Predictive Molecular Models for Charged Materials Systems: From Energy Materials to Biomacromolecules

Jeong, Kyeong-Jun; Jeong, Seungwon; Lee, Sangmin; Son, Chang Yun

doi:10.1002/adma.202204272

Cited by 4 publications

(2 citation statements)

References 302 publications

(585 reference statements)

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“…26 It is noteworthy that the explicit treatment of electrostatic interactions and polarization effects is crucial for comprehending the complex role of long-range strong electrostatics under heterogeneous conditions. [27][28][29] However, implementing such treatment with polarizable force fields poses significant computational challenges. An alternative approach with a scaled-charge force field, which accounts for electronic polarization by scaling the charges on the ions, was also employed to investigate the effect of alkali salts on the solvation structure of water molecules.…”

Section: Simulationmentioning

confidence: 99%

Regulating the electrical double layer to prevent water electrolysis for wet ionic liquids with cheap salts

Wu,

Zhang,

Chen

et al. 2023

Nanoscale

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Section: Simulationmentioning

confidence: 99%

Regulating the electrical double layer to prevent water electrolysis for wet ionic liquids with cheap salts

Wu,

Zhang,

Chen

et al. 2023

Nanoscale

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“…We also show studies of molecular simulation on these aquatic liquid crystals as examples of collaboration of experiment and computer science for design and understanding of these molecular assemblies. [6,21]…”

Section: Introductionmentioning

confidence: 99%

Aquatic Functional Liquid Crystals: Design, Functionalization, and Molecular Simulation

Kato,

Uchida,

Ishii

et al. 2023

Advanced Science

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Aquatic functional liquid crystals, which are ordered molecular assemblies that work in water environment, are described in this review. Aquatic functional liquid crystals are liquid‐crystalline (LC) materials interacting water molecules or aquatic environment. They include aquatic lyotropic liquid crystals and LC based materials that have aquatic interfaces, for example, nanoporous water treatment membranes that are solids preserving LC order. They can remove ions and viruses with nano‐ and subnano‐porous structures. Columnar, smectic, bicontinuous LC structures are used for fabrication of these 1D, 2D, 3D materials. Design and functionalization of aquatic LC sensors based on aqueous/LC interfaces are also described. The ordering transitions of liquid crystals induced by molecular recognition at the aqueous interfaces provide distinct optical responses. Molecular orientation and dynamic behavior of these aquatic functional LC materials are studied by molecular dynamics simulations. The molecular interactions of LC materials and water are key of these investigations. New insights into aquatic functional LC materials contribute to the fields of environment, healthcare, and biotechnology.

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Accounting for the Quantum Capacitance of Graphite in Constant Potential Molecular Dynamics Simulations

Goloviznina,

Fleischhaker,

Binninger

et al. 2024

Advanced Materials

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Molecular dynamics (MD) simulations at a constant electric potential are an essential tool to study electrochemical processes, providing microscopic information on the structural, thermodynamic, and dynamical properties. Despite the numerous advances in the simulation of electrodes, they fail to accurately represent the electronic structure of materials such as graphite. In this work, a simple parameterization method that allows to tune the metallicity of the electrode based on a quantum chemistry calculation of the density of states (DOS) is introduced. As a first illustration, the interface between graphite electrodes and two different liquid electrolytes, an aqueous solution of NaCl and a pure ionic liquid, at different applied potentials are studied. It is shown that the simulations reproduce qualitatively the experimentally‐measured capacitance; in particular, they yield a minimum of capacitance at the point of zero charge (PZC), which is due to the quantum capacitance (QC) contribution. An analysis of the structure of the adsorbed liquids allows to understand why the ionic liquid displays a lower capacitance despite its large ionic concentration. In addition to its relevance for the important class of carbonaceous electrodes, this method can be applied to any electrode materials (e.g. 2D materials, conducting polymers, etc), thus enabling molecular simulation studies of complex electrochemical devices in the future.

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Predictive Molecular Models for Charged Materials Systems: From Energy Materials to Biomacromolecules

Cited by 4 publications

References 302 publications

Regulating the electrical double layer to prevent water electrolysis for wet ionic liquids with cheap salts

Regulating the electrical double layer to prevent water electrolysis for wet ionic liquids with cheap salts

Aquatic Functional Liquid Crystals: Design, Functionalization, and Molecular Simulation

Accounting for the Quantum Capacitance of Graphite in Constant Potential Molecular Dynamics Simulations

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