Polysulfide Shuttle Suppression by Electrolytes with Low‐Density for High‐Energy Lithium–Sulfur Batteries

Weller, Christine; Pampel, Jonas; Dörfler, Susanne; Althues, Holger; Kaskel, Stefan

doi:10.1002/ente.201900625

Cited by 65 publications

(92 citation statements)

References 60 publications

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“…[119] Selective non-solvating electrolyte demonstrates the solvating power strong enough to dissolve the supporting salt but too weak to solvate the polysulfide. [120] Fluorination of some ether solvent molecules in standard electrolyte is an effective strategy to obtain such a selective non-solvating electrolyte under a low E/S ratio of 6.5 mL mg S À1 . [121] Except for leanelectrolyte operability, a mixture of hydrofluoro ether and sulfolane also inhibited the gas-producing behavior of pouch cells benefiting from their low volatility.…”

Section: Liquid-electrolyte Designmentioning

confidence: 99%

Lithium–Sulfur Batteries under Lean Electrolyte Conditions: Challenges and Opportunities

et al. 2020

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The development of energy‐storage devices has received increasing attention as a transformative technology to realize a low‐carbon economy and sustainable energy supply. Lithium–sulfur (Li–S) batteries are considered to be one of the most promising next‐generation energy‐storage devices due to their ultrahigh energy density. Despite the extraordinary progress in the last few years, the actual energy density of Li–S batteries is still far from satisfactory to meet the demand for practical applications. Considering the sulfur electrochemistry is highly dependent on solid‐liquid‐solid multi‐phase conversion, the electrolyte amount plays a primary role in the practical performances of Li–S cells. Therefore, a lean electrolyte volume with low electrolyte/sulfur ratio is essential for practical Li–S batteries, yet under these conditions it is highly challenging to achieve acceptable electrochemical performances regarding sulfur kinetics, discharge capacity, Coulombic efficiency, and cycling stability especially for high‐sulfur‐loading cathodes. In this Review, the impact of the electrolyte/sulfur ratio on the actual energy density and the economic cost of Li–S batteries is addressed. Challenges and recent progress are presented in terms of the sulfur electrochemical processes: the dissolution–precipitation conversion and the solid–solid multi‐phasic transition. Finally, prospects of future lean‐electrolyte Li–S battery design and engineering are discussed.

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Section: Liquid-electrolyte Designmentioning

confidence: 99%

Lithium–Sulfur Batteries under Lean Electrolyte Conditions: Challenges and Opportunities

et al. 2020

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“…As a result, high-concentration electrolytes i.e., room-temperature ionic liquids, (Park et al, 2013a,b;Song et al, 2013b) solvent-in-salt, (Suo et al, 2013), and solvate ionic liquids (Dokko et al, 2013;Ueno et al, 2013;Zhang et al, 2016) have all proven quite effective at discouraging polysulfide dissolution, despite their high viscosity and subsequent poor lithium transport properties. More recently, several researchers have addressed this problem through dilution of concentrated electrolytes with poorly-coordinating solvents; work reported by Weller et al demonstrated a low-density electrolyte with high lithium salt concentration to suppress polysulfide dissolution using hexyl methyl ether in combination with DOL (Weller et al, 2019). The Wang group has recently reported good Li-S cell performance achieved from developing a "localized high concentration electrolyte" using a fluoroalkyl ether additive blended with DME electrolyte (Zheng et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

A Micelle Electrolyte Enabled by Fluorinated Ether Additives for Polysulfide Suppression and Li Metal Stabilization in Li-S Battery

et al. 2020

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The Li-S battery is a promising next-generation technology due to its high theoretical energy density (2600 Wh kg −1) and low active material cost. However, poor cycling stability and coulombic efficiency caused by polysulfide dissolution have proven to be major obstacles for a practical Li-S battery implementation. In this work, we develop a novel strategy to suppress polysulfide dissolution using hydrofluoroethers (HFEs) with bi-functional, amphiphlic surfactant-like design: a polar lithiophilic "head" attached to a fluorinated lithiophobic "tail." A unique solvation mechanism is proposed for these solvents whereby dissociated lithium ions are readily coordinated with lithiophilic "head" to induce self-assembly into micelle-like complex structures. Complex formation is verified experimentally by changing the additive structure and concentration using small angle X-ray scattering (SAXS). These HFE-based electrolytes are found to prevent polysulfide dissolution and to have excellent chemical compatibility with lithium metal: Li||Cu stripping/plating tests reveal high coulombic efficiency (>99.5%), modest polarization, and smooth surface morphology of the uniformly deposited lithium. Li-S cells are demonstrated with 1395 mAh g −1 initial capacity and 71.9% retention over 100 cycles at >99.5% efficiency-evidence that the micelle structure of the amphiphilic additives in HFEs can prohibit polysulfide dissolution while enabling facile Li + transport and anode passivation.

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“…[29] Within the battery research community, significant efforts have been made to improve the performance of the cell components and materials used within Li-S batteries. [25,40,[48][49][50] The selected examples are briefly summarized below.…”

Section: Limitationsmentioning

confidence: 99%

“…To tackle the issue of a low volumetric energy density (in Wh L À1 ), the mass density of the electrolyte is less important than for gravimetric energy density (in Wh kg À1 ). [49] Reducing the content of electrolyte from 3 to 1.5 μL or per mg of S active material [24] will decrease the weight of the electrolyte and the free volume required for its uptake. This is of importance, as in all known Li-S cell concepts, the electrolyte may take a large fraction of the cell (>40 % of the cell weight and volume [23,52] ).…”

Section: Energy (Gravimetric Vs Volumetric)mentioning

confidence: 99%

Recent Progress and Emerging Application Areas for Lithium–Sulfur Battery Technology

et al. 2020

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With the ever-increasing need for electrification across many application sectors, the development of new energy-storage technologies is of increasing relevance and critical importance. Electrification is progressing significantly within the traditional transportation sectors such as electric bikes, cars, buses, and other commercial vehicles, enabled by continued cell development and Gigafactory-scale mass production of Li-ion battery (LIB) technology. However, two key factors are starting to drive the need for new solutions to be found. One factor is the secure supply of key elements-mainly cobalt and nickelused in most of the conventional Li-ion cells which are becoming increasingly critical. The other is the performance requirements of desirable emerging application areas that are beyond the capabilities of traditional LIB technology. Examples include large commercial vehicles, [1] high-altitude long endurance (HALE), high-altitude pseudosatellites (HAPS), electric vertical takeoff and landing (eVTOL), [2] and electric passenger aircraft. The weight of the battery system (BSM) is an especially critical factor for these aviation applications. The battery systems' performance requirements differ across these applications: power, cycle life, system cost, etc. However, the need for a high gravimetric energy density, 400 Wh kg À1 and beyond, is common across them all. Higher energy battery systems will enable these vehicles to achieve extended range, a longer mission duration, lighter vehicle weight, or increased payload. In the following sections, key advantages, limitations, and progress made to extend cycle life, energy, power, and safety of Li-S battery management systems (BMS) are described. Further, recent advances regarding modeling, battery system management, and the integration of Li-S batteries into present as well as future real-world applications are summarized. 2. Lithium-Sulfur Battery Technology 2.1. Advantages LIB systems are the current technology of choice for many applications; however, the achievable specific energy reaches a maximum at around 240-300 Wh kg À1 at the cell level. [3] Emerging

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Polysulfide Shuttle Suppression by Electrolytes with Low‐Density for High‐Energy Lithium–Sulfur Batteries

Cited by 65 publications

References 60 publications

Lithium–Sulfur Batteries under Lean Electrolyte Conditions: Challenges and Opportunities

Lithium–Sulfur Batteries under Lean Electrolyte Conditions: Challenges and Opportunities

A Micelle Electrolyte Enabled by Fluorinated Ether Additives for Polysulfide Suppression and Li Metal Stabilization in Li-S Battery

Recent Progress and Emerging Application Areas for Lithium–Sulfur Battery Technology

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