Solvent Activity in Electrolyte Solutions Controls Electrochemical Reactions in Li-Ion and Li-Sulfur Batteries

Moon, Heejoon; Mandai, Toshihiko; Tatara, Ryoichi; Ueno, Kazuhide; Yamazaki, Azusa; Yoshida, Kazuki; Seki, Shiro; Dokko, Kaoru; Watanabe, Masayoshi

doi:10.1021/jp5128578

Cited by 143 publications

(196 citation statements)

References 70 publications

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“…98 Furthermore, the transport properties of solvate ILs are much better than conventional Li-doped ILs 113 and can be further improved by dilution with solvents that do not disrupt the solvate structures. 117,122 Consequently, solvate ILs are suitable for use as electrolytes in lithium ion batteries [111][112][113][114] and lithium-sulfur batteries. [115][116][117][118][119][120] The most striking and significant findings of our research on solvate ILs are the formation criteria of solvate ILs, 101 the enhanced oxidation stability of coordinating solvents, 95 the low coordinating properties of solvate cations and anions, and their electrode reactions with graphite.…”

Section: © -Conducting Ils and Solvate Ilsmentioning

confidence: 99%

“…[115][116][117][118][119][120] The most striking and significant findings of our research on solvate ILs are the formation criteria of solvate ILs, 101 the enhanced oxidation stability of coordinating solvents, 95 the low coordinating properties of solvate cations and anions, and their electrode reactions with graphite. 121,122 Figure 8 shows how the anionic structures of lithium salts affect the formation of solvate ILs. 99 The amount of free glyme, determined by Raman spectroscopy, strongly depends on the anionic structures [ Fig.…”

Section: © -Conducting Ils and Solvate Ilsmentioning

confidence: 99%

“…125 121 The success of the electrochemical intercalation/deintercalation can be correlated with the activity the Li + -solvating free solvent, and very low activity of such solvent makes electrochemical intercalation/deintercalation possible. 122 …”

Section: © -Conducting Ils and Solvate Ilsmentioning

confidence: 99%

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Design and Materialization of Ionic Liquids Based on an Understanding of Their Fundamental Properties

Watanabe

2016

Electrochemistry

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Ionic liquids (ILs) are defined as salts that have melting points lower than 100°C. Most are organic salts, and these may be designed and tailored to have suitable properties. ILs are recognized as a third group of solvents (and electrolytes), after water and organic solvents. They are characterized by their unique properties such as nonvolatilities, high thermal stabilities, and high ionic conductivities. In this article, our work on the design and preparation of ILs is briefly reviewed. The concept of ionicity is proposed as a metric to characterize the basic nature (dissociativity) of ILs, which is affected by the Lewis acidity/basicity of cations/anions (i.e., coulombic interactions), the directionality of interactions between cations and anions, and van der Waals interactions between ions. The ionicity of ILs is dominated by a subtle balance between coulombic and van der Waals interactions, which clearly discriminates ILs from conventional high-temperature inorganic molten salts. Here, the design of protic ILs for fuel cell electrolytes, electron-transporting ILs for dye-sensitized solar cell electrolytes, and Li + -conducting solvate ILs for lithium battery electrolytes are discussed based on an understanding of the fundamental properties of ILs. Furthermore, the combination of ILs with polymers and colloidal particles affords intriguing quasi-solid materials (ion gels), and the ion transport in these gels is decoupled from the mechanical relaxation time of these materials, yielding new solid electrolytes. The possibility of temperature and photo-sensitive solubility dependence of polymers in ILs allows the creation of stimuli-responsive materials. Finally, protic ILs/protic salts are demonstrated to be good precursors for N-doped carbon materials.

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Section: © -Conducting Ils and Solvate Ilsmentioning

confidence: 99%

Section: © -Conducting Ils and Solvate Ilsmentioning

confidence: 99%

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Design and Materialization of Ionic Liquids Based on an Understanding of Their Fundamental Properties

Watanabe

2016

Electrochemistry

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“…It has been reported that the stable charge-discharge operation of these anodes is possible in the LiTFSA-G4 solvate ionic liquid. [9][10][11][12][13] However, these anode materials have to be lithated before combining with the S cathode. The Li metal anode is preferred to these anode materials without Li.…”

Section: Introductionmentioning

confidence: 99%

Electrochemical Deposition and Dissolution of Lithium on a Carbon Fiber Composite Electrode in a Solvate Ionic Liquid

et al. 2017

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Electrochemical deposition and dissolution of Li metal on a carbon fiber composite electrode were investigated in lithium bis(trifluoromethylsulfonyl)amide-tetraglyme solvate ionic liquid electrolyte. The carbon fiber composite coated on a Cu substrate was composed of vapor-grown carbon fiber (VGCF ® -H) and poly(vinylidene fluoride). The coulombic efficiency for dissolution of Li deposits on the VGCF ® -H modified Cu electrode was kept more than 98% at 100th cycle and higher than that on a Cu electrode in the solvate ionic liquid. Li was deposited in the porous structure of the VGCF ® -H modified Cu electrode and scarcely observed on the surface of the VGCF ® -H modified Cu probably because the overpotential for the reduction of Li is smaller on the Cu substrate and/or deposited Li than that on the cylindrical basal plane of VGCF ® -H. This result suggests that the voids in the carbon fiber network effectively act as the Li deposition sites at the electrode|separator interface in the coin cell.

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“…5,6 We have previously reported that ionic liquid and solvate ionic liquid electrolytes suppress the dissolution of lithium polysulfides. [7][8][9][10][11] The Li metal anode also has serious disadvantages. The dendritic growth of Li metal occurs in the cell during the charging process, especially at high current densities.…”

Section: Introductionmentioning

confidence: 99%

Si/Li<sub>2</sub>S Battery with Solvate Ionic Liquid Electrolyte

Kamei

Haruta

et al. 2016

Electrochemistry

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A lithium-sulfur cell was developed, consisting of a Si nanoflake negative electrode, a Li 2 S/graphene positive electrode, and a non-flammable solvate ionic liquid electrolyte. This cell configuration allows us to avoid the use of Li metal electrode and the concomitant dendritic deposition of Li metal at the negative electrode during charging, thereby rendering the cell operation highly safe and stable. The solvate ionic liquid electrolyte solution was composed of tetraglyme, lithium bis(trifluoromethanesulfonyl)amide, and a hydrofluoroether. The solubility of lithium polysulfide (reaction intermediate of the positive electrode) is very low, resulting in high Coulombic efficiency of discharge/charge and long cycle life of the Si/Li 2 S cell.

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Solvent Activity in Electrolyte Solutions Controls Electrochemical Reactions in Li-Ion and Li-Sulfur Batteries

Cited by 143 publications

References 70 publications

Design and Materialization of Ionic Liquids Based on an Understanding of Their Fundamental Properties

Design and Materialization of Ionic Liquids Based on an Understanding of Their Fundamental Properties

Electrochemical Deposition and Dissolution of Lithium on a Carbon Fiber Composite Electrode in a Solvate Ionic Liquid

Si/Li<sub>2</sub>S Battery with Solvate Ionic Liquid Electrolyte

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