Περίληψη:
Metal–organic frameworks (MOFs) could be utilized for a wide range of applications such as sorption, catalysis, chromatography, energy storage, sensors, drug delivery, and nonlinear optics. However, to date, there are very few examples of MOFs exploited on a commercial scale. Nevertheless, progress in MOF-related research is currently paving the way to new industrial opportunities, fostering applications and processes interconnecting fundamental chemistry with engineering and relevant sectors. Yet, the fabrication of porous MOF materials within resistant structures is a key challenge impeding their wide commercial use for processes such as adsorptive separation. In fact, the integration of nano-scale MOF crystallic structures into bulk components that can maintain the desired characteristics, i.e., size, shape, and mechanical stability, is a prerequisite for their wide practical use in many applications. At the same time, it requires sophisticated shaping techniques that can structure nano/micro-crystalline fine powders of MOFs into diverse types of macroscopic bodies such as monoliths. Under this framework, this review aims to bridge the gap between research advances and industrial necessities for fostering MOF applications into real life. Therefore, it critically explores recent advances in the shaping and production of MOF macro structures with regard to the binding materials that have received little attention to date, but have the potential to give new perspectives in the industrial applicability of MOFs. Moreover, it proposes future paths that can be adopted from both academy and industry and can further boost MOF exploitation. © 2022 by the authors. Licensee MDPI, Basel, Switzerland.
Συγγραφείς:
Ntouros, V.
Kousis, I.
Pisello, A.L.
Assimakopoulos, M.N.
Λέξεις-κλειδιά:
Binding energy; Chromatography; Industrial research; Mechanical stability; Nanotechnology; Nonlinear optics, As sorption; Binding materials; Inorganic binders; Metalorganic frameworks (MOFs); Monolith; Polymer binders; Porous metal; Real-life applications; Shape engineering; Shaping process, Drug delivery
