Redox-Active Supramolecular Polymer Binders for Lithium–Sulfur Batteries That Adapt Their Transport Properties in Operando

Frischmann, Peter D.; Hwa, Yoon; Cairns, Elton J.; Helms, Brett A.

doi:10.1021/acs.chemmater.6b03013

Cited by 60 publications

(52 citation statements)

References 53 publications

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“…[79] Later on, other linear polymers including sulfonated poly(ether ether ketone), [80] poly(vinylidene difluoride-trifluoroethylene), [81] poly(3,4-ethyle nedioxythiophene):polystyrene sulfonate (PEDOT:PSS), [82] polyamide-6, chitosan sulfate ethylamide glycinamide, [83] benzimidazole-containing poly(arylene ether ketone), and sulfonated poly(arylene ether ketone-co-benzimidazole) [84] also have been reported to show good polysulfide anchoring ability. [87] Recently, Cui et al reported an aqueous inorganic polymer binder, ammonium polyphosphate (APP), which acquires not only polysulfide adsorption capability but also the flameretardant property (Figure 4D). Funct.…”

Section: Immobilization Of Polysulfidementioning

confidence: 99%

Rational Design of Binders for Stable Li‐S and Na‐S Batteries

Guo

Zheng

2019

Adv Funct Materials

127

111

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Binders play a critical role in stabilizing the sulfur cathode of Li-S and Na-S batteries. Over the past decade, the design of binder molecules has gone through tremendous evolution from primarily maintaining the structural integrity of the electrode against volume change to rationally immobilizing polysulfide intermediate and facilitating electron/ion transport in the charge and discharge process. This article reviews the development of binder for Li-S and Na-S batteries from the perspective of molecular design, and comprehensively discusses the correlation between the functions of the binder molecules and the cell performance. It also points out the future challenge and the potential solutions to address them. Figure 2. Timeline of the development of binders in terms of specific functions in Li-S and Na-S batteries. The binder in Li-S batteries has experienced a remarkable evolution in terms of functions, from fundamental structural and mechanical stabilizer (linear, hybrid, [30] dendrimer, [31] and crossedlinked binder [32,33] ) to versatile functions of polysulfide immobilization (polymer with functional groups [34][35][36] or cation groups [37] ) and facilitation of electron transport on the basis of conductive polymer. [38,39] It opens up the research of multifunctional binder. The analogous development route in the binder is found in Na-S batteries. [40,41] Reproduced with permission. [30]

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Section: Immobilization Of Polysulfidementioning

confidence: 99%

Rational Design of Binders for Stable Li‐S and Na‐S Batteries

Guo

Zheng

2019

Adv Funct Materials

127

111

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“…As shown in Figure , if the electrode active material itself has both electrical conductivity and suitable adhesion or other properties that help improve ion/electron conductivity and inhibit the polysulfide dissolution, the electrode performance could be greatly enhanced. On one hand, some polymer binders showed excellent properties in reducing Li–S cell impedance, actively regulating ion transport and enabling strongly anchoring polysulfides, and some conductive polymers have been used as binders in some inorganic electrodes . By selecting some special current collectors, some sulfur‐containing polymers such as rubber products and sulfur–limonene polysulfide can act as both active material and binder at the same time to form a binder‐free and conductive agent‐free electrode for use as the cathode of Li–S batteries.…”

Section: Potential Of Sulfur‐containing Polymer‐based Li–s Batteriesmentioning

confidence: 99%

Recent Advances in Applying Vulcanization/Inverse Vulcanization Methods to Achieve High‐Performance Sulfur‐Containing Polymer Cathode Materials for Li–S Batteries

2018

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Lithium–sulfur (Li–S) batteries have great prospects as next‐generation energy storage devices because of their high energy density, inexpensive raw materials, and low pollution. However, the development of Li–S batteries is currently restricted by the shuttle effect that occurs during the charge–discharge process. Sulfur‐containing polymers are attractive for use as Li–S battery cathode materials to alleviate the shuttle effect through chemical bonds as well as physical confinement. Moreover, polymers have numerous different molecular structures and definable functional groups. A suitable monomer design can result in a final sulfur‐containing polymer possessing favorable properties such as ion and electron conductivity, high sulfur content, appropriate viscosity, processability, and controllable morphology. These characteristics are of great benefit for use in Li–S battery cathodes to achieve high capacity and stable discharge at high rates. This review summarizes recent developments in sulfur‐containing polymer cathode materials. Focusing on polymers prepared by the facile and low‐cost vulcanization/inverse vulcanization methods and the polymer‐based composites, the chemical structures and electrochemical mechanisms are clarified, and the relationship between their structures and performances is discussed comprehensively. It is expected that more polymer electrode materials with high performance will emerge in the coming years.

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“…Accordingly, there is significant current activity towards developing binder‐free electrode structures . However, there is also an increasing interest in identifying or developing new binder materials with properties that enable improved electrochemical performance through properties such as electronic conductivity or by interaction with polysulfides …”

Section: Introductionmentioning

confidence: 99%

“…[28][29][30][31] However,t here is also an increasing interest in identifying or developing new binder materialsw ith properties that enable improved electrochemical performance through properties such as electronic conductivity or by interaction with polysulfides. [32][33][34][35][36][37][38][39][40] We previously reported on the benefits of using poly(ethylene oxide) (PEO) [41] or ac ombination of PEO with poly(vinyl-We report here aw ater-based functional binder framework for the lithium-sulfur battery systems, based on the general combination of ap olyether and an amide-containing polymer. These binders are appliedt op ositive electrodes optimised towards high-energye lectrochemical performance based only on commercially availablem aterials.E lectrodes with up to 4mAh cm À2 capacity and 97-98 %c oulombic efficiency are achievablei ne lectrodes with a6 5% total sulfur content and ap oly(ethylene oxide):poly(vinylpyrrolidone) (PEO:PVP) binder system.E xchange of either binder component foradifferent polymerw ith similarf unctionality preserves the high capacity and coulombic efficiency.T he improvement in coulombic effi-ciency from the inclusion of the coordinating amide group was also observed in electrodes where pyrrolidonem oieties were covalently grafted to the carbon black, indicating the role of this functionality in facilitating polysulfide adsorption to the electrode surface.T he mechanical properties of the electrodes appear not to significantly influence sulfur utilisation or coulombic efficiency in the short termb ut rather determine retention of these properties over extended cycling.…”

Section: Introductionmentioning

confidence: 99%

A Robust, Water‐Based, Functional Binder Framework for High‐Energy Lithium–Sulfur Batteries

et al. 2017

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We report here a water-based functional binder framework for the lithium-sulfur battery systems, based on the general combination of a polyether and an amide-containing polymer. These binders are applied to positive electrodes optimised towards high-energy electrochemical performance based only on commercially available materials. Electrodes with up to 4 mAh cm capacity and 97-98 % coulombic efficiency are achievable in electrodes with a 65 % total sulfur content and a poly(ethylene oxide):poly(vinylpyrrolidone) (PEO:PVP) binder system. Exchange of either binder component for a different polymer with similar functionality preserves the high capacity and coulombic efficiency. The improvement in coulombic efficiency from the inclusion of the coordinating amide group was also observed in electrodes where pyrrolidone moieties were covalently grafted to the carbon black, indicating the role of this functionality in facilitating polysulfide adsorption to the electrode surface. The mechanical properties of the electrodes appear not to significantly influence sulfur utilisation or coulombic efficiency in the short term but rather determine retention of these properties over extended cycling. These results demonstrate the robustness of this very straightforward approach, as well as the considerable scope for designing binder materials with targeted properties.

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Redox-Active Supramolecular Polymer Binders for Lithium–Sulfur Batteries That Adapt Their Transport Properties in Operando

Cited by 60 publications

References 53 publications

Rational Design of Binders for Stable Li‐S and Na‐S Batteries

Rational Design of Binders for Stable Li‐S and Na‐S Batteries

Recent Advances in Applying Vulcanization/Inverse Vulcanization Methods to Achieve High‐Performance Sulfur‐Containing Polymer Cathode Materials for Li–S Batteries

A Robust, Water‐Based, Functional Binder Framework for High‐Energy Lithium–Sulfur Batteries

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