Synergistic Effects on Lithium Metal Batteries by Preferential Ionic Interactions in Concentrated Bisalt Electrolytes

Pham, Thuy Duong; Faheem, Abdullah Bin; Chun, So Yeon; Rho, Jung‐Rae; Kwak, Kyungwon; Lee, Kyungkoo

doi:10.1002/aenm.202003520

Cited by 44 publications

(55 citation statements)

References 69 publications

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“…[1,3] To deal with the aforementioned issues, a variety of solutions have been investigated. Considerable efforts have been devoted to the formation of a sound SEI layer on the Li anode and these include but are not limited to adding additives into conventional electrolytes, [7][8][9][10] using highly concentrated electrolytes including localized high concentration electrolytes, [4,[11][12][13][14][15][16] and employing different organic solvents. [17][18][19][20][21] Recently, highly concentrated electrolytes have attracted great attention.…”

Section: So Far the Practical Application Of LI Metal Batteries Has Been Hindered By The Undesirable Formation Of Li Dendrites And Low Comentioning

confidence: 99%

Simultaneous Stabilization of the Solid/Cathode Electrolyte Interface in Lithium Metal Batteries by a New Weakly Solvating Electrolyte

Pham

Lee

2021

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So far, the practical application of Li metal batteries has been hindered by the undesirable formation of Li dendrites and low Coulombic efficiencies (CEs). Herein, 1,2‐diethoxyethane (DEE) is proposed as a new electrolytic solvent for lithium metal batteries (LMBs), and the performances of 1.0 m LiFSI in DEE are evaluated. Because of the low dielectric constant and dipole moment of DEE, the majority of the FSI− exists in associated states like contact ion pairs and aggregates, which is similar to the highly concentrated electrolytes. These associated complexes are involved in the reduction reaction on the Li metal anode, forming sound solid electrolyte interphase layers. Furthermore, free FSI− ions in DEE are observed to participate in the formation of cathode electrolyte interphase layers. These passivation layers not only suppress dendrite growth on the Li anode but also prevent unwanted side‐reactions on the LiFePO4 cathode. The average CE of the Li||Cu cells in LiFSI–DEE is observed to be 98.0%. Moreover, LiFSI–DEE also plays an important role in enhancing the cycling stability of the Li||LiFP cell with a capacity retention of 93.5% after 200 cycles. These results demonstrate the benefits of LiFSI–DEE, which creates new possibilities for high‐energy‐density rechargeable LMBs.

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Section: So Far the Practical Application Of LI Metal Batteries Has Been Hindered By The Undesirable Formation Of Li Dendrites And Low Comentioning

confidence: 99%

Simultaneous Stabilization of the Solid/Cathode Electrolyte Interface in Lithium Metal Batteries by a New Weakly Solvating Electrolyte

Pham

Lee

2021

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“…[ 21 , 22 , 23 ] Compared with the concentrated mono‐salt, the concentrated dual‐salt effectively improves the ion conductivity of the high‐concentration electrolyte (HCE) system. [ 24 ] Although the problem of lithium anode has been alleviated to some extent, to our knowledge, there is still a gap between the performances of present lithium metal batteries and practical application. Calculation and simulation, such as, molecular dynamic simulation and phase field model, are used to propose new directions for the improvement of host materials, electrolyte formulations, etc.…”

Section: Introductionmentioning

confidence: 99%

Confronting the Challenges in Lithium Anodes for Lithium Metal Batteries

et al. 2021

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With the low redox potential of −3.04 V (vs SHE) and ultrahigh theoretical capacity of 3862 mAh g −1 , lithium metal has been considered as promising anode material. However, lithium metal battery has ever suffered a trough in the past few decades due to its safety issues. Over the years, the limited energy density of the lithium-ion battery cannot meet the growing demands of the advanced energy storage devices. Therefore, lithium metal anodes receive renewed attention, which have the potential to achieve high-energy batteries. In this review, the history of the lithium anode is reviewed first. Then the failure mechanism of the lithium anode is analyzed, including dendrite, dead lithium, corrosion, and volume expansion of the lithium anode. Further, the strategies to alleviate the lithium anode issues in recent years are discussed emphatically. Eventually, remaining challenges of these strategies and possible research directions of lithium-anode modification are presented to inspire innovation of lithium anode.

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“…The structure of Li + solvates in concentrated electrolytes has a significant impact on Li + transport and is influential in the rate capability of rechargeable lithium ion batteries (LIBs) (Borodin et al, 2018;Yamada et al, 2019;Krachkovskiy et al, 2020;Pham et al, 2021). ILs present an extreme case of a concentrated electrolyte where the electrolyte is made entirely of discrete ions and lacks neutral solvent molecules.…”

Section: Introductionmentioning

confidence: 99%

“…These properties are desirable for lithium battery systems and thus are of great interest for safe, high-density energy storage devices (Galinski et al, 2006;Bae et al, 2013;Navarra, 2013;Eftekhari et al, 2016). However, Li + transport in ILs is complex and hindered by the high viscosity, mainly due to Coulombic interactions and specific Li + -anion interactions, which leads to the formation of clusters that decrease the mobility of Li + in the bulk liquid (Lesch et al, 2014;Pham et al, 2021). Li + transport in ILs has been studied mostly by Raman spectroscopy, nuclear magnetic resonance spectroscopy, transference measurements, density functional theory (DFT), and classical molecular dynamic (MD) simulations (Borodin et al, 2006;Umebayashi et al, 2007;Duluard et al, 2008;Lassègues et al, 2009;Umebayashi et al, 2010;Castiglione et al, 2011;Fujii et al, 2013;Haskins et al, 2014;Borodin et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Energetics of Li+ Coordination with Asymmetric Anions in Ionic Liquids by Density Functional Theory

et al. 2021

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The energetics, coordination, and Raman vibrations of Li solvates in ionic liquid (IL) electrolytes are studied with density functional theory (DFT). Li+ coordination with asymmetric anions of cyano(trifluoromethanesulfonyl)imide ([CTFSI]) and (fluorosulfonyl)(trifluoro-methanesulfonyl)imide ([FTFSI]) is examined in contrast to their symmetric analogs of bis(trifluoromethanesulfonyl)imide ([TFSI]), bis(fluorosulfonyl)imide ([FSI]), and dicyanamide ([DCA]). The dissociation energies that can be used to describe the solvation strength of Li+ are calculated on the basis of the energetics of the individual components and the Li solvate. The calculated dissociation energies are found to be similar for Li+-[FTFSI], Li+-[TFSI], and Li+-[FSI] where only Li+-O coordination exists. Increase in asymmetry and anion size by fluorination on one side of the [TFSI] anion does not result in significant differences in the dissociation energies. On the other hand, with [CTFSI], both Li+-O and Li+-N coordination are present, and the Li solvate has smaller dissociation energy than the solvation by [DCA] alone, [TFSI] alone, or a 1:1 mixture of [DCA]/[TFSI] anions. This finding suggests that the Li+ solvation can be weakened by asymmetric anions that promote competing coordination environments through enthalpic effects. Among the possible Li solvates of (Li[CTFSI]n)−(n−1), where n = 1, 2, 3, or 4, (Li[CTFSI]2)−1 is found to be the most stable with both monodentate and bidentate bonding possibilities. Based on this study, we hypothesize that the partial solvation and weakened solvation energetics by asymmetric anions may increase structural heterogeneity and fluctuations in Li solvates in IL electrolytes. These effects may further promote the Li+ hopping transport mechanism in concentrated and multicomponent IL electrolytes that is relevant to Li-ion batteries.

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Synergistic Effects on Lithium Metal Batteries by Preferential Ionic Interactions in Concentrated Bisalt Electrolytes

Cited by 44 publications

References 69 publications

Simultaneous Stabilization of the Solid/Cathode Electrolyte Interface in Lithium Metal Batteries by a New Weakly Solvating Electrolyte

Simultaneous Stabilization of the Solid/Cathode Electrolyte Interface in Lithium Metal Batteries by a New Weakly Solvating Electrolyte

Confronting the Challenges in Lithium Anodes for Lithium Metal Batteries

Energetics of Li+ Coordination with Asymmetric Anions in Ionic Liquids by Density Functional Theory

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