In Situ Interfacial Tuning To Obtain High-Performance Nickel-Rich Cathodes in Lithium Metal Batteries

Ma, Hyunsoo; Hwang, Daeyeon; Ahn, Young Jun; Lee, Min Young; Kim, Saehun; Lee, Yong-Won; Lee, Sang‐Min; Kwak, Sang Kyu; Choi, Nam‐Soon

doi:10.1021/acsami.0c06830

Cited by 13 publications

(15 citation statements)

References 42 publications

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“…Great efforts have been devoted to suppressing the formation of Li dendrites in recent years. For example, functional electrolytes and additives were examined to form stable solid-electrolyte interphase layers. − Protective layers were suggested to mechanically suppress not only the growth of Li dendrites but also the electrolyte decomposition. − Porous frameworks were introduced as current collectors to confine Li deposition in their void space. − Three-dimensional porous frameworks have significant merits over conventional two-dimensional Li metal foils. The large surface area of the porous frameworks reduces the local current density, promoting uniform Li plating. − In addition, the volume change in the framework during charge and discharge is negligible because the Li metal is confined in the pores of the frameworks. , Taking the pack design of Li metal batteries into consideration, the volume change in the Li metal during cycling needs to be sufficiently small; otherwise the battery pack undergoes irreversible deformation during cycling.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Porous Frameworks for Li Metal Batteries: Superconformal versus Conformal Li Growth

Lee

Won

Kim

et al. 2021

ACS Appl. Mater. Interfaces

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Li metal batteries have been considered a promising alternative to Li-ion batteries because of the high theoretical capacity of the Li metal. There have been remarkable improvements in the electrochemical performance of Li metal electrodes, although the current Li metal technology is not sufficiently practical in terms of cycle performance, safety, and volume change during cycling. Herein, the role of pore size distribution in the Li metal plating behavior of porous frameworks is clarified to attain the ideal pore structure of the framework as a Li metal host. The monodisperse pore framework shows the conformal electrodeposition of the Li metal, whereas the pore size gradient framework exhibits the superconformal plating of the Li metal. The conformal and superconformal electrodepositions of the Li metal are elucidated in terms of variations along the pore depth direction in the charge-transfer resistance on the pore walls and the ionic resistance of electrolytes confined in pores. The pore size gradient framework also shows excellent electrochemical performance, such as stable capacity retention over 760 cycles with 0.5 mAh cm–2 at 2 mA cm–2. These findings provide fundamental insights into strategies to improve the electrochemical performance of porous frameworks for Li metal batteries.

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Section: Introductionmentioning

confidence: 99%

Three-Dimensional Porous Frameworks for Li Metal Batteries: Superconformal versus Conformal Li Growth

Lee

Won

Kim

et al. 2021

ACS Appl. Mater. Interfaces

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“…The carbonate-based organic electrolyte used in the current LIBs has been optimized to maximize the cell performance for lithium transition metal oxide cathodes and graphite anodes but is not suitable for LMBs because of the high reactivity of metallic lithium and low reduction stability of carbonates. − Many studies have been conducted on electrolytes with high compatibility with metallic lithium and high reduction stability, and it has been revealed that the ether-based 1,2-dimethoxyethane (DME) solvent exhibits the best performance in LMBs. − However, due to the lower oxidation stability of DME compared to carbonates, it is difficult to use ethers with commercial cathode materials such as LiCoO 2 and LiNi x Mn y Co 1– x – y O 2 that have a high reaction voltage of approximately 4 V ( vs Li/Li + ). To increase the oxidation stability, a high-concentration electrolyte system has been considered due to the increased oxidation stability of the DME participating in the solvation of lithium ions. − However, increasing salt concentration is directly related to an increase in the viscosity and a decrease in ionic conductivity that result in an increase in the cell resistance and poor rate capability.…”

Section: Introductionmentioning

confidence: 99%

High-Voltage-Compatible Dual-Ether Electrolyte for Lithium Metal Batteries

Jang

Sugimoto

Mizumo

et al. 2021

ACS Appl. Energy Mater.

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To improve the energy density of rechargeable batteries, lithium metal batteries (LMBs) consisting of high-voltage cathodes and metallic lithium anodes have been actively studied. Ether-based organic electrolytes, particularly 1,2-dimethoxyethane (DME), show good performance for LMB anodes, but due to low oxidation stability, they are difficult to apply in conjunction with high-reaction-voltage cathodes such as lithium cobalt oxide (LCO). Here, a dual-solvent system with fluorinated ether with high oxidative stability added as a co-solvent is used to increase the electrolyte oxidation stability. It is found that tetrafluoroethyl tetrafluoropropyl ether (TTE) is most suitable for use as the co-solvent, due to its non-solvation of Li salts and miscibility with DME arising from its non-polar nature. Introduction of a DME/TTE dual solvent with 1.0 M lithium bis(fluorosulfonyl)imide (LiFSI) increases the concentration of the salt coordinated by DME to an ultra-high electrolyte concentration of 5.0 M LiFSI. The oxidation stability of the electrolyte is improved by increasing the amount of the DME–Li+ complex. The DME/TTE ratio and the Li salt concentration of the dual-ether electrolyte are optimized through physical and electrochemical analyses. Compared to the conventional carbonated electrolyte, the dual-ether electrolyte shows low resistance and improved cycle performance in LMBs with an LCO cathode.

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“…9,10 It is generally considered that the volume variation of polycrystalline NCM originates from randomly oriented primary particles as the cause of boundary cracks, resulting in the attenuation of capacity and destruction of the overall structure. 11,12 Meanwhile, the pores gradually generated inside polycrystalline NCM will not only increase the contact area at the cathode/ electrolyte interface but also provide reaction sites with the electrolyte, leading to terrible side reactions and safety issues. 13 Moreover, the original layered phase (R3̅ m) is easily induced to transform into a cation disordered spinel (Fd3̅ m) and rock salt phase (Fm3̅ m) because of the de/intercalation of the lithium ion during electrochemical cycling, resulting in the release of lattice oxygen and further breakdown.…”

Section: ■ Introductionmentioning

confidence: 99%

“…In the past few decades, extensive reports have focused on polycrystalline NCM cathodes due to their high energy density. It needs to point out that such NCM cathode materials generally display micrometer-scale spherical secondary particles (size ≈ 10 μm) formed by submicrometer-level primary particles (size ≈ 300–500 nm). , It is generally considered that the volume variation of polycrystalline NCM originates from randomly oriented primary particles as the cause of boundary cracks, resulting in the attenuation of capacity and destruction of the overall structure. , Meanwhile, the pores gradually generated inside polycrystalline NCM will not only increase the contact area at the cathode/electrolyte interface but also provide reaction sites with the electrolyte, leading to terrible side reactions and safety issues . Moreover, the original layered phase ( R 3̅ m ) is easily induced to transform into a cation disordered spinel ( Fd 3̅ m ) and rock salt phase ( Fm 3̅ m ) because of the de/intercalation of the lithium ion during electrochemical cycling, resulting in the release of lattice oxygen and further breakdown. − To tackle these defects, innovative and effective strategies should be able to tune the crystal structure and morphology to suppress both internal microcrack and structural failure. , …”

Section: Introductionmentioning

confidence: 99%

In Situ Tuning Residual Lithium Compounds and Constructing TiO₂ Coating for Surface Modification of a Nickel-Rich Cathode toward High-Energy Lithium-Ion Batteries

Wang

et al. 2020

ACS Appl. Energy Mater.

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Nickel-rich layered oxides with excellent specific capacity and reasonable cost have extensively employed as cathode materials for higher energy density lithium-ion batteries (LIBs). However, side reactions caused by the surface contaminations and deterioration of the layered structure especially at high cutoff voltage lead to insufficient cycle life and poor electrochemical performance, which further hinder the commercial development of nickel-rich cathode materials. Herein, an optimized route combining acid treatment with titanium dioxide (TiO 2 ) coating successfully modifies the surface of the single-crystalline LiNi 0.6 Co 0.2 Mn 0.2 O 2 (SC-NCM) cathode material, which collaboratively eliminates surface residual contaminations and stabilizes the bulk structure. Furthermore, the evolution of the internal crack, phase transition, and host structure can be effectively mitigated via applying the TiO 2 coating on SC-NCM even after long-term cycling. Moreover, it is confirmed that such surface treatment significantly impedes the conversion of surface residual lithium after air exposure. As the cathode material for LIBs, as-optimized SC-NCM delivers a capacity retention of 87.4% at 1 C over 200 cycles at room temperature, higher than that of pristine SC-NCM (a capacity retention of 73.5%). This proposed method provides a simple and available strategy to obtain prolonged service life and safety characteristics of LIBs.

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In Situ Interfacial Tuning To Obtain High-Performance Nickel-Rich Cathodes in Lithium Metal Batteries

Cited by 13 publications

References 42 publications

Three-Dimensional Porous Frameworks for Li Metal Batteries: Superconformal versus Conformal Li Growth

Three-Dimensional Porous Frameworks for Li Metal Batteries: Superconformal versus Conformal Li Growth

High-Voltage-Compatible Dual-Ether Electrolyte for Lithium Metal Batteries

In Situ Tuning Residual Lithium Compounds and Constructing TiO₂ Coating for Surface Modification of a Nickel-Rich Cathode toward High-Energy Lithium-Ion Batteries

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In Situ Interfacial Tuning To Obtain High-Performance Nickel-Rich Cathodes in Lithium Metal Batteries

Cited by 13 publications

References 42 publications

Three-Dimensional Porous Frameworks for Li Metal Batteries: Superconformal versus Conformal Li Growth

Three-Dimensional Porous Frameworks for Li Metal Batteries: Superconformal versus Conformal Li Growth

High-Voltage-Compatible Dual-Ether Electrolyte for Lithium Metal Batteries

In Situ Tuning Residual Lithium Compounds and Constructing TiO2 Coating for Surface Modification of a Nickel-Rich Cathode toward High-Energy Lithium-Ion Batteries

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Product

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In Situ Tuning Residual Lithium Compounds and Constructing TiO₂ Coating for Surface Modification of a Nickel-Rich Cathode toward High-Energy Lithium-Ion Batteries