Prediction of the Conditions for Breathing of Metal Organic Framework Materials Using a Combination of X-ray Powder Diffraction, Microcalorimetry, and Molecular Simulation

Llewellyn, Philip L.; Maurin, Guillaume; Devic, Thomas; Loera‐Serna, Sandra; Rosenbach, Nilton; Serre, Christian; Bourrelly, Sandrine; Horcajada, Patricia; Filinchuk, Yaroslav; Férey, Gérard

doi:10.1021/ja803899q

Cited by 248 publications

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“…1 The MIL-53 materials family, 2 a particularly eye-catching case of the last category, has attracted a lot of attention due to its large flexibility and the occurrence of a double structural transition upon adsorption of some gases (CO 2 , H 2 O, C 2 H 6 ,...) but not others (H 2 , CH 4 ). 3 It was also reported very recently 4 that liquid phase adsorption of para-xylene does induce a structural transition, while ortho-and meta-xylene do not. The studies performed so far, both experimentally and by molecular simulation, mainly focused on structural characterization and energetics (by calorimetry, forcefield-based calculations and DFT).…”

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confidence: 75%

“…8 We now turn to the issue of how the presence or absence of guest-induced structural transitions can be related to the properties of the guest molecule. New experimental data on the adsorption of various species in the pores of MIL-53 have been published very recently, in both gas phase (for C n H 2n+2 , n e 4) 3 and liquid phase (for o-, m-, and p-xylene). 4 In the case of materials such as MIL-53, where the large-pore (lp) form is intrinsically more stable than the narrow-pore (np) form at room temperature, our taxonomy predicts either the occurrence of two structural transitions upon gas adsorption or the absence of any transition.…”

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confidence: 99%

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Double Structural Transition in Hybrid Material MIL-53 upon Hydrocarbon Adsorption: The Thermodynamics Behind the Scenes

et al. 2009

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In this paper, we rationalize the thermodynamics behind the guest-induced structural transitions of hybrid material showing that the existence of a double transition depends on the relatiVe guest affinities for the two phases, rather than absolute adsorption enthalpies. Based on a simple model, we interpret recent experimental data on alkane adsorption and predict transition pressures.Porous metal-organic frameworks (MOFs) are a topical class of materials that display an extremely large range of crystal structures and host-guest properties, potentially giving them a major impact in adsorption, separation, and storage of strategic gases (H 2 , CO 2 , CH 4 ,...). A growing number of these materials show exceptional guest-responsive behaviors upon gas adsorption, due to the flexibility of their organic-inorganic frameworks. This includes examples of progressive swelling or contraction (also called breathing), pore deformation, and amorphous-to-crystal and crystalto-crystal structural transitions.1 The MIL-53 materials family, 2 a particularly eye-catching case of the last category, has attracted a lot of attention due to its large flexibility and the occurrence of a double structural transition upon adsorption of some gases (CO 2 , H 2 O, C 2 H 6 ,...) but not others (H 2 , CH 4 ).3 It was also reported very recently 4 that liquid phase adsorption of para-xylene does induce a structural transition, while ortho-and meta-xylene do not. The studies performed so far, both experimentally and by molecular simulation, mainly focused on structural characterization and energetics (by calorimetry, forcefield-based calculations and DFT). However, the current depiction of these guest-induced structural transitions is lacking a general thermodynamic interpretation of all the results obtained so far; Llewellyn et al. indeed highlighted the necessity of understanding "the thermodynamic conditions for the host-guest interactions which allow the breathing to happen". 3 We recently developed a generic thermodynamic framework for the understanding of guest-induced structural transitions in flexible nanoporous materials such as MOFs, 5 by use of the osmotic pseudoensemble. For a material that has two possible framework structures and where gas adsorption follows type I isotherms, 6 we proposed a full taxonomy of possible guest-induced structural transitions. This classification relies only on a few key parameters, such as the free energy difference, ∆F, between the (empty) host structures, their pore volumes, V p (i) , and the adsorption affinities for the guest, K i . This method also allows us to calculate one of these parameters when the pressures of structural transitions are known. The robustness of the method was demonstrated on systems exhibiting such contrasting behaviors as "breathing" and "gate opening". In the case of MIL-53 (Al), in particular, we used the available CO 2 adsorption isotherm to calculate a free energy difference between the empty large pore (lp, Figure 1S) and narrow pore (np, Figure 2S) forms of ∆F ≈ 2....

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Double Structural Transition in Hybrid Material MIL-53 upon Hydrocarbon Adsorption: The Thermodynamics Behind the Scenes

et al. 2009

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“…Many PICNICs exhibit hysteretic adsorption-desorption behavior which is often associated with the 'gate-opening' effect ( Figure 4). They also show dynamic host-guest behavior due to structural transitions which occur between the guest-free and guest-loaded states [78][79][80][81][82].…”

Section: Ni(cn) 4 -Based Mofs (Picnics)mentioning

confidence: 99%

Crystallography of Representative MOFs Based on Pillared Cyanonickelate (PICNIC) Architecture

2016

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Abstract:The pillared layer motif is a commonly used route to porous coordination polymers or metal organic frameworks (MOFs). Materials based on the pillared cyano-bridged architecture, [Ni'(L)Ni(CN) 4 ] n (L = pillar organic ligands), also known as PICNICs, have been shown to be especially diverse where pore size and pore functionality can be varied by the choice of pillar organic ligand. In addition, a number of PICNICs form soft porous structures that show reversible structure transitions during the adsorption and desorption of guests. The structural flexibility in these materials can be affected by relatively minor differences in ligand design, and the physical driving force for variations in host-guest behavior in these materials is still not known. One key to understanding this diversity is a detailed investigation of the crystal structures of both rigid and flexible PICNIC derivatives. This article gives a brief review of flexible MOFs. It also reports the crystal structures of five PICNICS from our laboratories including three 3-D porous frameworks (Ni-Bpene, NI-BpyMe, Ni-BpyNH2), one 2-D layer (Ni-Bpy), and one 1-D chain (Ni-Naph) compound. The sorption data of BpyMe for CO 2 , CH 4 and N 2 is described. The important role of NH 3 (from the solvent of crystallization) as blocking ligands which prevent the polymerization of the 1-D chains and 2-D layers to become 3D porous frameworks in the Ni-Bpy and Ni-Naph compounds is also addressed.

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“…Some MOFs can present structural flexibility or "breathing effects," which allows them to modulate their pore size upon adsorption of organic molecules into the pores, while their crystallinity is maintained [22,50,54,59]. One example of BioMOFs presenting a "breathing effect" is MIL-53 [22,54,100].…”

Section: Exploring the Potentialities Of The Breathing Effects On Biomentioning

confidence: 99%

“…Less toxic systems, using iron and more flexible MILs, are under study [25], and the first biodegradable therapeutic MOF, BioMIL-1, was reported by Miller et al in 2010 [27]. The large breathing effect that MOFs can attain is another particularly interesting feature for potential applications in drug delivery [54,59,52].…”

Section: Introductionmentioning

confidence: 99%

Bio-Inspired Metal-Organic Frameworks in the Pharmaceutical World: A Brief Review

André¹,

Quaresma²

2016

Metal-Organic Frameworks

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One of the great challenges in the pharmaceutical industry is the search for more efficient and cost-effective ways to store and deliver existing drugs. Bio-inspired metalorganic frameworks (BioMOFs) are groundbreaking materials that have recently been explored for drug storage, delivery and controlled release as well as for applications in imaging and sensing for therapeutic and diagnostic. This review presents a brief overview on these materials, and by alluding to a few reported examples, it intends to clearly show the extremely important role that BioMOFs have been playing in the pharmaceutical field.

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Prediction of the Conditions for Breathing of Metal Organic Framework Materials Using a Combination of X-ray Powder Diffraction, Microcalorimetry, and Molecular Simulation

Cited by 248 publications

References 38 publications

Double Structural Transition in Hybrid Material MIL-53 upon Hydrocarbon Adsorption: The Thermodynamics Behind the Scenes

Double Structural Transition in Hybrid Material MIL-53 upon Hydrocarbon Adsorption: The Thermodynamics Behind the Scenes

Crystallography of Representative MOFs Based on Pillared Cyanonickelate (PICNIC) Architecture

Bio-Inspired Metal-Organic Frameworks in the Pharmaceutical World: A Brief Review

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