Tunable molecular separation by nanoporous membranes

Wang, Zhengbang; Knebel, Alexander; Grosjean, Sylvain; Wagner, Danny; Bräse, Stefan; Wöll, Christof; Caro, Jürgen; Heinke, Lars

doi:10.1038/ncomms13872

Cited by 220 publications

(227 citation statements)

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“…[47] The length of these linkers used in fabricating the MOF has to be adjusted so that the transition from the trans to the cis conformation is not hindered. [50,53] Copyright 2014 and 2016, American Chemical Society and Nature Publishing Group. Alternatively to the controlled incorporation of the photoswitches as dangling side groups to the MOF structure, the light-responsive mole cules may also be embedded in the pores, resulting in straightforward preparation of photoswitchable nanoporous materials.…”

Section: Photoswitchable Nanoporous Coatingmentioning

confidence: 99%

“…[53] In these membranes, the separation selectivities could be varied over a wide range by illumination with light (Figure 6c). Due to their large variety and the ability to adjust their functionalization and pore size by modification of the building units, MOFs are promising materials for efficient membrane separation.…”

Section: Dynamic Remote-control Over the Membrane Permeation And Sepamentioning

confidence: 99%

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Surface‐Mounted Metal–Organic Frameworks: Crystalline and Porous Molecular Assemblies for Fundamental Insights and Advanced Applications

2019

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with open voids attract significant interest, not only for use in gas storage and separation applications, [1b] but also as model systems used for fundamental investigations on molecular interactions. After being introduced about two decades ago, [2] this new type of crystalline coordination network created considerable excitement and much effort was devoted toward the discovery of new types of these compounds. In early 2017, after 20 years of intense research, the literature contains reports on more than 70 000 structurally characterized examples of this class. [3] Since MOFs can be assembled by combining molecular building blocks, specifically ditopic or higher-topic organic linkers and metal or metal-oxo nodes, a virtually unlimited number of structures can be realized. Moreover, essentially every organic molecule can be modified by the addition of appropriate coupling groups, e.g., carboxylic acid groups or pyridine units, to yield a ditopic linker. Therefore, the number of possible MOF structures is far greater than the number of known structures. In line with this consideration, more than a million of these compounds have been simulated using combinatorial approaches. [4] As MOFs are both crystalline and porous, they have fascinating and often surprising properties. Not only does the immense chemical space spanned by these compounds create enormous potential for advancing materials science, it also provides ideal matrices for reference experiments exploring fundamental spectroscopic and physicochemical properties. The framework provides a well-defined, crystalline, porous environment that can host guest molecules, thus permitting systematic spectroscopic investigations. In contrast to solvents or polymer matrices, MOFs provide a strictly periodic, very well defined structural framework, where the molecular environment is identical for each embedded guest molecule. In this respect, MOFs outperform amorphous noble-gas guest matrices [5] in which the environment surrounding varies from site to site, leading to inhomogeneous broadening of the embedded guest's spectroscopic features, including vibrational bands.Herein, we discuss the use of MOFs and, in particular, of surface-mounted metal-organic frameworks (SURMOFs), to provide well-defined environments for precisely determining Metal-organic frameworks (MOFs) are crystalline coordination polymers, assembled from inorganic nodes connected by organic linker molecules. An enormous surface area, huge compositional variety, regular structure, and favorable mechanical properties are among their outstanding properties. Monolithic MOF thin films, i.e., surface-mounted metalorganic frameworks (SURMOFs), with high degree of structural order and adjustable defect density, can be prepared on solid substrates using layer-by-layer techniques. Recent studies where SURMOFs served as model systems for quantitative studies of molecular interactions in porous media, including diffusion, are reviewed. Moreover, SURMOFs are ideally suited for the incorporation of photoactive mo...

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Section: Photoswitchable Nanoporous Coatingmentioning

confidence: 99%

Section: Dynamic Remote-control Over the Membrane Permeation And Sepamentioning

confidence: 99%

Surface‐Mounted Metal–Organic Frameworks: Crystalline and Porous Molecular Assemblies for Fundamental Insights and Advanced Applications

2019

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“…E.g. Wang et al [31] recently showed that continuous tuning of the separation ratio was possible by embedding a nanostructured metalorganic framework (MOF), assembled from a photoresponsive organic molecule, in a nanoporous membrane. 2 .…”

Section: Current Technologies For Comentioning

confidence: 99%

The Virtuous CO₂ Circle or the Three Cs: Capture, Cache, and Convert

Bocchini

Castro²,

Cocuzza

et al. 2017

Journal of Nanomaterials

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It is not the first time in human history, nor will it be the last for that matter, that a collective problem calls for a collective response. Climate change fueled by greenhouse emissions affects humankind alike. Despite the disagreement among policymakers and scientists on the severity of the issue, the truth is that the problem remains. A broad look at different technologies being used today in different fields has led to the idea of bringing them together in an attempt to offer a viable solution to reducing anthropogenic CO 2 . The following paper describes how the nanotechnologies, available or soon to be available, would make CO 2 capture, cache, and conversion (coined the three Cs) a valid way for achieving a more sustainable energy society. Authors also set out to highlight with this work how knowledge transfer is instrumental in the development of technology and how methodical assessment of crossovers can expedite research when time plays against us.

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“…It was demonstrated that SURMOFs with azobenzene side groups can be used for various Brought to you by | MIT Libraries Authenticated Download Date | 5/11/18 10:18 PM purposes: as membranes which allow the remote-controlled switching of the separation performance [24], for the remote-controlled release of guest molecules from multi-layered nanoporous films [25] as well as for switching the adsorption capacity [26]. Using fluorinated azobenzene side groups enables the switching of the MOF material properties with visible light only, avoiding UV light [27].…”

Section: Introductionmentioning

confidence: 99%

Thermal cis-to-trans Isomerization of Azobenzene Side Groups in Metal-Organic Frameworks investigated by Localized Surface Plasmon Resonance Spectroscopy

Zhou

Grosjean

Bräse

et al. 2018

Zeitschrift Für Physikalische Chemie

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Abstract:The energy barrier for cis-to-trans isomerization is among the key parameters for photoswitchable molecules such as azobenzene. Recently, we introduced a well-defined model system based on thin films of crystalline, nanoporous metal-organic frameworks, MOFs. The system enables the precise investigation of the thermal cis-to-trans relaxation of virtually isolated azobenzene pendant groups by means of infrared spectroscopy in vacuum. Here, this approach is extended by using localized surface plasmon resonance spectroscopy. This simple and relatively inexpensive setup enables the investigation of the thermal cis-to-trans isomerization in different environments, here in argon gas or in liquid butanediol. The energy barrier for the cis-to-trans-relaxation in argon, 1.17 ± 0.20 eV, is identical to the barrier in vacuum, while the energy barrier in liquid butanediol is slightly larger, 1.26 ± 0.15 eV.

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Tunable molecular separation by nanoporous membranes

Cited by 220 publications

References 53 publications

Surface‐Mounted Metal–Organic Frameworks: Crystalline and Porous Molecular Assemblies for Fundamental Insights and Advanced Applications

Surface‐Mounted Metal–Organic Frameworks: Crystalline and Porous Molecular Assemblies for Fundamental Insights and Advanced Applications

The Virtuous CO₂ Circle or the Three Cs: Capture, Cache, and Convert

Thermal cis-to-trans Isomerization of Azobenzene Side Groups in Metal-Organic Frameworks investigated by Localized Surface Plasmon Resonance Spectroscopy

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Tunable molecular separation by nanoporous membranes

Cited by 220 publications

References 53 publications

Surface‐Mounted Metal–Organic Frameworks: Crystalline and Porous Molecular Assemblies for Fundamental Insights and Advanced Applications

Surface‐Mounted Metal–Organic Frameworks: Crystalline and Porous Molecular Assemblies for Fundamental Insights and Advanced Applications

The Virtuous CO2 Circle or the Three Cs: Capture, Cache, and Convert

Thermal cis-to-trans Isomerization of Azobenzene Side Groups in Metal-Organic Frameworks investigated by Localized Surface Plasmon Resonance Spectroscopy

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Product

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The Virtuous CO₂ Circle or the Three Cs: Capture, Cache, and Convert