Anion-Induced Uniform and Robust Cathode–Electrolyte Interphase for Layered Metal Oxide Cathodes of Sodium Ion Batteries

Wu, Minli; Zhang, Bei; Ye, Yonghuang; Fu, Liang; Xie, Hualin; Jin, Haizu; Tang, Yougen; Wang, Haiyan; Sun, Dan

doi:10.1021/acsami.4c00199

ACS Appl. Mater. Interfaces

2024

DOI: 10.1021/acsami.4c00199

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Anion-Induced Uniform and Robust Cathode–Electrolyte Interphase for Layered Metal Oxide Cathodes of Sodium Ion Batteries

Minli Wu,

Bei Zhang,

Yonghuang Ye

et al.

Abstract: Layer metal oxides demonstrate great commercial application potential in sodium-ion batteries, while their commercialization is extremely hampered by the unsatisfactory cycling performance caused by the irreversible phase transition and interfacial side reaction. Herein, trimethoxymethylsilane (TMSI) is introduced into electrolytes to construct an advanced cathode/ electrolyte interphase by tuning the solvation structure of anions. It is found that due to the stronger interaction between ClO 4 − and TMSI than … Show more

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Cited by 4 publications

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Enhancing Li⁺ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO₃ and Vinylene Carbonate

Quan,

Cui,

et al. 2024

Carbon Neutralization

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The solvent‐rich solvent sheath in low‐concentration electrolytes (LCEs) not only results in high desolvation energy of Li+, but also forms organic‐rich solid electrolyte interface film (SEI) with poor Li+ conductivity, which hinders Li+ transport at the electrode‐electrolyte interface and greatly limits the application of LCEs. Here, the electrochemical performance of the LCEs is enhanced by dual interfacial modification with LiNO3 and vinylene carbonate (VC) additives. Results show that LiNO3 is preferentially reduced at about 1.65 V to form an inorganic‐rich but incomplete SEI inner layer. The formation of Li3N and LiNxOy inorganic components helps to achieve rapid Li+ transport in the SEI film, and the bare electrode surface caused by the incomplete SEI inner layer provides a place for the subsequent decomposition of VC. Then, at a lower potential of about 0.73 V, VC is reduced to generate the poly(VC)‐rich SEI outer layer, which provides lithium‐philic sites and greatly weakens the interaction between Li+ and ethylene carbonate (EC). The interaction modulates the Li+ solvation structure at the interface and reduces the desolvation energy of Li+. This ingenious design of the bilayer SEI film greatly enhances Li+ transport and inhibits the decomposition of traditional carbonate solvents and the swelling of graphite. As a result, the electrochemical performance of the battery using 0.5 M LiPF6 EC/diethyl carbonate (DEC) + 0.012 M LiNO3 + 0.5 vt% VC is improved to a higher level than the one using 1.0 M LiPF6 EC/DEC electrolyte. This research expands the design strategy and promising applications of LCEs by constructing a favorable SEI to enhance Li+ transport at the electrode‐electrolyte interface.

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Enhancing Li⁺ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO₃ and Vinylene Carbonate

Quan,

Cui,

et al. 2024

Carbon Neutralization

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Sodiophilic Interface and Electrolyte Regulation Boost the Lifespan of Anode‐Free Sodium Battery

Ji,

Xie,

Zhang

et al. 2024

SusMat

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Anode‐free sodium batteries (AFSBs) have attracted increasing attention for their high energy density. However, they suffer from rapid capacity decline resulting from sodium dendrite growth at the sodium/host interface and irreversible side reactions at the electrolyte/sodium interface. Herein, a GaInSn‐coated Cu foil (G‐Cu), prepared by a simple brush coating method, was applied as the sodiophilic current collector to regulate sodium nucleation behavior. In addition, a nonexpendable functional electrolyte additive, hexamethyldisiloxane (HMDSO), was introduced, which could be absorbed on the sodium surface and serve as a protective layer against corrosion side reactions at the electrolyte/sodium interface. It is interesting to note that this additive barely participated in forming the solid electrolyte interphase. The synergetic effects of sodiophilic interface design and electrolyte regulation enable reversible sodium plating and stripping. Ultimately, the AFSB assembled using G‐Cu and HMDSO electrolyte with a highly loaded Na3V2(PO4)3 cathode (≈12.5 mg cm−2) delivers a discharge capacity of 84.5 mAh g−1 after 200 cycles with a high capacity retention of 87.6%, significantly extending its operation lifespan.

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Study on the impact of cutoff voltage on structural and electrochemical stability of sodium-ion layered cathodes

Wang,

Xu,

Fan

et al. 2024

Chemical Engineering Journal

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Anion-Induced Uniform and Robust Cathode–Electrolyte Interphase for Layered Metal Oxide Cathodes of Sodium Ion Batteries

Cited by 4 publications

References 50 publications

Enhancing Li⁺ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO₃ and Vinylene Carbonate

Enhancing Li⁺ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO₃ and Vinylene Carbonate

Sodiophilic Interface and Electrolyte Regulation Boost the Lifespan of Anode‐Free Sodium Battery

Study on the impact of cutoff voltage on structural and electrochemical stability of sodium-ion layered cathodes

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Anion-Induced Uniform and Robust Cathode–Electrolyte Interphase for Layered Metal Oxide Cathodes of Sodium Ion Batteries

Cited by 4 publications

References 50 publications

Enhancing Li+ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO3 and Vinylene Carbonate

Enhancing Li+ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO3 and Vinylene Carbonate

Sodiophilic Interface and Electrolyte Regulation Boost the Lifespan of Anode‐Free Sodium Battery

Study on the impact of cutoff voltage on structural and electrochemical stability of sodium-ion layered cathodes

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Product

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Enhancing Li⁺ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO₃ and Vinylene Carbonate

Enhancing Li⁺ Transportation at Graphite‐Low Concentration Electrolyte Interface Via Interphase Modulation of LiNO₃ and Vinylene Carbonate