFs are combined with tailored same-charge high-aspect-ratio cellulose nanofibrils (CNFs) to manufacture robust, wet-stable, and multifunctional MOF-based aerogels with 90 wt% nanoMOF loading. The porous aerogel architectures show excellent potential for practical applications such as efficient water purification, CO and CH gas adsorption and separation, and fire-safe insulation. Moreover, a one-step carbonization process enables these aerogels as effective structural energy-storage electrodes. This work exhibits the unique ability of high-aspect-ratio CNFs to bind large amounts of nanoMOFs in structured materials with outstanding mechanical integrity-a quality that is preserved even after carbonization. The demonstrated process is simple and fully discloses the intrinsic potential of the nanoMOFs, resulting in synergetic properties not found in the components alone, thus paving the way for MOFs in macroscopic multifunctional composites.
金属有机框架材料(MOFs)是具有可调节化学和结构性质的混合多孔晶体网络。然而,它们难以成型的粉末形式限制了其在实际应用中的卓越潜力,使得将MOFs组装成具有机械完整性的宏观复合材料具有挑战性。虽然粘合剂基质能够制成混合材料,但这类材料的MOF含量有限,因此功能也有限。为了克服这一挑战,将纳米MOFs与定制的同电荷高长径比纤维素纳米纤维(CNFs)相结合,以制造出具有90 wt%纳米MOF负载量的坚固、耐湿且多功能的MOF基气凝胶。这种多孔气凝胶结构在高效水净化、CO和CH气体吸附与分离以及防火隔热等实际应用中显示出卓越潜力。此外,一步碳化工艺使这些气凝胶能够成为有效的结构储能电极。这项工作展示了高长径比CNFs在具有出色机械完整性的结构化材料中结合大量纳米MOFs的独特能力——即使在碳化后这种品质依然得以保留。所展示的工艺简单,充分揭示了纳米MOFs的内在潜力,产生了单独成分中未发现的协同性能,从而为MOFs在宏观多功能复合材料中的应用铺平了道路。
