Your search keyword '"Snurr, Randall Q."' showing total 9 results

1. Machine learning heat capacities.

Author

Snurr RQ

Subjects

Hot Temperature, Machine Learning

Published

2022

2. Molecular Simulations of the Chain Length Dependent Adsorption of C7‐C14 n‐Alkanes in ZIF‐8.

Author

Gopalan, Arun and Snurr, Randall Q.

Subjects

*SCIENTIFIC computing, *ADSORPTION isotherms, *ADSORPTION (Chemistry), *ALKANES, *IMAGE processing, *DIFFUSION coatings

Abstract

Recent experiments show that the diffusivities of C8 and C10 n‐alkanes in ZIF‐8 are higher than those of C7 and C9, respectively. We investigated this unusual 'odd‐even' effect by simulating the adsorption of C7‐C14 n‐alkanes in ZIF‐8 using hybrid Monte Carlo molecular simulations. The resultant adsorption isotherms, guest‐host energies, isosteric heats, and chain length distributions are analyzed for trends among the n‐alkanes. ZIF‐8 cages filled with n‐alkanes are characterized using a combination of image processing and data science to quantify the differences in packing that occur with chain length. Results indicate that packing changes drastically from C7 to C8 and from C9 to C10, which is consistent with the diffusion trends previously reported in experiments. [ABSTRACT FROM AUTHOR]

Published

2023

3. Machine learning using host/guest energy histograms to predict adsorption in metal–organic frameworks: Application to short alkanes and Xe/Kr mixtures.

Author

Li, Zhao, Bucior, Benjamin J., Chen, Haoyuan, Haranczyk, Maciej, Siepmann, J. Ilja, and Snurr, Randall Q.

Subjects

METAL-organic frameworks, MACHINE learning, GAS absorption & adsorption, ADSORPTION (Chemistry), HISTOGRAMS, ALKANES, ETHANES

Abstract

A machine learning (ML) methodology that uses a histogram of interaction energies has been applied to predict gas adsorption in metal–organic frameworks (MOFs) using results from atomistic grand canonical Monte Carlo (GCMC) simulations as training and test data. In this work, the method is first extended to binary mixtures of spherical species, in particular, Xe and Kr. In addition, it is shown that single-component adsorption of ethane and propane can be predicted in good agreement with GCMC simulation using a histogram of the adsorption energies felt by a methyl probe in conjunction with the random forest ML method. The results for propane can be improved by including a small number of MOF textural properties as descriptors. We also discuss the most significant features, which provides physical insight into the most beneficial adsorption energy sites for a given application. [ABSTRACT FROM AUTHOR]

Published

2021

4. Molecular fingerprint and machine learning to accelerate design of high‐performance homochiral metal–organic frameworks.

Author

Qiao, Zhiwei, Li, Lifeng, Li, Shuhua, Liang, Hong, Zhou, Jian, and Snurr, Randall Q.

Subjects

DNA fingerprinting, MACHINE learning, CLASSIFICATION algorithms, METAL-organic frameworks, FUNCTIONAL groups, DESIGN

Abstract

Computational screening was employed to calculate the enantioseparation capabilities of 45 functionalized homochiral metal–organic frameworks (FHMOFs), and machine learning (ML) and molecular fingerprint (MF) techniques were used to find new FHMOFs with high performance. With increasing temperature, the enantioselectivities for (R,S)‐1,3‐dimethyl‐1,2‐propadiene are improved. The "glove effect" in the chiral pockets was proposed to explain the correlations between the steric effect of functional groups and performance of FHMOFs. Moreover, the neighborhood component analysis and RDKit/MACCS MFs show the highest predictive effect on enantioselectivities among the four ML classification algorithms with nine MFs that were tested. Based on the importance of MF, 85 new FHMOFs were designed, and a newly designed FHMOF, NO2‐NHOH‐FHMOF, with high similarity to the optimal MFs achieved improved chiral separation performance, with enantioselectivities of 85%. The design principles and new chiral pockets obtained by ML and MFs could facilitate the development of new materials for chiral separation. [ABSTRACT FROM AUTHOR]

Published

2021

5. Prediction of hydrogen adsorption in nanoporous materials from the energy distribution of adsorption sites.

Author

Gopalan, Arun, Bucior, Benjamin J., Bobbitt, N. Scott, and Snurr, Randall Q.

Subjects

KRIGING, NANOPOROUS materials, ADSORPTION (Chemistry), ADSORPTION isotherms, HYDROGEN, METAL-organic frameworks

Abstract

We present a fast and accurate, semi-analytical method for predicting hydrogen adsorption in nanoporous materials. For any temperature and pressure, the adsorbed amount is calculated as an integral over the energy density of adsorption sites (guest-host interactions) plus an average guest-guest term. The guest-host interaction energy is calculated using a classical force field with hydrogen modelled as a single-site probe. The guest-guest interaction energy is approximated using an average coordination number, which is regressed using Gaussian Process Regression (GPR). Local adsorption at each site is then modelled using a Langmuir isotherm, which when weighted with its probability density gives an accurate description of hydrogen adsorption. The method is tested on 933 metal-organic frameworks (MOFs) from the Computation-Ready Experimental (CoRE) MOF database at 77 K from 10 − 5 to 100 bar, and the results are compared against GCMC predictions. To demonstrate the utility of the method, we calculated hydrogen adsorption isotherms for 12,914 existing MOF structures, at two different temperatures at a speed about 100 times that of GCMC simulations and analyzed the results. We found 13 MOFs with predicted deliverable capacities exceeding the DOE target of 50 g/L for adsorption at 100 bar, 77 K and desorption at 5 bar, 160 K. [ABSTRACT FROM AUTHOR]

Published

2019

6. Molecular modelling and machine learning for high-throughput screening of metal-organic frameworks for hydrogen storage.

Author

Bobbitt, N. Scott and Snurr, Randall Q.

Subjects

*METAL-organic frameworks, *MOLECULAR models, *MACHINE learning, *NANOPOROUS materials, *EQUATIONS of state, *HYDROGEN storage, *FUEL cell vehicles

Abstract

Hydrogen is an appealing energy storage solution for electric vehicles due to its low environmental impact and faster recharge times compared to batteries. However, there are many engineering challenges involved in safely storing a sufficient amount of hydrogen onboard a vehicle with a reasonable volumetric density. Nanoporous materials such as metal–organic frameworks (MOFs) have the potential to store hydrogen at high density and only moderate pressure. Considerable research has been devoted to finding new MOFs for hydrogen storage in recent years; however, a MOF that provides sufficient hydrogen density and is suitable to commercial applications has not yet been found. Much of this research makes use of molecular modelling to screen thousands of materials in a high-throughput way. Computational screening can be an effective tool for gaining insight into structure-performance relationships as well as finding specific candidates for an application. Recently, some research groups have also used machine learning to analyze data more effectively and accelerate the screening process. In this review, we discuss some recent advances in using molecular modelling and machine learning to find materials for hydrogen storage. We also discuss and compare some popular models for the hydrogen molecule and the accuracy of different equations of state, which are important considerations for accurate molecular simulations. [ABSTRACT FROM AUTHOR]

Published

2019

7. In silico design of microporous polymers for chemical separations and storage.

Author

Anstine, Dylan M, Sholl, David S, Siepmann, Joern Ilja, Snurr, Randall Q, Aspuru-Guzik, Alán, and Colina, Coray M

Subjects

POLYMER fractionation, CHEMICAL storage, MACHINE learning, PSEUDOPOTENTIAL method, MICROPOROSITY, POLYMERS

Abstract

[Display omitted] • Atomistic modeling techniques for microporous feature analysis. • In silico predictions of adsorption with flexible frameworks. • Data-driven methods are positioned to accelerate PIM discovery and design. Polymers of intrinsic microporosity (PIMs) are a family of materials with potential to be effective and scalable solutions for challenging adsorbent and membrane applications. The broad range of repeat unit chemistry, microporous structural features, and polymer processing makes exploration of the expansive PIM design space inefficient via chemical and materials intuition alone. Computational techniques such as molecular simulations and machine learning can provide a leap in capabilities to address this polymer design challenge and will be central to the future development of PIMs. We highlight recent microporous material studies that arrived at key results by employing computational techniques and provide our perspective on the prospects for in silico design and development of PIMs. [ABSTRACT FROM AUTHOR]

Published

2022

8. Realizing the data-driven, computational discovery of metal-organic framework catalysts.

Author

Rosen, Andrew S, Notestein, Justin M, and Snurr, Randall Q

Subjects

METAL-organic frameworks, CATALYSTS, MACHINE learning, HIGH throughput screening (Drug development)

Abstract

[Display omitted] • Big data approaches are needed to efficiently explore MOF catalyst space. • High-throughput protocols have been developed to screen large MOF datasets. • Machine learning is poised to accelerate MOF catalyst discovery. • While challenges remain, there are many recent developments and new opportunities. Metal-organic frameworks (MOFs) have been widely investigated for challenging catalytic transformations due to their well-defined structures and high degree of synthetic tunability. These features, at least in principle, make MOFs ideally suited for a computational approach towards catalyst design and discovery. Nonetheless, the widespread use of data science and machine learning to accelerate the discovery of MOF catalysts has yet to be substantially realized. In this review, we provide an overview of recent work that sets the stage for future high-throughput computational screening and machine learning studies involving MOF catalysts. This is followed by a discussion of several challenges currently facing the broad adoption of data-centric approaches in MOF computational catalysis, and we share possible solutions that can help propel the field forward. [ABSTRACT FROM AUTHOR]

Published

2022

9. Exploring the Structural, Dynamic, and Functional Properties of Metal‐Organic Frameworks through Molecular Modeling.

Author

Formalik, Filip, Shi, Kaihang, Joodaki, Faramarz, Wang, Xijun, and Snurr, Randall Q.

Abstract

This review spotlights the role of atomic‐level modeling in research on metal‐organic frameworks (MOFs), especially the key methodologies of density functional theory (DFT), Monte Carlo (MC) simulations, and molecular dynamics (MD) simulations. The discussion focuses on how periodic and cluster‐based DFT calculations can provide novel insights into MOF properties, with a focus on predicting structural transformations, understanding thermodynamic properties and catalysis, and providing information or properties that are fed into classical simulations such as force field parameters or partial charges. Classical simulation methods, highlighting force field selection, databases of MOFs for high‐throughput screening, and the synergistic nature of MC and MD simulations, are described. By predicting equilibrium thermodynamic and dynamic properties, these methods offer a wide perspective on MOF behavior and mechanisms. Additionally, the incorporation of machine learning (ML) techniques into quantum and classical simulations is discussed. These methods can enhance accuracy, expedite simulation setup, reduce computational costs, as well as predict key parameters, optimize geometries, and estimate MOF stability. By charting the growth and promise of computational research in the MOF field, the aim is to provide insights and recommendations to facilitate the incorporation of computational modeling more broadly into MOF research. [ABSTRACT FROM AUTHOR]

Published

2023