A Ligand Field Molecular Mechanics Study of CO2‐Induced Breathing in the Metal–Organic Framework DUT‐8(Ni)

Melix, Patrick; Paesani, Francesco; Heine, Thomas

doi:10.1002/adts.201900098

Cited by 12 publications

(24 citation statements)

References 39 publications

(74 reference statements)

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“…Out of 28 simulations, 16 end up in a diamond-shaped and 12 in a disturbed diamond-shaped closed pore form, independent of the conformation and the system size. The observation of differently shaped closed pore forms agrees with already reported deviations from the perfect periodic image [31]. The DUT-8 NCs show an equivalent number of different closed pore forms as the DMOF-1 model system.…”

Section: Application To Breathing Mofs: Dut-128 and Dut-8supporting

confidence: 90%

Molecular Dynamics Simulations of the Breathing Phase Transition of MOF Nanocrystallites II: Explicitly Modeling the Pressure Medium

Schaper

Keupp

Schmid

2021

Preprint

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One of the most investigated properties of porous crystalline metal-organic frameworks (MOFs) is their potential flexibility to undergo large changes in unit cell size upon guest adsorption or other stimuli, referred to as "breathing". Computationally, such phase transitions are usually investigated using periodic boundary conditions, where the system's volume can be controlled directly. However, we have recently shown that important aspects like the formation of a moving interface between the open and the closed pore form or the free energy barrier of the first-order phase transition and its size effects can best be investigated using non-periodic nanocrystallite (NC) models [Keupp and Schmid (2019) Adv. Theory Simul. 2, 1900117]. In this case, the application of pressure is not straightforward, and a distance constraint was used to mimic a mechanical strain enforcing the reaction coordinate. In contrast to this prior work, a mediating particle bath is used here to exert an isotropic hydrostatic pressure on the MOF nanocrystallites. The approach is inspired by the mercury nanoporosimetry used to compress flexible MOF powders. For such a mediating medium, parameters are presented that require a reasonable additional numerical effort and avoid unwanted diffusion of bath particles into the MOF pores. As a proof-of-concept, NCs of pillared-layer MOFs with different linkers and sizes are studied concerning their response to external pressure exerted by the bath. By this approach, an isotropic pressure on the NC can be applied in analogy to corresponding periodic simulations, without any bias for a specific mechanism. This allows a more realistic investigation of the breathing phase transformation of a MOF NC and further bridges the gap between experiment and simulation.

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Section: Application To Breathing Mofs: Dut-128 and Dut-8supporting

confidence: 90%

Molecular Dynamics Simulations of the Breathing Phase Transition of MOF Nanocrystallites II: Explicitly Modeling the Pressure Medium

Schaper

Keupp

Schmid

2021

Preprint

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“…We recently presented the possibility to perform molecular dynamics (MD) simulations of DUT8-(Ni) by employing Ligand Field Molecular Mechanics (LFMM) for the description of the metal nodes. 25 Alzahrani and Deeth lately also confirmed the applicability of LFMM for the description of flexibility in MOFs. 29 Experimental adsorption energies of chlorinated methanes (CH x Cl 4-x , x = 0 to 3) in DUT-8(Ni) (−25 to −40 , −35 to −50 , −30 to −40 and −20 to −40 kJ mol −1 for CCl 4 to CH 3 Cl respectively, see Figure 2b) 26,30 suggest, in agreement with chemical intuition, a significant impact of the guest's dipole moment on the adsorption energy.…”

Section: Introductionmentioning

confidence: 78%

“…A thoroughly investigated representative of breathing flexible Metal-Organic Frameworks (MOFs), [1][2][3][4][5][6] sometimes also referred to as thirdgeneration MOFs, 7-9 is the layered pillar MOF Ni 2 (ndc) 2 (dabco) (ndc = 2,6-naphthalene-dicarboxylate, dabco = 1,4-diazabicyclo-[2.2.2]octane), also known as DUT-8(Ni). [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27] It consists of layers of Ni 2 (COO) 4 paddle wheel nodes interconnected by ndc linkers (Figure 1). The so formed layers are interconnected in the third dimension by dabco pillars (right side of Figure 1).…”

Section: Introductionmentioning

confidence: 99%

London Dispersion Governs the Interaction Mechanism of Small Polar and Non-Polar Molecules in Metal-Organic Frameworks

Melix¹,

Heine

2020

Preprint

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<div>In this work we investigate the adsorption of chlorinated methanes (CHxCl4-x, x=0-4) in a representative layer-pillar Metal-Organic Framework (MOF), the flexible MOF Ni2(ndc)2(dabco) (ndc = 2,6-naphthalene-dicarboxylate, dabco = 1,4-diazabicyclo-[2.2.2]-octane), also known as DUT-8(Ni). The guest molecules show a systematic increase of polarizability with increasing number of chlorine atoms, while the dipole moment exceeds 2 Debye for x = 2 and 3. Our ligand field molecular mechanics (LFMM) simulations show that, counter-intuitively, the host-guest interactions are mainly characterized by London dispersion, despite the molecular dipole moments reaching magnitudes as large as water. This highlights the importance of London dispersion interactions in the description of host-guest interactions. </div>

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“…The studies of gas adsorption in breathing materials remain dominated by molecular simulation at present. 60 Hence, DFT calculations were performed to support the unusual adsorption behavior (Figures 6e and 6f). Upon visible light irradiation, the binding energy of NUT-101 adsorbing CO 2 is negative, suggesting that the CO 2 molecule can be captured within the cage (Supporting Information Table S4).…”

Section: Adsorption Performancementioning

confidence: 99%

Breathing Metal–Organic Polyhedra Controlled by Light for Carbon Dioxide Capture and Liberation

Jiang

Tan

et al. 2021

CCS Chem

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Metal-organic polyhedra (MOPs) have emerged as versatile platforms for artificial models of biological systems due to their discrete structure and modular nature. However, the design and fabrication of MOPs with special functionality for mimicking biological processes are challenging. Inspired by the breathing mechanism of lungs, we developed a new type of MOP (a breathing MOP, denoted as NUT-101) by directly using azobenzene units as the pillars of the polyhedra to coordinate with Zr-based metal clusters. In addition to considerable thermal and chemical stability, the obtained MOP exhibits photocontrollable breathing behavior. Upon irradiation with visible or UV light, the configuration of azobenzene units transforms, leading to reversible expansion or contraction of the cages and, correspondingly, capture or liberation of CO 2 molecules. Such a breathing behavior of NUT-101 is further confirmed by density functional theory (DFT) calculation. This system might establish an avenue for the construction of new materials with particular functionality that mimic biological processes.

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A Ligand Field Molecular Mechanics Study of CO₂‐Induced Breathing in the Metal–Organic Framework DUT‐8(Ni)

Cited by 12 publications

References 39 publications

Molecular Dynamics Simulations of the Breathing Phase Transition of MOF Nanocrystallites II: Explicitly Modeling the Pressure Medium

Molecular Dynamics Simulations of the Breathing Phase Transition of MOF Nanocrystallites II: Explicitly Modeling the Pressure Medium

London Dispersion Governs the Interaction Mechanism of Small Polar and Non-Polar Molecules in Metal-Organic Frameworks

Breathing Metal–Organic Polyhedra Controlled by Light for Carbon Dioxide Capture and Liberation

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