Thermal safety and thermal management of batteries

Rao, Zhonghao; Lyu, Peizhao; Du, Peixing; He, Deqing; Huo, Yujia; Liu, Chenzhen

doi:10.1002/bte2.20210019

Cited by 21 publications

(9 citation statements)

References 147 publications

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“…7) Thermal safety is another key issue that hinders the practical applications of supercapacitors. [242] Heat generation and thermal changes between electrode and electrolyte can lead to nonuniform electrochemical reactions. In addition, thick electrodes are not conducive to heat dissipation and conduction, which will lead to rapid heat accumulation.…”

Section: Challenges and Perspectivesmentioning

confidence: 99%

“…Especially under high mass‐loading, the self‐discharge and leakage current of the device will inevitably be aggravated, thus it is very important to optimize the suppression strategy reasonably. 7)Thermal safety is another key issue that hinders the practical applications of supercapacitors. [ 242 ] Heat generation and thermal changes between electrode and electrolyte can lead to nonuniform electrochemical reactions. In addition, thick electrodes are not conducive to heat dissipation and conduction, which will lead to rapid heat accumulation.…”

Section: Challenges and Perspectivesmentioning

confidence: 99%

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High Mass‐Loading Biomass‐Based Porous Carbon Electrodes for Supercapacitors: Review and Perspectives

Yang

Qiu

2023

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Biomass‐based porous carbon (BPC) with renewability and flexible nano/microstructure tunability has attracted increasing attention as efficient and cheap electrode materials for supercapacitors. To meet commercial needs, high mass‐loading electrodes with high areal capacitance are preferred when designing supercapacitors. The increased mass percentage of active materials can effectively improve the energy density of supercapacitors. However, as the thickness of the electrode increases, it will face the following challenges including severely blocked ion transport channels, poor charging dynamics, poor electrode structural stability, and complex preparation processes. A bridge between theoretical research and practical applications of BPC electrodes for supercapacitors needs to be established. In this review, the advances of high mass‐loading BPC electrodes for supercapacitors are summarized based on different biomass precursors. The key performance evaluation parameters of the high mass‐loading electrodes are analyzed, and the performance influencing factors are systematically discussed, including specific surface area, pore structure, electrical conductivity, and surface functional groups. Subsequently, the promising optimization strategies for high mass‐loading electrodes are summarized, including the structure regulation of electrode materials and the optimization of other supercapacitor components. Finally, the major challenges and opportunities of high mass‐loading BPC electrodes in the future are discussed and outlined.

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Section: Challenges and Perspectivesmentioning

confidence: 99%

Section: Challenges and Perspectivesmentioning

confidence: 99%

High Mass‐Loading Biomass‐Based Porous Carbon Electrodes for Supercapacitors: Review and Perspectives

Yang

Qiu

2023

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“…[1][2][3][4][5][6] Due to the relatively high energy and/or power density, rechargeable lithium-based batteries, including the Li-ion battery (LIB), Li-metal battery (LMB), Li-S battery (LSB), and Li-O 2 battery (LOB), show great promise for electrochemical energy storage (EES) systems. [7][8][9][10][11] In particular, LIBs are leading EES systems widely used in both portable consumer smart electronics and the automotive industry, making energy use convenient, green, and continual. [12][13][14][15][16] As the majority of current commercial LIBs contain liquid organic electrolytes composed of ionic salts dissolved in organic solvents, electrolyte leakage, and even combustion accidents occasionally occur, which hinders further reliable applications, especially in flexible and/or wearable devices.…”

Section: Introductionmentioning

confidence: 99%

“…To achieve the net‐zero carbon future committed by more and more countries, energy storage technologies utilizing intermittent renewable energy such as wind, tidal energy, and solar power (excess solar photovoltaic generation) are extremely significant to reduce the consumption of limited fossil fuels 1–6 . Due to the relatively high energy and/or power density, rechargeable lithium‐based batteries, including the Li‐ion battery (LIB), Li‐metal battery (LMB), Li‐S battery (LSB), and Li‐O 2 battery (LOB), show great promise for electrochemical energy storage (EES) systems 7–11 . In particular, LIBs are leading EES systems widely used in both portable consumer smart electronics and the automotive industry, making energy use convenient, green, and continual 12–16 .…”

Section: Introductionmentioning

confidence: 99%

Recent developments of nanocomposite ionogels as monolithic electrolyte membranes for lithium‐based batteries

Xie,

Chen,

Zhang

et al. 2023

Battery Energy

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To utilize intermittent renewable energy to achieve carbon neutrality, rechargeable lithium‐based batteries have been deemed to be the most promising electrochemical systems for energy supply and storage. However, there still exist safety issues and challenges, especially originating from the intrinsic volatility and flammability of the electrolytes used in lithium‐based batteries. Due to the unique advantages of better safety, (quasi) solid‐state electrolytes have been exploited. Ionogel (IG), known as ionic liquid (IL) based monolithic quasi‐solid‐state electrolyte separator, consists of IL and gelling matrix and has become an active area of research in lithium‐based battery technology, owing to fascinating exotic characteristics including high safety (thermal stability) under extreme operating conditions, wide processing compatibility, and decent electrochemical performances. Among various gelling matrices, nanomaterials are very promising to simultaneously enhance ionic conductivity, mechanical strength, and thermal and electrochemical properties of IGs, which make the nanocomposite ionogels (NIGs). Herein, several significant advantages of NIGs as monolithic electrolyte membranes are briefly described. Also, recent advances in the NIGs for Li‐ion batteries, Li‐metal batteries, Li‐S batteries, and Li‐O2 batteries are timely and systematically overviewed. Finally, the remaining challenges and perspectives on such an interesting and active field are discussed. To the best of our knowledge, there are rare review articles focusing on the NIGs for Li‐based batteries till now. This work could offer a comprehensive understanding of recent advances and challenges of NIGs for advanced lithium storage.

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“…As a vital component of LMBs, the separator prevents the direct contact between the anode and cathode, as well as regulating the ion migration between them, which exerts its direct and essential role for the efficiency, stability, and safety of LMBs. [ 7,8 ] During the cycling of batteries, especially at high charge/discharge rates, substantial amount of Joule heat is generated and the internal temperature rises often, causing inhomogeneous heat accumulation, [ 6,9–11 ] which would deteriorate the nonuniform lithium deposition and result in undesired growth of lithium dendrites, that in turn, would eventually puncture through the separator and cause thermal runaway. [ 12 ] To address these issues in high‐rate operation, a strong driving force has been created to develop high‐performance separators with uniform and narrow pore size, high thermal stability, and mechanical property, with an aim to facilitate a homogeneous lithium deposition to suppress the lithium dendrite growth and enhance the cycling performance of LMBs at high charge/discharge rates.…”

Section: Introductionmentioning

confidence: 99%

Scalable Preparation of Polyimide Sandwiched Separator for Durable High‐Rate Lithium‐Metal Battery

Zhou,

Wang,

Mei

et al. 2023

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The ever‐growing demands for efficient energy storage accelerate the development of high‐rate lithium‐metal battery (LMB) with desirable energy density, power density, and cycling stability. Nevertheless, the practical application of LMB is critically impeded by internal temperature rise and lithium dendrite growth, especially at high charge/discharge rates. It is highly desired but remains challenging to develop high‐performance thermotolerant separators that can provide favorable channels to enable fast Li+ transport for high‐rate operation and simultaneously homogenize the lithium deposition for dendrite inhibition. Polyimide‐based separators with superior thermal properties are promising candidate alternatives to the commercial polyolefin‐based separators, but previous strategies of designing either nanoporous or microporous channels in polyimide‐based separators often meet a dilemma. Here, a facile and scalable approach is reported to develop a polyimide fiber/aerogel (denoted as PIFA) separator with the microporous polyimide fiber membrane sandwiched between two nanoporous polyimide aerogel layers, which can enable LMBs with remarkable capacity retention of 97.2% after 1500 cycles at 10 C. The experimental and theoretical studies unravel that the sandwiched structure of PIFA can appreciably enhance the electrolyte adsorption and ionic conductivity; while, the aerogel coating can effectively inhibit dendrite growth to realize durable high‐rate LMBs.

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Thermal safety and thermal management of batteries

Cited by 21 publications

References 147 publications

High Mass‐Loading Biomass‐Based Porous Carbon Electrodes for Supercapacitors: Review and Perspectives

High Mass‐Loading Biomass‐Based Porous Carbon Electrodes for Supercapacitors: Review and Perspectives

Recent developments of nanocomposite ionogels as monolithic electrolyte membranes for lithium‐based batteries

Scalable Preparation of Polyimide Sandwiched Separator for Durable High‐Rate Lithium‐Metal Battery

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