Luca Malfatti scite author profile

In this review we present a short overview of the main fields of application of mesoporous ordered films obtained via templating self-assembly. These materials, because of their very special properties such as high surface area, ordered porosity, versatile functionalization of the pore surface, have been widely used for developing advanced functional applications. Mesoporous ordered films have also shown a high capability of integration in current material processing technologies also taking advantage of the high flexibility of the synthesis. A surprisingly large variety of devices and applications have been developed so far which ranges from sensors to supercapacitors and biodevices. All these applications have in common the exploitation of ordered porosity on the mesoscale and in general a strong dependence on pore topology, the nature of the pore surface and pore accessibility has been demonstrated for most of the cases. Even if a high number of examples of applications have been reported still many more are expected to come in the near future.

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Applications of magnetic metal–organic framework composites

Riccò

et al. 2013

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The high and regular porosity of metal-organic frameworks (MOFs) provides exceptional properties suitable for technological applications. The increasing interest of the scientific community is based on the exploration of these advantageous properties for industrial applications. Pure MOFs are specifically designed to offer a huge surface area; such a high specific surface area has been explored and exploited for gas storage, separation, or catalysis in a variety of chemical processes. A different and promising scientific trend aims to combine MOFs with extrinsic functionalities such as functional nanoparticles; this strategy enables the preparation of new nanocomposite materials with unprecedented properties. An interesting case is offered by the synergic combination of magnetic particles with MOF crystals. In the resulting nanocomposite material, the adaptive functional responses can be triggered by an external magnetic field. In this context, different protocols have been developed for the efficient preparation of magnetic framework composites (MFCs), a class of materials that combines magnetic nano-or micro-particles with MOFs crystals. This application paper highlights the progress on MFCs for drug delivery, environmental control, catalysis, sensing and miniaturized device fabrication.Raffaele Ricco (1979) received his Master's degree in Chemistry (2004) and his PhD in Molecular Sciences (2008) from the University of Padua, Italy. He was a researcher at the CIVEN Association in Venice, Italy, from 2008 to 2012. He was appointed a post doctoral fellow position in Paolo Falcaro's group at the CSIRO Material Science and Engineering Division (Melbourne, Australia) in 2012. His main research topic deals with the synthesis of metal organic frameworks and their applications in sensing and catalysis.

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Luca Malfatti

Mesoporous thin films: properties and applications

Applications of magnetic metal–organic framework composites

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