Strategic Structural Design of a Gel Polymer Electrolyte toward a High Efficiency Lithium-Ion Battery

Baskoro, Febri; Wong, Hui Qi; Yen, Hung‐Ju

doi:10.1021/acsaem.9b00295

Cited by 164 publications

(126 citation statements)

References 159 publications

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“…Polyether, polynitrile, polycarbonate, polyarylate, and their derivatives have been used as polymer matrices which can dissolve Li salts by coordination between Li ions and polar groups or electrostatic forces in polymeric chains. [ 23–25 ] Still, their σ values are lower than the required conductivity of 10 −3 S cm −1 , and lower than the σ values of conventional electrolytes. Therefore, other alternative SPE systems with better physicochemical and electrochemical properties, such as polymer‐in‐salts containing plasticizer or organic solvents, single‐ion conducting polymer electrolytes that require modification of the polymer matrix or use of new types of Li salt, and organic–inorganic composite polymer separators (CPSs), have been developed in the past two decades.…”

Section: Introductionmentioning

confidence: 85%

Tough and Flexible, Super Ion‐Conductive Electrolyte Membranes for Lithium‐Based Secondary Battery Applications

Mong

Shi

Jeon

et al. 2020

Adv Funct Materials

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Recently, stringent requirements brought on by environmental regulations and safety issues are driving the development of solid electrolytes to replace conventional liquid electrolyte systems for lithium‐based secondary batteries (LiBs). However, the low Li‐ion conductivity and/or poor mechanical properties of electrolytes remain the main obstacles hindering their commercialization. Hierarchitectural and composite polymer separators (CPSs) based on electrolyte membranes have been reported as promising tools for both high ionic conductivity and mechanical stability. In light of such work, the new types of flexible electrolytes based on phase‐separated and mixed‐phase morphologies achieved via self‐assembly and the use of functional molecular composites are reviewed along with the fundamental mechanisms associated with such systems. In particular, the structure and morphology, ionic conductivity, thermal/mechanical stability, and fabrication of polymer electrolytes are introduced. Additionally, recent advancements in CPSs including methods of ensuring low interfacial resistance, the respective contributions of these critical factors to the significant functional properties of CPSs, and directions for development and essential applications in the field of CPSs for LiBs are presented. Based on previous works, the perspectives put forth will aid in the design of advanced electrolytes for practical Li secondary batteries in the near future.

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Section: Introductionmentioning

confidence: 85%

Tough and Flexible, Super Ion‐Conductive Electrolyte Membranes for Lithium‐Based Secondary Battery Applications

Mong

Shi

Jeon

et al. 2020

Adv Funct Materials

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“…High power lithium ion battery (LIB), as an energy storage equipment, has raised scientists much attention with the development of electric vehicle and renewable energy. [1,2] Separator sandwiched between two electrodes plays an important role in blocking the passage of electrons while allowing the delivery of Li + . Hence, higher requirements are put forward that separator must be able to tolerate high temperature, adsorb more electrolyte and benefit to transfer Li + , which can finally meet the demand of safety and charge/discharge performance followed by the increase of LIB power density.…”

Section: Introductionmentioning

confidence: 99%

“…High power lithium ion battery (LIB), as an energy storage equipment, has raised scientists much attention with the development of electric vehicle and renewable energy [1,2] . Separator sandwiched between two electrodes plays an important role in blocking the passage of electrons while allowing the delivery of Li + .…”

Section: Introductionmentioning

confidence: 99%

Semi‐Interpenetrating Polymer Electrolyte as a Coating Layer Constructed on Polyphenylene Sulfide Nonwoven to Afford Superior Stability and Performance for Lithium‐Ion Batteries

et al. 2020

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High power lithium-ion battery (LIB) puts forward higher requirements for separator. In this study, a new composite separator (SIPN/PPS) with superior stability and improved electrochemical performance was fabricated by the construction of semi-interpenetrating polymer network (SIPN) on polyphenylene sulfide (PPS) nonwoven substrate. In SIPN, branched polyethyleneimine (PEI) was selected as crosslinking points due to multiple reactive terminal groups À NH 2. Meanwhile, PEI owned irregular topology structure, which would be beneficial to interrupt the crystallization of polymer matrix and increase electrolyte storage by swelling. Characterization results show that this designed composite separator can exhibit higher porosity, improved electrolyte wettability, enhanced electrolyte uptake and excellent electrochemical performance, thus endowing battery with superior discharge capacity even at 3 C. In addition, the introduction of SIPN is confirmed to increase mechanical strength more obviously than that of single crosslinked network reported in previous study. Meanwhile, anode current begins to be detected for SIPN/PPS composite separator under higher applied voltage (4.6 V vs Li + /Li), indicating its broader electrochemical window. Moreover, SIPN/PPS composite separator is displayed satisfactory cycling stability with higher discharge capacity retention ratio (85.3 %). Consequently, this contribution opens a new avenue for separator applied in high power LIB.

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“…Since ionic conductivity is directly proportional to the concentration of charged species and their electrical mobility, as per σ = n i *q i *µ i , it is expected that ionic conductivity to be lower in GPEs as the mobility of ions is higher in liquid electrolytes [114]. • High Cationic Transference Number (t + ): Besides the ionic conductivity, the transference number of polymer electrolytes is an important figure of merit when assessing their efficacy.…”

mentioning

confidence: 99%

“…The cationic transference number is the cation mobility relative to the anion in single salts GPEs. In GPEs, working species need to have a transference number close to unity [114].…”

mentioning

confidence: 99%

A Review of the Use of GPEs in Zinc-Based Batteries. A Step Closer to Wearable Electronic Gadgets and Smart Textiles

2020

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With the flourish of flexible and wearable electronics gadgets, the need for flexible power sources has become essential. The growth of this increasingly diverse range of devices boosted the necessity to develop materials for such flexible power sources such as secondary batteries, fuel cells, supercapacitors, sensors, dye-sensitized solar cells, etc. In that context, comprehensives studies on flexible conversion and energy storage devices have been released for other technologies such Li-ion standing out the importance of the research done lately in GPEs (gel polymer electrolytes) for energy conversion and storage. However, flexible zinc batteries have not received the attention they deserve within the flexible batteries field, which are destined to be one of the high rank players in the wearable devices future market. This review presents an extensive overview of the most notable or prominent gel polymeric materials, including biobased polymers, and zinc chemistries as well as its practical or functional implementation in flexible wearable devices. The ultimate aim is to highlight zinc-based batteries as power sources to fill a segment of the world flexible batteries future market.

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Strategic Structural Design of a Gel Polymer Electrolyte toward a High Efficiency Lithium-Ion Battery

Cited by 164 publications

References 159 publications

Tough and Flexible, Super Ion‐Conductive Electrolyte Membranes for Lithium‐Based Secondary Battery Applications

Tough and Flexible, Super Ion‐Conductive Electrolyte Membranes for Lithium‐Based Secondary Battery Applications

Semi‐Interpenetrating Polymer Electrolyte as a Coating Layer Constructed on Polyphenylene Sulfide Nonwoven to Afford Superior Stability and Performance for Lithium‐Ion Batteries

A Review of the Use of GPEs in Zinc-Based Batteries. A Step Closer to Wearable Electronic Gadgets and Smart Textiles

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