Hyeon-Su Bae scite author profile

Hyeon-Su Bae

5Publications

51Citation Statements Received

210Citation Statements Given

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203

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Hanbat National University

Publications

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Synergistic Effect of a Dual-Salt Liquid Electrolyte with a LiNO₃ Functional Additive toward Stabilizing Thin-Film Li Metal Electrodes for Li Secondary Batteries

Phiri

Kim

et al. 2021

ACS Appl. Mater. Interfaces

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Li metal thickness has been considered a key factor in determining the electrochemical performance of Li metal anodes. The use of thin Li metal anodes is a prerequisite for increasing the energy density of Li secondary batteries intended for emerging large-scale electrical applications, such as electric vehicles and energy storage systems. To utilize thin (20 μm thick) Li metal anodes in Li metal secondary batteries, we investigated the synergistic effect of a functional additive (Li nitrate, LiNO3) and a dual-salt electrolyte (DSE) system composed of Li bis(fluorosulfonyl)imide (LiTFSI) and Li bis(oxalate)borate (LiBOB). By controlling the amount of LiNO3 in DSE, we found that DSE containing 0.05 M LiNO3 (DSE–0.05 M LiNO3) significantly improved the electrochemical performance of Li metal anodes. DSE–0.05 M LiNO3 increased the cycling performance by 146.3% [under the conditions of a 1C rate (2.0 mA cm–2), DSE alone maintained 80% of the initial discharge capacity up to the 205th cycle, whereas DSE–0.05 M LiNO3 maintained 80% up to the 300th cycle] and increased the rate capability by 128.2% compared with DSE alone [the rate capability of DSE–0.05 M LiNO3 = 50.4 mAh g–1, and DSE = 39.3 mAh g–1 under 7C rate conditions (14.0 mA cm–2)]. After analyzing the Li metal surface using scanning electron microscopy and X-ray photoelectron spectroscopy, we were able to infer that the stabilized solid electrolyte interphase layer formed by the combination of LiNO3 and the dual salt resulted in a uniform Li deposition during repeated Li plating/stripping processes.

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Eco-Friendly Water-Processable Polyimide Binders with High Adhesion to Silicon Anodes for Lithium-Ion Batteries

Bae

Kang

et al. 2021

Nanomaterials

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Silicon is an attractive anode material for lithium-ion batteries (LIBs) because of its natural abundance and excellent theoretical energy density. However, Si-based electrodes are difficult to commercialize because of their significant volume changes during lithiation that can result in mechanical damage. To overcome this limitation, we synthesized an eco-friendly water-soluble polyimide (W-PI) precursor, poly(amic acid) salt (W-PAmAS), as a binder for Si anodes via a simple one-step process using water as a solvent. Using the W-PAmAS binder, a composite Si electrode was achieved by low-temperature processing at 150 °C. The adhesion between the electrode components was further enhanced by introducing 3,5-diaminobenzoic acid, which contains free carboxylic acid (–COOH) groups in the W-PAmAS backbone. The –COOH of the W-PI binder chemically interacts with the surface of Si nanoparticles (SiNPs) by forming ester bonds, which efficiently bond the SiNPs, even during severe volume changes. The Si anode with W-PI binder showed improved electrochemical performance with a high capacity of 2061 mAh g−1 and excellent cyclability of 1883 mAh g−1 after 200 cycles at 1200 mA g−1. Therefore, W-PI can be used as a highly effective polymeric binder in Si-based high-capacity LIBs.

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Scaffold-structured polymer binders for long-term cycle performance of stabilized lithium-powder electrodes

Jin

Bae

Hong

et al. 2020

Electrochimica Acta

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Large-area surface-patterned Li metal anodes fabricated using large, flexible patterning stamps for Li metal secondary batteries

Bae

Phiri

Kang

et al. 2021

Journal of Power Sources

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Highly Stable Porous Polyimide Sponge as a Separator for Lithium-Metal Secondary Batteries

et al. 2020

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To inhibit Li-dendrite growth on lithium (Li)-metal electrodes, which causes capacity deterioration and safety issues in Li-ion batteries, we prepared a porous polyimide (PI) sponge using a solution-processable high internal-phase emulsion technique with a water-soluble PI precursor solution; the process is not only simple but also environmentally friendly. The prepared PI sponge was processed into porous PI separators and used for Li-metal electrodes. The physical properties (e.g., thermal stability, liquid electrolyte uptake, and ionic conductivity) of the porous PI separators and their effect on the Li-metal anodes (e.g., self-discharge and open-circuit voltage properties after storage, cycle performance, rate capability, and morphological changes) were investigated. Owing to the thermally stable properties of the PI polymer, the porous PI separators demonstrated no dimensional changes up to 180 °C. In comparison with commercialized polyethylene (PE) separators, the porous PI separators exhibited improved wetting ability for liquid electrolytes; thus, the latter improved not only the physical properties (e.g., improved the electrolyte uptake and ionic conductivity) but also the electrochemical properties of Li-metal electrodes (e.g., maintained stable self-discharge capacity and open-circuit voltage features after storage and improved the cycle performance and rate capability) in comparison with PE separators.

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Hyeon-Su Bae

Synergistic Effect of a Dual-Salt Liquid Electrolyte with a LiNO₃ Functional Additive toward Stabilizing Thin-Film Li Metal Electrodes for Li Secondary Batteries

Eco-Friendly Water-Processable Polyimide Binders with High Adhesion to Silicon Anodes for Lithium-Ion Batteries

Scaffold-structured polymer binders for long-term cycle performance of stabilized lithium-powder electrodes

Large-area surface-patterned Li metal anodes fabricated using large, flexible patterning stamps for Li metal secondary batteries

Highly Stable Porous Polyimide Sponge as a Separator for Lithium-Metal Secondary Batteries

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Hyeon-Su Bae

Synergistic Effect of a Dual-Salt Liquid Electrolyte with a LiNO3 Functional Additive toward Stabilizing Thin-Film Li Metal Electrodes for Li Secondary Batteries

Eco-Friendly Water-Processable Polyimide Binders with High Adhesion to Silicon Anodes for Lithium-Ion Batteries

Scaffold-structured polymer binders for long-term cycle performance of stabilized lithium-powder electrodes

Large-area surface-patterned Li metal anodes fabricated using large, flexible patterning stamps for Li metal secondary batteries

Highly Stable Porous Polyimide Sponge as a Separator for Lithium-Metal Secondary Batteries

Contact Info

Product

Resources

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Synergistic Effect of a Dual-Salt Liquid Electrolyte with a LiNO₃ Functional Additive toward Stabilizing Thin-Film Li Metal Electrodes for Li Secondary Batteries