Tuning the Electron Density of Aromatic Solvent for Stable Solid‐Electrolyte‐Interphase Layer in Carbonate‐Based Lithium Metal Batteries

Yoo, Dong‐Joo; Yang, Sungyun; Yun, Yang; Choi, Jeong‐Yoon; Yoo, Dongwon; Kim, Ki Jae; Choi, Jang Wook

doi:10.1002/aenm.201802365

Cited by 50 publications

(33 citation statements)

References 55 publications

(41 reference statements)

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“…Numerous approaches have been proposed to address issues associated with Li‐dendrite growth. A variety of electrolyte additives were introduced, including Cs + and Rb + , ionic liquids, co‐solvents, vinylene carbonate, LiNO 3 and polysulfides . These additives were used to promote stable SEI layers by enhancing the mechanical properties and the Li‐ion diffusivity or manipulating electrostatic fields near the Li electrode surface.…”

Section: Figurementioning

confidence: 99%

“…[2] Numerous approaches have been proposed to address issues associated with Li-dendrite growth. Av ariety of electrolyte additives were introduced, including Cs + and Rb + , [3] ionic liquids, [4] co-solvents, [5] vinylene carbonate, [6] LiNO 3 and polysulfides. [7] These additives were used to promote stable SEI layers by enhancing the mechanical properties and the Li-ion diffusivity or manipulating electrostatic fields near the Li electrode surface.T he addition of lithium fluoride (LiF) was found to be particularly beneficial [8] from the perspective of both, mechanical stability and ionic conductivity.I na na ttempt to enhance the mechanical stability of SEI layers and Li-host structures,m ore recently also elastic polymers were incorporated.…”

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confidence: 99%

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Lithium‐Salt Mediated Synthesis of a Covalent Triazine Framework for Highly Stable Lithium Metal Batteries

et al. 2019

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A new strategy for the synthesis of a covalent triazine framework (CTF‐1) was introduced based on the cyclotrimerization reaction of 1,4‐dicyanobenzene using lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) under ionothermal conditions. LiTFSI not only served as a catalyst, but also facilitated the in situ generation and homogeneous distribution of LiF particles across the framework. The hierarchical structure resulting upon integration of CTF‐LiF onto an airlaid‐paper (AP) offered unique features for lithium metal anodes, such as lithiophilicity from CTF, interface stabilization from LiF, and sufficient lithium storage space from AP. Based on this synergistic effect, the AP‐CTF‐LiF anode exhibited stable cycling performance even at a current density of 10 mA cm−2.

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Section: Figurementioning

confidence: 99%

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Lithium‐Salt Mediated Synthesis of a Covalent Triazine Framework for Highly Stable Lithium Metal Batteries

et al. 2019

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“…The other approach is to stabilize the SEI. Strategies including the exploitation of electrolyte additives (24)(25)(26)(27)(28), artificial protection layers (29)(30)(31)(32), and solid-state electrolytes (4,(33)(34)(35)(36) have been developed to regulate and modify the physicochemical properties of the Li/electrolyte interface (37), leading to uniform Li + ion flux distribution and thus stable Li electroplating. At present, most reported protocols, however, only focused on either inducing uniform Li nucleation or stabilizing the SEI.…”

Section: Introductionmentioning

confidence: 99%

An ultrastable lithium metal anode enabled by designed metal fluoride spansules

et al. 2020

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The lithium metal anode (LMA) is considered as a promising star for next-generation high-energy density batteries but is still hampered by the severe growth of uncontrollable lithium dendrites. Here, we design “spansules” made of NaMg(Mn)F3@C core@shell microstructures as the matrix for the LMA, which can offer a long-lasting release of functional ions into the electrolyte. By the assistance of cryogenic transmission electron microscopy, we reveal that an in situ–formed metal layer and a unique LiF-involved bilayer structure on the Li/electrolyte interface would be beneficial for effectively suppressing the growth of lithium dendrites. As a result, the spansule-modified anode affords a high Coulombic efficiency of 98% for over 1000 cycles at a current density of 2 mA cm−2, which is the most stable LMA reported so far. When coupling this anode with the Li[Ni0.8Co0.1Mn0.1]O2 cathode, the practical full cell further exhibits highly improved capacity retention after 500 cycles.

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“…In a recent study, Yoo et al suggested aromatic compounds with different functional groups as electrolyte solvents for the formation of a stable SEI layer in carbonatebased Li metal batteries. [203] To form a uniform and rigid SEI layer on the Li metal, the study used the bonding characteristics of benzene rings that do leading to polymeric branch structures in polymerization after initiating itself due to being three double bonds resonance. In addition, three different aromatic compounds, benzene (Ben), toluene (Tol), and trifluorotoluene (Tof), were chosen for the study because the electron density determined by the functional group attached to the benzene group was found to influence the polymerization, as shown in Figure 11a.…”

Section: Artificial Layers Driven By Electrolyte Component Decompositionmentioning

confidence: 99%

Lithium Metal Interface Modification for High‐Energy Batteries: Approaches and Characterization

Lee

Song

Cho

et al. 2020

Batteries & Supercaps

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Rechargeable batteries have been a profoundly greater part of our lives than we could have ever imagined. The rechargeable Li‐ion batteries (LIBs) that have been developed for transport systems even put fossil fuels in the corner. However, state‐of‐the‐art Li‐ion batteries with graphite anodes are now approaching their theoretical specific energy limits, so they cannot meet the increasing demands of a range of portable electronics and large‐scale energy storage systems. Li metal is one of the most promising anode materials that could break through the energy density bottleneck of Li‐ion batteries due to its ultrahigh specific capacity and very low potential compared to other anode materials. Nonetheless, the direct use of Li metal in commercial battery systems has been hindered due to significant obstacles associated with it such as safety issues, corrosion from chemical reactions that occur inside the battery, or poor cycling performance. The fundamental reason for these problems is the dendritic growth of Li‐ions on the Li metal anode during cycling, as a result of the interfacial phenomena of Li metal and electrolytes. Modification of the Li metal interface with an electrolyte presents an efficient solution to solve these problems. In this review, the current challenges facing the development of Li metal anodes are presented in detail. The most recent advances in Li metal anodes using a controlled interface between the Li metal surface and an electrolyte are highlighted and an introduction on the synthesis and production methods for the application of high‐energy‐density battery systems such as Li‐oxygen (Li−O2), Li‐sulfur (Li−S), and Li metal batteries with high‐energy density cathodes is presented. Furthermore, the recent developments in the in situ/operando analysis tools adopted for the investigation of Li metal anodes such as the structural and chemical changes, dynamic properties, and solid–electrolyte interface (SEI) layer properties are described and summarized. Finally, some suggestions are given in the direction of the development of Li metal with artificial surface layers for use in future high‐energy batteries.

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Tuning the Electron Density of Aromatic Solvent for Stable Solid‐Electrolyte‐Interphase Layer in Carbonate‐Based Lithium Metal Batteries

Cited by 50 publications

References 55 publications

Lithium‐Salt Mediated Synthesis of a Covalent Triazine Framework for Highly Stable Lithium Metal Batteries

Lithium‐Salt Mediated Synthesis of a Covalent Triazine Framework for Highly Stable Lithium Metal Batteries

An ultrastable lithium metal anode enabled by designed metal fluoride spansules

Lithium Metal Interface Modification for High‐Energy Batteries: Approaches and Characterization

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