Jae‐Hyun An scite author profile

Jae‐Hyun An

2Publications

18Citation Statements Received

41Citation Statements Given

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Korea University

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Enabling 100C Fast‐Charging Bulk Bi Anodes for Na‐Ion Batteries

Kim

et al. 2022

Advanced Materials

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However, even with the use of nanoscale materials, the large volume changes associated with charging and discharging cause the fragmentation of the anode material, [2] decreasing their capacities, and cycling lifetimes. The coating and doping of anode nanomaterials are among the various methods proposed to address this problem. [3] However, these methods are complex and expensive, and the overlayer coated on the anode nanomaterials may hinder the fast transport of carrier ions. Another approach based on the reaction between an anode material and electrolyte has also been reported. [4] This method induces the spontaneous restructuring of a bulk anode material into a 3D porous nanostructure during battery cycling with a glyme-based electrolyte [4b-e] . Although the short diffusion distance in thus-formed nanostructure is beneficial for improving the rate performance of the anode, its energy capacity still rapidly decreases with increasing current rate (C-rate). [3a,b,5] This indicates that a strategy based on reducing the diffusion distance alone is not sufficient to simultaneously improve the energy capacity, rate capability, and cycling stability of alloying anodes.To determine another variable governing the kinetics of carrier-ion diffusion at high C-rates, it is necessary to investigate why the practical capacity of the anode decreases with It is challenging to develop alloying anodes with ultrafast charging and large energy storage using bulk anode materials because of the difficulty of carrierion diffusion and fragmentation of the active electrode material. Herein, a rational strategy is reported to design bulk Bi anodes for Na-ion batteries that feature ultrafast charging, long cyclability, and large energy storage without using expensive nanomaterials and surface modifications. It is found that bulk Bi particles gradually transform into a porous nanostructure during cycling in a glyme-based electrolyte, whereas the resultant structure stores Na ions by forming phases with high Na diffusivity. These features allow the anodes to exhibit unprecedented electrochemical properties; the developed Na-Bi half-cell delivers 379 mA h g −1 (97% of that measured at 1C) at 7.7 A g −1 (20C) during 3500 cycles. It also retained 94% and 93% of the capacity measured at 1C even at extremely fast-charging rates of 80C and 100C, respectively. The structural origins of the measured properties are verified by experiments and first-principles calculations. The findings of this study not only broaden understanding of the underlying mechanisms of fast-charging anodes, but also provide basic guidelines for searching battery anodes that simultaneously exhibit high capacities, fast kinetics, and long cycling stabilities.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.202201446.

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Solvent‐Driven Transformation of Microsized Metal Particles into a Nanoporous Structure and Its Application to Ultrafast‐Charging Batteries

Kim

et al. 2023

Adv Funct Materials

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The coalescence of metal nanoparticles in colloidal solutions is a universal and ubiquitous phenomenon. Using this behavior, a simple yet effective route is developed that enables the spontaneous transformation of microsized metals into nanoporous structures in specific electrolyte solvents. The criteria for selecting solvents and counterpart metals suitable for generating nanoporous structures are derived based on the classical theory of acid–base reactions and quantum chemistry based on density functional theory. When employing the developed method for anodes for Na‐ion batteries, the anodes prepared using microsized Sn, Pb, Bi, and CuS particles store 592, 423, 383, and 546 mAh g−1, respectively, at 10 C with cycling lifetimes of 3000−6000 cycles. This study provides fundamental framework for selecting solvents to realize low‐cost anodes with large capacities, long cycling lifetimes, and excellent rate performances. Moreover, the findings can be extended to other functional materials that can exploit their large specific surface areas.

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Jae‐Hyun An

Enabling 100C Fast‐Charging Bulk Bi Anodes for Na‐Ion Batteries

Solvent‐Driven Transformation of Microsized Metal Particles into a Nanoporous Structure and Its Application to Ultrafast‐Charging Batteries

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