Extension of the QuickFF force field protocol for an improved accuracy of structural, vibrational, mechanical and thermal properties of metal–organic frameworks

Vanduyfhuys, Louis; Vandenbrande, Steven; Wieme, Jelle; Waroquier, Michel; Verstraelen, Toon; Speybroeck, Véronique Van

doi:10.1002/jcc.25173

Cited by 67 publications

(93 citation statements)

References 75 publications

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“…[460] The QuickFF force field protocol was extended for an improved accuracy of structural, vibrational, mechanical, and thermal properties of metal-organic frameworks like IRMOF-1, MIL-53(Al), CAU-13, and NOTT-300. [461] UFF4MOF [462,463] is an extension of the original Universal force field UFF (UFF) that incorporates additional atom types found in the Computation-Ready Experimental (CoRE) Database. [464] The BTW-FF model is a transferable inter-atomic potential that can be applied to MOFs regardless of metal or ligand identity.…”

Section: Mof Force Fieldsmentioning

confidence: 99%

Design, Parameterization, and Implementation of Atomic Force Fields for Adsorption in Nanoporous Materials

Dubbeldam

Walton

Vlugt

et al. 2019

Advcd Theory and Sims

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Molecular simulations are an excellent tool to study adsorption and diffusion in nanoporous materials. Examples of nanoporous materials are zeolites, carbon nanotubes, clays, metal-organic frameworks (MOFs), covalent organic frameworks (COFs) and zeolitic imidazolate frameworks (ZIFs). The molecular confinement these materials offer has been exploited in adsorption and catalysis for almost 50 years. Molecular simulations have provided understanding of the underlying shape selectivity, and adsorption and diffusion effects. Much of the reliability of the modeling predictions depends on the accuracy and transferability of the force field. However, flexibility and the chemical and structural diversity of MOFs add significant challenges for engineering force fields that are able to reproduce experimentally observed structural and dynamic properties. Recent developments in design, parameterization, and implementation of force fields for MOFs and zeolites are reviewed.contain silicon and oxygen. They are readily available, very stable, and relatively cheap. The material should have the right combination of high adsorption selectivity, combined with adequate capacity for use in fixed-bed devices. Recently, new classes of nanoporous materials have been designed that have stability, high void volumes, and well defined tailorable cavities of uniform size. Example are metal-organic frameworks (MOFs), [1][2][3][4][5][6][7] covalent organic frameworks (COFs), [8,9] and zeolitic imidazolate frameworks (ZIFs). [10] These novel materials posses almost unlimited structural variety because of the many combinations of building blocks that can be imagined. The building blocks self-assembly during synthesis into crystalline materials that, after evacuation of the structure, can find applications in adsorption separations, air purification, gas storage, chemical sensing, and catalysis. [4,11] The judicious selection of building blocks allows the pore volume and functionality to be tailored in a rational manner. Because of the designprinciple underlying the synthesis, it is important to understand structure-properties relations, such as the mechanisms of gas separation as a function of shape and size of the pore system, in order to create "blueprints to MOF-design." Computer simulation is cost-effective, fast, and allows for rapid identification of important structural parameters affecting adsorption.Most of the published works on molecular simulation studying zeolites have used the Kiselev model. [12] In this model, zeolite atoms are fixed and interactions of guest atoms with silicon atoms is accounted for by an effective interaction only with the surrounding oxygen atoms. Interactions between sorbate molecules and the host are modeled by placing Lennard-Jones sites and partial charges on all framework atoms and sorbate molecules. The Kiselev model is attractive because of its simplicity and computational efficiency. This model has shown significant success, both in using the molecular dynamics method to compute, for example, the diffu...

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Section: Mof Force Fieldsmentioning

confidence: 99%

Design, Parameterization, and Implementation of Atomic Force Fields for Adsorption in Nanoporous Materials

Dubbeldam

Walton

Vlugt

et al. 2019

Advcd Theory and Sims

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“…To extend our predictions towards experimental conditions at higher temperature, we performed force eld MD simulations as described in the Methods section on DMOF-1(Zn) with a new QuickFF force eld 72,73 The Helmholtz free energy proles are shown in Fig. 4.…”

Section: Molecular-level Characterization Of the Phase Transition At mentioning

confidence: 99%

Pillared-layered metal–organic frameworks for mechanical energy storage applications

et al. 2019

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“…The thermodynamic model requires input profiles for the empty host material (F host (V)), pore volume (V p (V)) and interaction energy (ΔU(V)) as well as van der Waals a and b parameters. For DUT-49, F host (V) was constructed with a newly developed force field using QuickFF 38,39 (more details can be found in Supplementary Note 3), ΔU(V) was computed by means of the Monte Carlo scheme outlined in ref. 37 using the Universal Force Field 40 for the van der Waals interactions and atomic charges derived using the Minimal Basis Iterative Stockholder (MBIS) method 41 to model the electrostatic interactions, and the pore volume was fitted to the experimental measurements from ref.…”

Section: Methodsmentioning

confidence: 99%

“…For MIL-53(Al) the free energy of the empty host was constructed using a QuickFF force field taken from ref. 39 , while the profiles for the adsorption energy and pore volume were computed using the scheme of ref. 37 with the same force field that was applied for the computation of the free energy profile (augmented with the MM3 parameters and MBIS gaussian charges for methane and carbon dioxide).…”

Section: Methodsmentioning

confidence: 99%

Unraveling the thermodynamic conditions for negative gas adsorption in soft porous crystals

Vanduyfhuys

Speybroeck

2019

Commun Phys

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Soft porous crystals (SPCs) are widely known for their intriguing properties and various counterintuitive phenomena such as negative linear compression, negative thermal expansion and negative gas adsorption (NGA). An intriguing case is the adsorption of methane in DUT-49 for which experimentally a drop in the amount of adsorbed particles was observed under increasing vapor pressure. It is yet unknown which specific systems can exhibit NGA under which thermodynamic conditions. Herein, a semi-analytical thermodynamic model is applied to determine the conditions required for NGA, including their sensitivity towards various system-specific parameters, and investigate the correlation with pressure-induced breathing. As such, it is found that certain non-breathing materials may exhibit breathing with NGA under application of a fixed mechanical pressure. Such meticulous control of multiple triggers for NGA can open the way to new applications such as tunable gas detection and pressure amplification.

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Extension of the QuickFF force field protocol for an improved accuracy of structural, vibrational, mechanical and thermal properties of metal–organic frameworks

Cited by 67 publications

References 75 publications

Design, Parameterization, and Implementation of Atomic Force Fields for Adsorption in Nanoporous Materials

Design, Parameterization, and Implementation of Atomic Force Fields for Adsorption in Nanoporous Materials

Pillared-layered metal–organic frameworks for mechanical energy storage applications

Unraveling the thermodynamic conditions for negative gas adsorption in soft porous crystals

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