Jurn Heinen scite author profile

Some of the most remarkable recent developments in metal-organic framework (MOF) performance properties can only be rationalized by the mechanical properties endowed by their hybrid inorganic-organic nanoporous structures. While these characteristics create intriguing application prospects, the same attributes also present challenges that will need to be overcome to enable the integration of MOFs with technologies where these promising traits can be exploited. In this review, emerging opportunities and challenges are identified for MOF-enabled device functionality and technological applications that arise from their fascinating mechanical properties. This is discussed not only in the context of their more well-studied gas storage and separation applications, but also for instances where MOFs serve as components of functional nanodevices. Recent advances in understanding MOF mechanical structure-property relationships due to attributes such as defects and interpenetration are highlighted, and open questions related to state-of-the-art computational approaches for quantifying their mechanical properties are critically discussed.

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Polarizable Force Fields for CO₂and CH₄Adsorption in M-MOF-74

Becker

et al. 2017

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The family of M-MOF-74, with M = Co, Cr, Cu, Fe, Mg, Mn, Ni, Ti, V, and Zn, provides opportunities for numerous energy related gas separation applications. The pore structure of M-MOF-74 exhibits a high internal surface area and an exceptionally large adsorption capacity. The chemical environment of the adsorbate molecule in M-MOF-74 can be tuned by exchanging the metal ion incorporated in the structure. To optimize materials for a given separation process, insights into how the choice of the metal ion affects the interaction strength with adsorbate molecules and how to model these interactions are essential. Here, we quantitatively highlight the importance of polarization by comparing the proposed polarizable force field to orbital interaction energies from DFT calculations. Adsorption isotherms and heats of adsorption are computed for CO2, CH4, and their mixtures in M-MOF-74 with all 10 metal ions. The results are compared to experimental data, and to previous simulation results using nonpolarizable force fields derived from quantum mechanics. To the best of our knowledge, the developed polarizable force field is the only one so far trying to cover such a large set of possible metal ions. For the majority of metal ions, our simulations are in good agreement with experiments, demonstrating the effectiveness of our polarizable potential and the transferability of the adopted approach.

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Negative Thermal Expansion Design Strategies in a Diverse Series of Metal–Organic Frameworks

Burtch

Baxter

Heinen

et al. 2019

Adv Funct Materials

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Negative thermal expansion materials are of interest for an array of composite material applications whereby they can compensate for the behavior of a positive thermal expansion matrix. In this work, various design strategies for systematically tuning the coefficient of thermal expansion in a diverse series of metal-organic frameworks (MOFs) are demonstrated. By independently varying the metal, ligand, topology, and guest environment of representative MOFs, a range of negative and positive thermal expansion behaviors are experimentally achieved. Insights into the origin of these behaviors are obtained through an analysis of synchrotron-radiation total scattering and diffraction experiments, as well as complementary molecular simulations. The implications of these findings on the prospects for MOFs as an emergent negative thermal expansion material class are also discussed.

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On flexible force fields for metal–organic frameworks: Recent developments and future prospects

Heinen

Dubbeldam

2018

WIREs Comput Mol Sci

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Classical force field simulations can be used to study structural, diffusion, and adsorption properties of metal–organic frameworks (MOFs). To account for the dynamic behavior of the material, parameterization schemes have been developed to derive force constants and the associated reference values by fitting on ab initio energies, vibrational frequencies, and elastic constants. Here, we review recent developments in flexible force field models for MOFs. Existing flexible force field models are generally able to reproduce the majority of experimentally observed structural and dynamic properties of MOFs. The lack of efficient sampling schemes for capturing stimuli‐driven phase transitions, however, currently limits the full predictive potential of existing flexible force fields from being realized.This article is categorized under: Structure and Mechanism > Computational Materials ScienceMolecular and Statistical Mechanics > Molecular Mechanics

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In situ visualization of loading-dependent water effects in a stable metal–organic framework

et al. 2019

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Jurn Heinen

Mechanical Properties in Metal–Organic Frameworks: Emerging Opportunities and Challenges for Device Functionality and Technological Applications

Polarizable Force Fields for CO₂and CH₄Adsorption in M-MOF-74

Negative Thermal Expansion Design Strategies in a Diverse Series of Metal–Organic Frameworks

On flexible force fields for metal–organic frameworks: Recent developments and future prospects

In situ visualization of loading-dependent water effects in a stable metal–organic framework

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Resources

About

Jurn Heinen

Mechanical Properties in Metal–Organic Frameworks: Emerging Opportunities and Challenges for Device Functionality and Technological Applications

Polarizable Force Fields for CO2and CH4Adsorption in M-MOF-74

Negative Thermal Expansion Design Strategies in a Diverse Series of Metal–Organic Frameworks

On flexible force fields for metal–organic frameworks: Recent developments and future prospects

In situ visualization of loading-dependent water effects in a stable metal–organic framework

Contact Info

Product

Resources

About

Polarizable Force Fields for CO₂and CH₄Adsorption in M-MOF-74