Hyebin Jeong scite author profile

Lithium metal batteries are considered “rough diamonds” in electrochemical energy storage systems. Li-metal anodes have the versatile advantages of high theoretical capacity, low density, and low reaction potential, making them feasible candidates for next-generation battery applications. However, unsolved problems, such as dendritic growths, high reactivity of Li-metal, low Coulombic efficiency, and safety hazards, still exist and hamper the improvement of cell performance and reliability. The use of functional separators is one of the technologies that can contribute to solving these problems. Recently, functional separators have been actively studied and developed. In this paper, we summarize trends in the research on separators and predict future prospects.

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A review on current collector coating methods for next-generation batteries

Jeong

Jang

2022

Chemical Engineering Journal

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Spinodal Decomposition Method for Structuring Germanium–Carbon Li-Ion Battery Anodes

Wen

Jeong

et al. 2023

ACS Nano

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To increase the energy density of lithium-ion batteries (LIBs), high-capacity anodes which alloy with Li ions at a low voltage against Li/Li+ have been actively pursued. So far, Si has been studied the most extensively because of its high specific capacity and cost efficiency; however, Ge is an interesting alternative. While the theoretical specific capacity of Ge (1600 mAh g–1) is only half that of Si, its density is more than twice as high (Ge, 5.3 g cm–3; Si, 2.33 g cm–3), and therefore the charge stored per volume is better than that of Si. In addition, Ge has a 400 times higher ionic diffusivity and 4 orders of magnitude higher electronic conductivity compared to Si. However, similarly to Si, Ge needs to be structured in order to manage stresses induced during lithiation and many reports have achieved sufficient areal loadings to be commercially viable. In this work, spinodal decomposition is used to make secondary particles of about 2 μm in diameter that consist of a mixture of ∼30 nm Ge nanoparticles embedded in a carbon matrix. The secondary structure of these germanium–carbon particles allows for specific capacities of over 1100 mAh g−1 and a capacity retention of 91.8% after 100 cycles. Finally, high packing densities of ∼1.67 g cm–3 are achieved in blended electrodes by creating a bimodal size distribution with natural graphite.

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Effects of chelating agent on the nanostructure of nickel hexacyanoferrate and its performance in seawater battery application

Jeong

Ahn

2023

Chemical Engineering Journal

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Hyebin Jeong

A Review of Functional Separators for Lithium Metal Battery Applications

A review on current collector coating methods for next-generation batteries

Spinodal Decomposition Method for Structuring Germanium–Carbon Li-Ion Battery Anodes

Effects of chelating agent on the nanostructure of nickel hexacyanoferrate and its performance in seawater battery application

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