Insights into Host–Guest Binding in Hydroquinone Clathrates: Single-Crystal X-ray and Neutron Diffraction, and Complementary Computational Studies on the Hydroquinone-CO<sub>2</sub> Clathrate

Grosjean, Arnaud; Spackman, Peter R.; Edwards, Alison J.; Tolborg, Kasper; Vosegaard, Emilie S.; Koutsantonis, George A.; Iversen, Bo B.; Spackman, Mark A.

doi:10.1021/acs.cgd.1c00271

Cited by 6 publications

(3 citation statements)

References 71 publications

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“…9) (Turner et al, 2015); (iv) the computation of quite accurate lattice energies for molecular crystals . The techniques currently available in CE have already found many applications in many hot topics of solid-state chemistry and physics: (supra)molecular recognition (Shi, Sobolev et al, 2015;Shi, Thomas et al, 2015;Dey, Bhandary et al, 2016;Shi et al, 2016Shi et al, , 2017Shi et al, , 2019Grosjean et al, 2021), polymorphism Thomas, Grosjean et al, 2019), effects of temperature and pressure on crystal structures (Eikeland, Thomsen et al, 2016, 2017Sussardi et al, 2023), and structure-property relationships (Thomas, Shi et al, 2017;Karothu et al, 2022).…”

Section: Wavefunction-and Density-matrix-based Approachesmentioning

confidence: 99%

Current developments and trends in quantum crystallography

Krawczuk,

Genoni

2024

Acta Crystallogr B Struct Sci Cryst Eng Mater

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Quantum crystallography is an emerging research field of science that has its origin in the early days of quantum physics and modern crystallography when it was almost immediately envisaged that X-ray radiation could be somehow exploited to determine the electron distribution of atoms and molecules. Today it can be seen as a composite research area at the intersection of crystallography, quantum chemistry, solid-state physics, applied mathematics and computer science, with the goal of investigating quantum problems, phenomena and features of the crystalline state. In this article, the state-of-the-art of quantum crystallography will be described by presenting developments and applications of novel techniques that have been introduced in the last 15 years. The focus will be on advances in the framework of multipole model strategies, wavefunction-/density matrix-based approaches and quantum chemical topological techniques. Finally, possible future improvements and expansions in the field will be discussed, also considering new emerging experimental and computational technologies.

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Section: Wavefunction-and Density-matrix-based Approachesmentioning

confidence: 99%

Current developments and trends in quantum crystallography

Krawczuk,

Genoni

2024

Acta Crystallogr B Struct Sci Cryst Eng Mater

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“…Due to the weak scattering power of hydrogen atoms in XRD experiments, their positions are typically inferred closer to their parent atoms, resulting in shorter X-H distances than those obtained from neutron experiments. Fortunately, this discrepancy can be corrected using QC, and computational modeling, to gain a comprehensive understanding of the structures and functionalities of materials for carbon capture, including those explored for DAC applications [23,[25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

Crystal Engineering of Hydrogen Bonding for Direct Air Capture of CO2: A Quantum Crystallography Perspective

Pawlędzio,

Wang

2024

Crystals

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Rising atmospheric CO2 levels demand efficient and sustainable carbon capture solutions. Direct air capture (DAC) via crystallizing hydrogen-bonded frameworks such as carbonate salts has emerged as a promising approach. This review explores the potential of crystal engineering, in tandem with advanced quantum crystallography techniques and computational modeling, to unlock the full potential of DAC materials. We examine the critical role of hydrogen bonding and other noncovalent interactions within a family of bis-guanidines that governs the formation of carbonate salts with high CO2 capture capacity and low regeneration energies for utilization. Quantum crystallography and charge density analysis prove instrumental in elucidating these interactions. A case study of a highly insoluble carbonate salt of a 2,6-pyridine-bis-(iminoguanidine) exemplifies the effectiveness of these approaches. However, challenges remain in the systematic and precise determination of hydrogen atom positions and atomic displacement parameters within DAC materials using quantum crystallography, and limitations persist in the accuracy of current energy estimation models for hydrogen bonding interactions. Future directions lie in exploring diverse functional groups, designing advanced hydrogen-bonded frameworks, and seamlessly integrating experimental and computational modeling with machine learning. This synergistic approach promises to propel the design and optimization of DAC materials, paving the way for a more sustainable future.

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“…Among the most common uses are the capture of pollutants, and storage of substances of interest such as fuels, flammable fluids or reagents, that require safe transport [16][17][18]22,23], or absorption of greenhouse gases and solid-liquid separation processes, commonly known as "selective clathration". The latter is based on the preference of a host structure for a certain substance present in a liquid sample, which is then confined in the solid phase as guest particles [10,18,21,[24][25][26][27].…”

Section: Introductionmentioning

confidence: 99%

Influence of Lennard–Jones Parameters in the Temperature Dependence of Real Gases Diffusion through Nanochannels

2023

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Umbrella Sampling Molecular Dynamics has been used to determine transition energies for different guest molecules through hydroquinone β-clathrate nanochannels, as well as their temperature trend. This clathrate has been shown to successfully enclathrate different types of small gases with remarkable selectivity, and thus it has been proposed as a potential gas separation and storage medium. Most of these potential guest gases can be successfully modeled as single Lennard–Jones spheres. Then, to obtain a general view of diffusion probabilities for different potential guest molecules, a comparative study for different virtual guest molecules described by different Lennard–Jones parameters has been performed. A regular temperature trend has been obtained for the transition energies for the molecular model characteristic parameter range explored. Finally, to locate the transition energy values of real gases within the space of phases explored, calculations have been repeated for molecular models of different noble gases and H2. The correlation results presented allow a wide interpolation ability for determining the transition energies of potential guest molecules stored or diffusing through the nanochannels of the studied clathrate structure.

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Insights into Host–Guest Binding in Hydroquinone Clathrates: Single-Crystal X-ray and Neutron Diffraction, and Complementary Computational Studies on the Hydroquinone-CO₂ Clathrate

Cited by 6 publications

References 71 publications

Current developments and trends in quantum crystallography

Current developments and trends in quantum crystallography

Crystal Engineering of Hydrogen Bonding for Direct Air Capture of CO2: A Quantum Crystallography Perspective

Influence of Lennard–Jones Parameters in the Temperature Dependence of Real Gases Diffusion through Nanochannels

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Insights into Host–Guest Binding in Hydroquinone Clathrates: Single-Crystal X-ray and Neutron Diffraction, and Complementary Computational Studies on the Hydroquinone-CO2 Clathrate

Cited by 6 publications

References 71 publications

Current developments and trends in quantum crystallography

Current developments and trends in quantum crystallography

Crystal Engineering of Hydrogen Bonding for Direct Air Capture of CO2: A Quantum Crystallography Perspective

Influence of Lennard–Jones Parameters in the Temperature Dependence of Real Gases Diffusion through Nanochannels

Contact Info

Product

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Insights into Host–Guest Binding in Hydroquinone Clathrates: Single-Crystal X-ray and Neutron Diffraction, and Complementary Computational Studies on the Hydroquinone-CO₂ Clathrate