Statistical mechanical model of gas adsorption in porous crystals with dynamic moieties

Simon, Cory; Braun, Efrem; Carraro, Carlo; Smit, Berend

doi:10.1073/pnas.1613874114

Cited by 43 publications

(33 citation statements)

References 76 publications

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“…64 Lastly, the presence of dynamic moieties within a porous crystal may lead to phenomena resembling CA behavior. 65 Case V: Dissociative Adsorption DA…”

Section: Case Iv: Cooperative Adsorption Camentioning

confidence: 99%

Langmuir’s Theory of Adsorption: A Centennial Review

2019

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The 100 th anniversary of Langmuir's theory of adsorption is a significant landmark for the physical chemistry and chemical engineering communities. Despite its simplicity, the Langmuir adsorption model captures the key physics of molecular interactions at interfaces and laid the foundation for further progress in understanding interfacial phenomena, developing new adsorbent materials, and designing engineering processes. The Langmuir model has had an exceptional impact on diverse fields within the chemical sciences ranging from chemical biology to materials science , an impact that became clearer with the development of modified adsorption theories and continues to be relevant today.

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“…64 Lastly, the presence of dynamic moieties within a porous crystal may lead to phenomena resembling CA behavior. 65 Case V: Dissociative Adsorption DA…”

Section: Case Iv: Cooperative Adsorption Camentioning

confidence: 99%

Langmuir’s Theory of Adsorption: A Centennial Review

2019

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“…We have previously reviewed matrix methods for the statistical mechanical treatment of onedimensional lattice fluids [50]. A recent study applying matrix methods to MOFs has been presented by Simon et al [51]. The osmotic partition function equation (2.1) can be written as the sum of the products of N factors (unit cells) given by [45].…”

Section: Transfer Matrix Treatment Of Binary Mixture Adsorption In Mementioning

confidence: 99%

Statistical mechanics of binary mixture adsorption in metal–organic frameworks in the osmotic ensemble

Dunne

Manos

2018

Phil. Trans. R. Soc. A.

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Although crucial for designing separation processes little is known experimentally about multi-component adsorption isotherms in comparison with pure single components. Very few binary mixture adsorption isotherms are to be found in the literature and information about isotherms over a wide range of gas-phase composition and mechanical pressures and temperature is lacking. Here, we present a quasi-one-dimensional statistical mechanical model of binary mixture adsorption in metal-organic frameworks (MOFs) treated exactly by a transfer matrix method in the osmotic ensemble. The experimental parameter space may be very complex and investigations into multi-component mixture adsorption may be guided by theoretical insights. The approach successfully models breathing structural transitions induced by adsorption giving a good account of the shape of adsorption isotherms of CO and CH adsorption in MIL-53(Al). Binary mixture isotherms and co-adsorption-phase diagrams are also calculated and found to give a good description of the experimental trends in these properties and because of the wide model parameter range which reproduces this behaviour suggests that this is generic to MOFs. Finally, a study is made of the influence of mechanical pressure on the shape of CO and CH adsorption isotherms in MIL-53(Al). Quite modest mechanical pressures can induce significant changes to isotherm shapes in MOFs with implications for binary mixture separation processes.This article is part of the theme issue 'Modern theoretical chemistry'.

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“…This last work, formulated at a mesoscopic scale, shows that the solid-fluid interaction can lead to a hysteresis of the adsorption strain isotherm. For nanoporous crystalline materials with rotatable ligands shared between neighboring cages, a statistical mechanical model that captures the coupling was developed [38], which includes energy penalization for the rotation of a ligand and an energy of an adsorbed molecule that depends on the rotation of the ligands: the model captures inflections, steps, and hysteresis.…”

Section: Modeling the Coupling Between Adsorption And Mechanicsmentioning

confidence: 99%

Coupling between adsorption and mechanics (and vice versa)

Vandamme

2019

Current Opinion in Chemical Engineering

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Adsorption can deform porous solids, and mechanical stresses or strains can impact the adsorption process: this mini-review is dedicated to this coupling. After introducing some frameworks used to predict adsorption-induced strains, the question of how important it is to take into account the impact of mechanics on the adsorption process is addressed. Finally, some specific complexities (e.g., of the microstructure, or of the mechanical behavior of the adsorbent) that the community aims at integrating into the prediction of adsorption-induced strains are addressed. 2. Some frameworks to predict adsorption-induced strains The discussion in this section is quite generic and disregards specific complexities of the material, which will be addressed later in the manuscript. A first pore-scale approach to predict adsorption-induced strains is a thermodynamic one, which consists in identifying the energy to minimize in the so-called osmotic ensemble, which is the right thermodynamic ensemble to address adsorption-induced deformations [4]. Through this approach, Ravikovitch and Neimark [5] first showed that adsorption induces a mechanical stress (sometimes

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Statistical mechanical model of gas adsorption in porous crystals with dynamic moieties

Cited by 43 publications

References 76 publications

Langmuir’s Theory of Adsorption: A Centennial Review

Langmuir’s Theory of Adsorption: A Centennial Review

Statistical mechanics of binary mixture adsorption in metal–organic frameworks in the osmotic ensemble

Coupling between adsorption and mechanics (and vice versa)

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