Jungyu Kim scite author profile

Lithium-ion batteries (LIBs) have been deployed in a wide range of energy-storage applications and helped to revolutionize technological development. Recently, a lithium ion battery that uses superconcentrated salt water as its electrolyte has been developed. However, the role of water in facilitating fast ion transport in such highly concentrated electrolyte solutions is not fully understood yet. Here, femtosecond IR spectroscopy and molecular dynamics simulations are used to show that bulk-like water coexists with interfacial water on ion aggregates. We found that dissolved ions form intricate three-dimensional ion−ion networks that are spontaneously intertwined with nanometric water hydrogen-bonding networks. Then, hydrated lithium ions move through bulk-like water channels acting like conducting wires for lithium ion transport. Our experimental and simulation results indicate that water structure-breaking chaotropic anion salts with a high propensity to form ion networks in aqueous solutions would be excellent candidates for water-based LIB electrolytes. We anticipate that the present work will provide guiding principles for developing aqueous LIB electrolytes.

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Dynamic Water Promotes Lithium-Ion Transport in Superconcentrated and Eutectic Aqueous Electrolytes

Kim

Koo

Lim

et al. 2021

ACS Energy Lett.

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Superconcentrated aqueous electrolytes have shown promise as safe and high-voltage lithium-ion battery (LIB) electrolytes. However, the interplay of lithium-ion solvation structure and dynamics with fast Li-ion transport has not been elucidated yet. Here, we combine the ultrafast femtosecond mid-IR spectroscopy, dielectric relaxation spectroscopy, pulsed-field gradient NMR, and molecular dynamics simulation for investigating the solvation structure and Li-ion transport mechanism in superconcentrated aqueous electrolytes. We found the existence of water molecules with vibrational and rotational properties very similar to those of bulk water, even at extremely high salt concentrations (28 m). Our experimental results show that the electrolytes have a heterogeneous solvation environment, and bulk-like water molecules promote fast Li-ion transport. We anticipate that the molecular understanding of the superconcentrated aqueous electrolytes obtained here would facilitate the design of solvation structures to overcome the limit of dilute LIB electrolytes.

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Solvation structure of phosphonium ionic liquid/CH₃SCN mixture as electrolytes for Li‐ion batteries: Infrared pump‐probe spectroscopic studies

Sahu

Kim

Park

et al. 2021

Bulletin Korean Chem Soc

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Lithium‐ion battery (LIB) electrolytes based on room‐temperature ionic liquids (RTIL) are promising as safe and sustainable LIB electrolytes. However, there are no reports on the solvation structure and dynamics of RTIL due to the existence of various solvation species in RTIL. Here, we investigated the solvation structure and dynamics of binary mixtures of the phosphonium ionic liquid, tributyl(2‐methoxyethyl)phosphonium bis(trifluoromethanesulfonyl)imide (P444102TFSI), and methylthiocyanate (CH3SCN), with ultrafast mid‐IR Spectroscopy. The changes of vibrational and rotational dynamics of CH3SCN∙∙∙Li+ complex and free CH3SCN with an increase in CH3SCN concentration suggest the presence of at least four solvation species, providing superior resolving power for various solvation species existing in complex LIB electrolytes. Our experimental results show that the environment of free CH3SCN and CH3SCN∙∙∙Li+ complex changes drastically with change in CH3SCN mole fraction and Li salt concentration in the mixture. We expect that this can affect the Li‐ion transport mechanism in the IL‐based electrolytes.

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Electronic Effect on the Molecular Motion of Aromatic Amides: Combined Studies Using VT-NMR and Quantum Calculations

Kim

et al. 2018

Molecules

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Rotational barrier energy studies to date have focused on the amide bond of aromatic compounds from a kinetic perspective using quantum calculations and nuclear magnetic resonance (NMR). These studies provide valuable information, not only regarding the basic conformational properties of amide bonds but also the molecular gear system, which has recently gained interest. Thus, we investigate the precise motion of the amide bonds of two aromatic compounds using an experimental rotational barrier energy estimation by NMR experiments and a theoretical evaluation of the density functional theory calculation. The theoretical potential energy surface scan method combined with the quadratic synchronous transit 3 method and consideration of additional functional group rotation with optimization and frequency calculations support the results of the variable temperature 1H NMR, with deviations of less than 1 kcal/mol. This detailed experimental and theoretical research strongly supports molecular gear motion in the aromatic amide system, and the difference in kinetic energy indicates that the electronic effect from the aromatic structure has a key role in conformational movements at different temperatures. Our study provides an enhanced basis for future amide structural dynamics research.

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Jungyu Kim

Nanometric Water Channels in Water-in-Salt Lithium Ion Battery Electrolyte

Dynamic Water Promotes Lithium-Ion Transport in Superconcentrated and Eutectic Aqueous Electrolytes

Solvation structure of phosphonium ionic liquid/CH₃SCN mixture as electrolytes for Li‐ion batteries: Infrared pump‐probe spectroscopic studies

Electronic Effect on the Molecular Motion of Aromatic Amides: Combined Studies Using VT-NMR and Quantum Calculations

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Jungyu Kim

Nanometric Water Channels in Water-in-Salt Lithium Ion Battery Electrolyte

Dynamic Water Promotes Lithium-Ion Transport in Superconcentrated and Eutectic Aqueous Electrolytes

Solvation structure of phosphonium ionic liquid/CH3SCN mixture as electrolytes for Li‐ion batteries: Infrared pump‐probe spectroscopic studies

Electronic Effect on the Molecular Motion of Aromatic Amides: Combined Studies Using VT-NMR and Quantum Calculations

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Solvation structure of phosphonium ionic liquid/CH₃SCN mixture as electrolytes for Li‐ion batteries: Infrared pump‐probe spectroscopic studies