From Metal-Organic Framework Powders to ...
Type de document :
Article dans une revue scientifique: Article de synthèse/Review paper
DOI :
URL permanente :
Titre :
From Metal-Organic Framework Powders to Shaped Solids: Recent Developments and Challenges
Auteur(s) :
Yeskendir, Bakytzhan [Auteur]
Dacquin, Jean-Philippe [Auteur]
Unité de Catalyse et de Chimie du Solide (UCCS) - UMR 8181
Lorgouilloux, Yannick [Auteur]
Courtois, Christian [Auteur]
royer, sebastien [Auteur]
Unité de Catalyse et de Chimie du Solide (UCCS) - UMR 8181
Dhainaut, Jérémy [Auteur]
Unité de Catalyse et de Chimie du Solide (UCCS) - UMR 8181
Dacquin, Jean-Philippe [Auteur]
Unité de Catalyse et de Chimie du Solide (UCCS) - UMR 8181
Lorgouilloux, Yannick [Auteur]
Courtois, Christian [Auteur]
royer, sebastien [Auteur]
Unité de Catalyse et de Chimie du Solide (UCCS) - UMR 8181
Dhainaut, Jérémy [Auteur]
Unité de Catalyse et de Chimie du Solide (UCCS) - UMR 8181
Titre de la revue :
Materials Advances
Nom court de la revue :
Mater. Adv.
Éditeur :
Royal Society of Chemistry (RSC)
Date de publication :
2021
ISSN :
2633-5409
Résumé en anglais : [en]
Metal-organic frameworks represent a class of porous materials which developed
considerably over the past few years. Their highly porous structure makes them
outperforming conventional adsorbents in hot topics such as ...
Lire la suite >Metal-organic frameworks represent a class of porous materials which developed considerably over the past few years. Their highly porous structure makes them outperforming conventional adsorbents in hot topics such as dihydrogen and methane storage, and carbon dioxide capture. Their consequent modularity, based on the assembly of organic linkers and metal ions or clusters, also brings novel perspectives in catalysis, sensing and drug delivery just to name a few. However, one of the main bottlenecks to their broader use remains their shaping. Especially, shaped materials should present a long-term mechanical stability as well as preservation of the physical and chemical properties. This makes shaping of MOFs a special case as their thermal and chemical stabilities remain a downside as compared to other traditional porous materials such as silicas and zeolites today. Therefore, an over-increasing effort has been devoted to the shaping of these materials. In this review, the state of the art for the preparation of shaped 3D MOF-based materials is presented. Emphasis will be given to the final physical and chemical properties of the shaped solids comparatively to the initial powders, when data are available. In the first part, traditional techniques based on applying a significant force to MOF-based powders will be reviewed. These include pelletization, granulation, extrusion which generally lead to an increase of the final volumetric gas uptake of the objects. At the same time, advantages and disadvantages of each technique will be discussed as well as the main outcome on the final objects. In the second part, focus will be given on the newly-emerging techniques such as 3D printing and spray drying. The former also maximizes the volumetric gas uptake of the final materials and for both techniques the quality of the final objects heavily rely on the working parameters. Finally, the third part will include the so-called “phase separation” shaping techniques which are for the most part performed without using special techniques. This implies shaping via physical and chemical phenomena such as sublimation or precipitation. Subsequently, a discussion will be proposed on the performance of these materials for adsorption-based applications. Finally, perspectives and future outlook will be discussed.Lire moins >
Lire la suite >Metal-organic frameworks represent a class of porous materials which developed considerably over the past few years. Their highly porous structure makes them outperforming conventional adsorbents in hot topics such as dihydrogen and methane storage, and carbon dioxide capture. Their consequent modularity, based on the assembly of organic linkers and metal ions or clusters, also brings novel perspectives in catalysis, sensing and drug delivery just to name a few. However, one of the main bottlenecks to their broader use remains their shaping. Especially, shaped materials should present a long-term mechanical stability as well as preservation of the physical and chemical properties. This makes shaping of MOFs a special case as their thermal and chemical stabilities remain a downside as compared to other traditional porous materials such as silicas and zeolites today. Therefore, an over-increasing effort has been devoted to the shaping of these materials. In this review, the state of the art for the preparation of shaped 3D MOF-based materials is presented. Emphasis will be given to the final physical and chemical properties of the shaped solids comparatively to the initial powders, when data are available. In the first part, traditional techniques based on applying a significant force to MOF-based powders will be reviewed. These include pelletization, granulation, extrusion which generally lead to an increase of the final volumetric gas uptake of the objects. At the same time, advantages and disadvantages of each technique will be discussed as well as the main outcome on the final objects. In the second part, focus will be given on the newly-emerging techniques such as 3D printing and spray drying. The former also maximizes the volumetric gas uptake of the final materials and for both techniques the quality of the final objects heavily rely on the working parameters. Finally, the third part will include the so-called “phase separation” shaping techniques which are for the most part performed without using special techniques. This implies shaping via physical and chemical phenomena such as sublimation or precipitation. Subsequently, a discussion will be proposed on the performance of these materials for adsorption-based applications. Finally, perspectives and future outlook will be discussed.Lire moins >
Comité de lecture :
Oui
Audience :
Non spécifiée
Établissement(s) :
Université de Lille
CNRS
Centrale Lille
ENSCL
Univ. Artois
CNRS
Centrale Lille
ENSCL
Univ. Artois
Collections :
Équipe(s) de recherche :
Matériaux pour la catalyse (MATCAT)
Date de dépôt :
2021-10-05T07:53:05Z
Fichiers
- D1MA00630D.pdf
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- Accès libre
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