The Solvation Structure of Lithium Ions in an Ether Based Electrolyte Solution from First-Principles Molecular Dynamics

Callsen, Martin; Sodeyama, Keitaro; Futera, Zdeněk; Tateyama, Yoshitaka; Hamada, Ikutaro

doi:10.1021/acs.jpcb.6b09203

Cited by 45 publications

(46 citation statements)

References 53 publications

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“…presence around the lithium ion. 42 However, hexane and cyclohexane are not present within the first two solvation shells around lithium, but TTE is (dashed line in 5g). A snapshot of the first solvation shell at a distance (r = 0.33 nm) further confirms this and the inset in Figure 5g shows that TTE is present within the first solvation shell whereas the insets in Figures 5e-f do not show hexane or cyclohexane present.…”

Section: Solvation Effectmentioning

confidence: 99%

Nonpolar Alkanes Modify Lithium‐Ion Solvation for Improved Lithium Deposition and Stripping

Amanchukwu

Kong

Qin

et al. 2019

Advanced Energy Materials

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Lithium metal batteries have been plagued by the high reactivity of lithium. Reactive additives that can passivate the lithium metal surface and limit electrolyte accessibility to a fresh lithium surface have been widely explored, but can have limited utility with continuous consumption of the additive. In this work, we explore an alternative strategy. We study the use of nonreactive cosolvents such as nonpolar alkanes and show that hexane and cyclohexane addition to ether solvents (1,3-dioxolane and 1,2-dimethoxyethane) halves the nucleation and growth overpotentials for lithium deposition, increases the cell coulombic efficiency, improves the lithium deposition morphology, increases the electrolyte oxidative stability (> 0.2V), and doubles the cycle life-even when compared to a widely used fluorinated ether. The nonpolar alkanes modify the lithium ion solvation environment and reduce the solvation free energy; hence reducing the reaction barrier for lithium deposition. Exploration of nonpolar alkanes as part of the electrolyte mixture is a promising strategy for controlling metal deposition.

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Section: Solvation Effectmentioning

confidence: 99%

Nonpolar Alkanes Modify Lithium‐Ion Solvation for Improved Lithium Deposition and Stripping

Amanchukwu

Kong

Qin

et al. 2019

Advanced Energy Materials

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“…[7][8][9][10][11][12] Although the basic assumptions underlying models of the ion transport processes in liquid electrolytes rely predominantly on simple physical diffusion of ions according to the Stokes-Einstein relationship, recent molecular dynamics simulation studies predicted that Li ion hopping or exchange mechanisms through frequent exchange of solvents and anions with labile Li ion coordination can contribute to the ionic conduction of highly concentrated electrolytes. [13][14][15] Despite low ionic conductivity and high viscosity, stable cycling of Li and Na ion batteries with high current density was reported for ionic liquid (IL)-based concentrated electrolytes. The improved rate capability was considered to be influenced by the increased mass transfer via ion hopping or exchange mechanisms through large ionic aggregates (Li m + X n À ) present in the IL-based concentrated electrolytes.…”

Section: Introductionmentioning

confidence: 99%

Ionic transport in highly concentrated lithium bis(fluorosulfonyl)amide electrolytes with keto ester solvents: structural implications for ion hopping conduction in liquid electrolytes

Kondou

Thomas

Mandai

et al. 2019

Phys. Chem. Chem. Phys.

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“…In additional to extensive experimental studies, FPMD simulations have started to be utilized to investigate properties of this new class of electrolytes. [170,[173][174][175] For instance, Yamada et al [173] employed FPMD simulations to unravel the unique electronic structures of the superconcentrated acetonitrile solution, which can be directly related to the enhanced reductive stability of the solution in lithium-ion batteries. However, the fundamental understanding of these complex electrolytes is generally still in its infancy, which continues to stimulate further theoretical studies in the near future.…”

Section: Organic Electrolytesmentioning

confidence: 99%

Ab initio simulations of liquid electrolytes for energy conversion and storage

Pham

2018

Int J of Quantum Chemistry

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Understanding physicochemical properties of liquid electrolytes is essential for predicting and optimizing device performance for a wide variety of emerging energy technologies, including photoelectrochemical water splitting, supercapacitors, and batteries. In this work, we review recent progress and open challenges in predicting structural, dynamical, and electronic properties of the liquids using first-principles approaches. We briefly summarize the basic concepts of first-principles molecular dynamics (FPMD), and we discuss how FPMD methods have enriched our understanding of a number of liquids, including aqueous solutions, organic electrolytes and ionic liquids. We also discuss technical challenges in extending FPMD simulations to the study of liquid electrolytes in more complex environments, including the interface between electrolytes and electrodes, which is a key component in many energy storage and conversion systems. K E Y W O R D S energy conversion and storage, first-principles simulations, liquid electrolytes 1 | INTRODUCTIONLiquid electrolytes are essential components in a wide variety of emerging energy and environmental technologies, including hydrogen production through solar-water-splitting, [1,2] supercapacitors, [3][4][5] ion batteries, [6][7][8] and ion-selective membranes. [9][10][11] Within these devices, a large number of liquids have been explored, ranging from aqueous solutions and ionic liquids to organic, redox-type, and solid-state electrolytes. At the same time, continuing progress has been made during the past several decades in the development of novel liquids. For example, recent studies show that the use of highly concentrated aqueous electrolytes could open new opportunities for the design of high-voltage aqueous lithium-ion batteries while also significantly improving battery safety. [12,13] For several energy storage and conversion systems, the understanding of structure, dynamics, and electronic properties of liquid electrolytes is essential for predicting and optimizing device performance. For example, desolvation of ions in sub-nanometer carbon electrodes is known to lead to improved capacitive performance. [14][15][16] Controlling transport of the lithium ion in organic electrolytes and at the interface with the graphite anode is key to the development of next-generation lithium ion batteries. [17][18][19][20] Tailoring the electronic structures of aqueous solutions for facilitated charge transfer at semiconductor/water interfaces in photoelectrochemical cells is critical for improving the efficiency of water-splitting reactions for hydrogen production. [21,22] Last but not least, understanding the electronic properties of liquid electrolytes is one of the prerequisites for manipulating the electrochemical stability of electrode-electrolyte interfaces in ion batteries and supercapacitors. [5,23] Structural, dynamical, and electronic properties of liquid electrolytes are often intertwined. For example, it is now widely accepted that the solvation structure of ions in liquid...

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The Solvation Structure of Lithium Ions in an Ether Based Electrolyte Solution from First-Principles Molecular Dynamics

Cited by 45 publications

References 53 publications

Nonpolar Alkanes Modify Lithium‐Ion Solvation for Improved Lithium Deposition and Stripping

Nonpolar Alkanes Modify Lithium‐Ion Solvation for Improved Lithium Deposition and Stripping

Ionic transport in highly concentrated lithium bis(fluorosulfonyl)amide electrolytes with keto ester solvents: structural implications for ion hopping conduction in liquid electrolytes

Ab initio simulations of liquid electrolytes for energy conversion and storage

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