Hydrophobic Metal–Organic Frameworks

Jayaramulu, Kolleboyina; Geyer, Florian; Schneemann, Andreas; Kment, Štěpán; Otyepka, Michal; Zbořil, Radek; Vollmer, Doris; Fischer, Roland A.

doi:10.1002/adma.201900820

Cited by 161 publications

(124 citation statements)

References 224 publications

(316 reference statements)

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“…[14][15][16][17] Recently, superhydrophobic/ superoleophilic materials have gained special attention in oily wastewater purification driven by their unique surficial properties, which can allow oil to penetrate through but repel water out. [18][19][20][21][22][23] Hitherto, diverse methods have been developed to design superhydrophobic materials, according to models of wetting, [24][25][26][27] such as layer-by-layer method, [28,29] dip-coating route, [30][31][32] templates route, [33] spraycoating method, [34] and so on. [35][36][37] However, most existing superhydrophobic/superoleophilic materials can only remove oil from the water surface, preventing their applications in separating the heavy oil under the water.…”

Section: Doi: 101002/mame202000160mentioning

confidence: 99%

One‐Pot Route for Fe@Poly(styrene‐co‐divinylbenzene) Foam with Robust Physical/Chemical Stability and Remote Magnetic Driven Capacity for Oil Removal

Zhang

et al. 2020

Macro Materials & Eng

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Magnetic and superhydrophobic materials with robust physical/chemical stability for controllable and remote magnetic driven capacity for oil removal under harsh environments are meaningful for oil–water separation but still a challenge. Herein, an alternative strategy to address this challenge is demonstrated by decorating poly(styrene‐co‐divinylbenzene) (PSDVB) on Fe foam via one‐pot solvothermal method. Different from previous magnetic and superhydrophobic materials, Fe foam is chosen to replace Fe3O4 nanomaterials. Thus, complicated preparation procedures and the high cost for Fe3O4 nanomaterials can be avoided. Additionally, PSDVB coating provides the whole foam with robust physical/chemical stabilities: i) the surface wettability can be maintained after 50 abrasion cycles or exposed in humid air (relative humidity: 90%) for 14 days, and ii) the surface wettability does not change under different pH solutions (3 < pH < 12) or highly salty solution (NaCl 10 wt%) for 6 h. Besides, outstanding separation efficiency (>99.9%), high durability (>70 times), and excellent oil flux (16 963–75 156 L m−2 h−1) can be realized under gravity. Most importantly, the foam continuously removes oil from confine place (on water surface or under water) under magnetic driven force.

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Section: Doi: 101002/mame202000160mentioning

confidence: 99%

One‐Pot Route for Fe@Poly(styrene‐co‐divinylbenzene) Foam with Robust Physical/Chemical Stability and Remote Magnetic Driven Capacity for Oil Removal

Zhang

et al. 2020

Macro Materials & Eng

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“…The integrated attributions of the reported hydrophobic MOFs with respect to porosity, hydrophobicity and stability lead to great promise for this unique class of materials in diverse applications, including humid CO 2 capture, alcohol/water separation, pollutant removal from air or water, substrate‐selective catalysis, energy storage, anticorrosion coatings and self‐cleaning. Some excellent reviews about hydrophobic MOFs have been recently published . However, the goal of this contribution is to present a comprehensive review of the development and advancement of hydrophobic MOFs.…”

Section: Introductionmentioning

confidence: 99%

“…Some excellent reviews about hydrophobic MOFs have been recently published. [67][68][69][70] However, the goal of this contribution is to present a comprehensive review of the development and advancement of hydrophobic MOFs.In the following sections, the existing techniques for assessing the hydrophobicity of MOFs are first introduced, including the determination of crystal structure, water adsorption measurement, quantitative determination of the hydrophobicity index by the competitive breakthrough adsorption experiment of a hydrocarbon/water mixture, and water contact angle measurement. These measurements offer information about the extent of the hydrophobicity of MOFs at the internal pore surface or external crystal surface.…”

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confidence: 99%

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Hydrophobic Metal–Organic Frameworks: Assessment, Construction, and Diverse Applications

et al. 2020

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Tens of thousands of metal–organic frameworks (MOFs) have been developed in the past two decades, and only ≈100 of them have been demonstrated as porous and hydrophobic. These hydrophobic MOFs feature not only a rich structural variety, highly crystalline frameworks, and uniform micropores, but also a low affinity toward water and superior hydrolytic stability, which make them promising adsorbents for diverse applications, including humid CO2 capture, alcohol/water separation, pollutant removal from air or water, substrate‐selective catalysis, energy storage, anticorrosion, and self‐cleaning. Herein, the recent research advancements in hydrophobic MOFs are presented. The existing techniques for qualitatively or quantitatively assessing the hydrophobicity of MOFs are first introduced. The reported experimental methods for the preparation of hydrophobic MOFs are then categorized. The concept that hydrophobic MOFs normally synthesized from predesigned organic ligands can also be prepared by the postsynthetic modification of the internal pore surface and/or external crystal surface of hydrophilic or less hydrophobic MOFs is highlighted. Finally, an overview of the recent studies on hydrophobic MOFs for various applications is provided and suggests the high versatility of this unique class of materials for practical use as either adsorbents or nanomaterials.

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“…Other non-covalent interactions such as transition metal coordination, hydrophobic interaction and protein-protein interaction have been utilized to obtain hierarchical structures. Metal coordination is widely used to construct metal-organic frameworks (MOF) for their application in separation, storage, and catalysis [93][94][95][96] . Inspired by the assembly of synthetic organic hybrid crystals, Ferritin was applied as building blocks for the construction of metal-protein cage crystals due to its feasibility for genetically engineered symmetrical metal-ion binding site ( Figure 2.8 A).…”

Section: Assembly Of Virus-like-particles Into Superlattices Through mentioning

confidence: 99%

Controlling the Assembly of Protein Cages towards Functional Supramolecular Materials

Cao¹

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In natural as well as synthetic systems, supramolecular interactions plays a vital role in essential life processes, such as catalysis, 1 protein synthesis, 2 cell replication and differentiation, 3 as well as molecule transport and delivery. 4 These supramolecular interactions are reversible, stimuli responsive and dynamic. Understanding and modulating these interactions would thus offer an effective manner to control the organization of a range of complexes which would benefit their potential properties and applications. Protein cages such as viruses and bacterial nano-compartment are perfect examples of natural assemblies formed by such supramolecular interactions. 5-8 Recent years have witnessed an increasing attempt to understand the assembly process of virus-like particles, in that way using these capsid proteins to construct functional materials for various applications. 9, 10 More specifically, plant viruses, as an example, consist of capsid proteins which envelop their genome inside highly symmetric cages via both electrostatic interactions and hydrophobic interaction. Furthermore, these viruses are uniform in size and hollow, which allows the encapsulation of functional cargos. These hollow nanometer-sized protein structures provide a template for the study of host-guest interactions in confined space, which in theory should be different from bulk solution, in addition, the specific interactions parameters could also provide vital information of the physical microenvironment inside protein cages. The work described in this thesis combined supramolecular chemistry and physical virology, by studying host-guest interactions inside the cowpea chlorotic mottle virus (CCMV) capsid, and ultimately utilize these interactions to induce the self-assembly of virus-based protein into structures with control in multi dimension. Chapter 2 provides an overview of recently reported assembly of virus-like particles induced by supramolecular interactions, that have been used as nanocontainers, nanoreactors and nano-templates for inorganic or organic material synthesis. Furthermore, the assembly of protein cages via supramolecular interactions into highly ordered 2D and 3D superstructures is described.

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Hydrophobic Metal–Organic Frameworks

Cited by 161 publications

References 224 publications

One‐Pot Route for Fe@Poly(styrene‐co‐divinylbenzene) Foam with Robust Physical/Chemical Stability and Remote Magnetic Driven Capacity for Oil Removal

One‐Pot Route for Fe@Poly(styrene‐co‐divinylbenzene) Foam with Robust Physical/Chemical Stability and Remote Magnetic Driven Capacity for Oil Removal

Hydrophobic Metal–Organic Frameworks: Assessment, Construction, and Diverse Applications

Controlling the Assembly of Protein Cages towards Functional Supramolecular Materials

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