Dehydration of a crystal hydrate at subglacial temperatures

Eaby, Alan C; Myburgh, Dirkie C; Kosimov, Akmal; Kwit, Marcin; Esterhuysen, Catharine; Janiak, Agnieszka; Barbour, Leonard J.

doi:10.1038/s41586-023-05749-7

Cited by 12 publications

(7 citation statements)

References 71 publications

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“…It is apparent that the oxygen atoms are stationary within the limiting domain space during extreme experimental conditions, but the protons are observed to easily diffuse through the oxygen lattice, which is indicative of the recently discovered superionic phase in water (see Figure 2c). Alan C. Eaby et al [20] from the University of Stellenbosch, South Africa, and the University of Poznan, Poland, described a porous organic crystal that reversibly adsorbs water into a 1 nm wide channel at relative humidity above 55 %. The ease of water passage through T1 was assessed by mean square displacement (MSD) analysis.…”

Section: Properties Of Water In the Spatially Confined Domainmentioning

confidence: 99%

Enhanced Electrocatalytic Performances by Spatially Confined Aqueous Electrolytes

Zhang,

Cai,

2024

ChemistrySelect

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Electrocatalysis is an important energy conversion and storage technology that has made significant progress in areas such as fuel cells, hydrogen production from electrolyzed water and electrochemical synthesis. In practical applications, the efficiency and stability of electrocatalytic processes remain challenging. Spatially confined (or called domain‐limited) water refers to the immobilization of water molecules in a limited region near the catalyst surface to form a specific aqueous phase environment. This domain‐limited aqueous phase environment can greatly influence the electrocatalytic efficacy by enhancing adsorption and lowering the proton transport and solvent diffusion energy barriers in the reaction. In recent years, the goal of improving electrocatalytic performance has been successfully achieved through interfacial domain‐limited, microporous domain‐limited and nanoreactor domain‐limited. Spatially domain‐limited water as a novel strategy can significantly enhance the activity and selectivity of electrocatalytic reactions, but understanding its mechanism of action remains a challenge. With a deeper understanding of domain‐limited water and further development of the technology, it is believed that it will bring greater breakthroughs and application prospects in the field of electrocatalysis.

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Section: Properties Of Water In the Spatially Confined Domainmentioning

confidence: 99%

Enhanced Electrocatalytic Performances by Spatially Confined Aqueous Electrolytes

Zhang,

Cai,

2024

ChemistrySelect

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“…Controlling the three-dimensional self-assembly of organic molecules into a solid-state structure remains challenging for crystal engineers and materials scientists. The extended solid-state structure, as well as the intermolecular forces sustaining the solid have a direct influence on the properties of the material. − Π-stacking interactions, , for example, play a role in protein folding and binding of small molecules, affect conductivity in organic semiconductors, , and can be used to drive molecular recognition. , One property affected by solid-state structure and intermolecular forces is thermal expansion (TE); the response of a material to temperature change. Stronger intermolecular interactions, such as halogen and hydrogen bonds, are typically less affected by temperature than weaker interactions, such as π stacking.…”

Section: Introductionmentioning

confidence: 99%

Polymorphism and π Stacking Affect Thermal Expansion Behavior in Halogen-Bonded Cocrystals Based on 1,4-Diiodoperchlorobenzene

George III,

Karimi,

Juneja

et al. 2024

Crystal Growth & Design

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The thermal expansion behavior of a series of halogen-bonded cocrystals containing 1,4-diiodoperchlorobenzene as the donor is described. Two of the solids are polymorphs and contain 4-stilbazole as the acceptor, while the third solid contains 4-(phenylethynyl)pyridine as the acceptor, and this solid is isostructural with one of the polymorphs. All solids are sustained by I•••N halogen bonds, and the least thermal expansion occurs along this direction in all solids. The polymorphs exhibit significant differences in π stacking, and we show that electronically similar face-to-face stacked rings undergo more expansion compared to electronically different stacked rings. Moreover, in the two polymorphs, the directions of moderate expansion and most expansion are reversed, demonstrating how cocrystal polymorphism can affect material properties.

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“…Water plays a crucial role in biological and chemical systems as the matrix of life, and hydrogen bond, especially its strength, is vital to the exhibited properties of water. − Chaplin et al suggested that if the strength of hydrogen bonds in water is 7% stronger, the freezing temperature would increase to the average surface temperature (15 °C) of Earth, while the water would boil at a normal human body temperature if it is 22% weaker . Hence, large numbers of studies have been performed to explore the strength of hydrogen bonds.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Hydrogen Bonds of the (H₂O)_n (n = 4–8) Clusters Confined in Uranyl Peroxide Cluster Na₂₀(UO₂)₂₀(O₂)₃₀

Song

2023

Inorg. Chem.

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Water is a basic resource and an essential component of living organisms. It often exhibits some novel properties under confinement. The water clusters (H2O) n (n = 4–8) confined in the cavity of uranyl peroxide cluster Na20(UO2)20(O2)30 (U20) have been computationally investigated by using ab initio molecular dynamics (AIMD) simulations and density functional theory (DFT) calculations in this study. The results show that the confined water clusters can form hydrogen bonds with the internal oxygen atoms (Ouranyl) of U20, and their conformations changed significantly. The average lengths (2.553–2.645 Å) of hydrogen bonds in confined (H2O) n are shorter than those (2.731–2.841 Å) in the corresponding free water clusters. Moreover, these confined hydrogen bonds show better hydrogen bond patterns according to the quantified indices. The natural bond orbital (NBO) calculations determine that there is electron transferring from the U20 to its interior (H2O) n . It is the main reason for enhancing hydrogen bond interactions among the confined water molecules because their oxygen atoms are more negatively charged and their hydrogen atoms are more positively charged. The quantum theory of atoms in molecules (QTAIM) and interacting quantum atoms (IQA) analyses indicate that the confined hydrogen bonds are more covalent, based on the significant electron density ρ(r) and local energy density H(r) at the bond critical points (BCPs), and the stronger energies of interatomic exchange interactions (V xc). These findings may help to promote the communication of confined water clusters and enrich the understating of confined hydrogen bonds.

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Dehydration of a crystal hydrate at subglacial temperatures

Cited by 12 publications

References 71 publications

Enhanced Electrocatalytic Performances by Spatially Confined Aqueous Electrolytes

Enhanced Electrocatalytic Performances by Spatially Confined Aqueous Electrolytes

Polymorphism and π Stacking Affect Thermal Expansion Behavior in Halogen-Bonded Cocrystals Based on 1,4-Diiodoperchlorobenzene

Enhanced Hydrogen Bonds of the (H₂O)_n (n = 4–8) Clusters Confined in Uranyl Peroxide Cluster Na₂₀(UO₂)₂₀(O₂)₃₀

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Dehydration of a crystal hydrate at subglacial temperatures

Cited by 12 publications

References 71 publications

Enhanced Electrocatalytic Performances by Spatially Confined Aqueous Electrolytes

Enhanced Electrocatalytic Performances by Spatially Confined Aqueous Electrolytes

Polymorphism and π Stacking Affect Thermal Expansion Behavior in Halogen-Bonded Cocrystals Based on 1,4-Diiodoperchlorobenzene

Enhanced Hydrogen Bonds of the (H2O)n (n = 4–8) Clusters Confined in Uranyl Peroxide Cluster Na20(UO2)20(O2)30

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Enhanced Hydrogen Bonds of the (H₂O)_n (n = 4–8) Clusters Confined in Uranyl Peroxide Cluster Na₂₀(UO₂)₂₀(O₂)₃₀