Novel Thermotolerant and Flexible Polyimide Aerogel Separator Achieving Advanced Lithium‐Ion Batteries

Deng, Yurui; Pan, Yuelei; Zhang, Zhongxin; Fu, Yangyang; Gong, Lunlun; Liu, Chengyuan; Yang, Jiuzhong; Zhang, Heping

doi:10.1002/adfm.202106176

Cited by 54 publications

(61 citation statements)

References 50 publications

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“…14 Despite all of the advantages, their inherent fragility also affects any application. 15,16 Therefore, polyimide aerogels (PIA) are of great interest due to their ability to withstand high temperatures, 17,18 their exceptional thermal stability, 19 and their favorable mechanical properties, making PIA the material of choice in the thermal insulation field in the aerospace industry. 20,21 At present, the matrix of PIA has the problems of large drying shrinkage and insufficient thermal insulation performance.…”

Section: Introductionmentioning

confidence: 99%

“…Silica aerogels are the most welcome and the darling among these aerogels which have excellent properties such as high specific area, high porosity, and extremely low thermal conductivity . Despite all of the advantages, their inherent fragility also affects any application. , Therefore, polyimide aerogels (PIA) are of great interest due to their ability to withstand high temperatures, , their exceptional thermal stability, and their favorable mechanical properties, making PIA the material of choice in the thermal insulation field in the aerospace industry. , …”

Section: Introductionmentioning

confidence: 99%

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Polyimide Aerogels with Excellent Thermal Insulation, Hydrophobicity, Machinability, and Strength Evolution at Extreme Conditions

Zhang

Wang

et al. 2022

ACS Appl. Polym. Mater.

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High performance polyimide aerogels (PIA) are highly desirable as a part of thermal protection systems for aircraft. However, the large drying shrinkage and insufficient thermal insulation of PIA limit their practical applications in the aerospace field. Herein, the strategy of two-step prepolymerization and polycondensation route was proposed to fabricate PIA with ultralow drying shrinkage, outstanding thermal insulation, hydrophobicity, machinability, compressive strength in cryogenic/high-temperature atmospheres, flame resistance, and fantastic dimensional stability. In more detail, the drying shrinkage rate of PIA series can be lowered to 1.84%, mainly owing to the strengthened skeletons by chemical bond formation and physical entanglement of molecular chains. Excellent thermal insulation is reflected upon keeping an ink drop state as long as 265 s despite placing it on a cold surface with a temperature of −196 °C. PIA-O2B2 are imparted with hydrophobic properties (with water contact angle of 135°) depending on the hydrogen-bonding interaction between polyimide networking chains and 1H,1H,2H,2H-perfluorodecyltriethoxysilane that was introduced. In addition, the exceptional flame retardant is endowed completely, which is attributed to the evidence of the presence of aromatic ring structures in constructing the aerogel. The high-temperature shrinkage rate of PIA series is as low as 4.81% due to the relative small free volume of the molecular chains. Our study would provide a method for designing ultralow drying shrinkage and superb thermal insulation in cryogenic conditions for PIA in aerospace uses.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Polyimide Aerogels with Excellent Thermal Insulation, Hydrophobicity, Machinability, and Strength Evolution at Extreme Conditions

Zhang

Wang

et al. 2022

ACS Appl. Polym. Mater.

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“…The SPEs can also act as the separator between the cathode and anode in LBs [ 19 ]. Commercialized polyolefin membranes have many shortcomings, such as poor thermal and dimensional stability, poor wettability and low porosity (<50%), which will lead to a high level of internal resistance, low ionic conductivity, Li dendrite growth and even short circuits occurring [ 20 , 21 , 22 ]. Great effort has been devoted to improving the performance of the polyolefin membrane [ 23 , 24 , 25 ], such as the surface modification of it [ 26 , 27 , 28 ] or developing various diaphragms from other sources such as PAN, PVDF and polyurethane [ 29 , 30 , 31 ].…”

Section: Introductionmentioning

confidence: 99%

Quasi-Solid-State Polymer Electrolyte Based on Electrospun Polyacrylonitrile/Polysilsesquioxane Composite Nanofiber Membrane for High-Performance Lithium Batteries

Liu

Zhu

et al. 2022

Materials

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Considering the safety problem that is caused by liquid electrolytes and Li dendrites for lithium batteries, a new quasi-solid-state polymer electrolyte technology is presented in this work. A layer of 1,4-phenylene bridged polysilsesquioxane (PSiO) is synthesized by a sol-gel way and coated on the electrospun polyacrylonitrile (PAN) nanofiber to prepare a PAN@PSiO nanofiber composite membrane, which is then used as a quasi-solid-state electrolyte scaffold as well as separator for lithium batteries (LBs). This composite membrane, consisting of the three-dimensional network architecture of the PAN nanofiber matrix and a mesoporous PSiO coating layer, exhibited a high electrolyte intake level (297 wt%) and excellent mechanical properties. The electrochemical analysis results indicate that the ionic conductivity of the PAN@PSiO-based quasi-solid-state electrolyte membrane is 1.58 × 10−3 S cm−1 at room temperature and the electrochemical stability window reaches 4.8 V. The optimization of the electrode and the composite membrane interface leads the LiFePO4|PAN@PSiO|Li full cell to show superior cycling (capacity of 137.6 mAh g−1 at 0.2 C after 160 cycles) and excellent rate performances.

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“…Furthermore, when a high-Ni LNCM material is exposed to a humid environment, Ni 3+ on the surface changes to Ni 2+ , and the formation of residual Li compounds is accelerated, of which those present on the cover of the LNCM material cause the following problems. [12][13][14][15][16][17] (1) When the residual Li compound is dissolved in the solvent, that is, N-methyl-2-pyrrolidone (NMP), during the electrode casting process, the solvent is basified, following which it is mixed with the binder, polyvinylidene fluoride (PVdF), to gelate the slurry, making it impossible to fabricate the electrode. (2) The carbonate component of the residual Li is easily attacked by HF generated by a negligible number of water molecules present in the electrolyte and decompose to generate gas, which causes the battery to explode.…”

Section: Introductionmentioning

confidence: 99%

“…For this reason, Li that is not located in the Li layer reacts with CO 2 present in the air during the heat treatment process to form Li 2 CO 3 or reacts with water to form LiOH, which are referred to as residual Li compounds. Furthermore, when a high‐Ni LNCM material is exposed to a humid environment, Ni 3+ on the surface changes to Ni 2+ , and the formation of residual Li compounds is accelerated, of which those present on the cover of the LNCM material cause the following problems 12‐17 . (1) When the residual Li compound is dissolved in the solvent, that is, N‐methyl‐2‐pyrrolidone (NMP), during the electrode casting process, the solvent is basified, following which it is mixed with the binder, polyvinylidene fluoride (PVdF), to gelate the slurry, making it impossible to fabricate the electrode.…”

Section: Introductionmentioning

confidence: 99%

Design of a hydrolysis‐supported coating layer on the surface of Ni‐rich cathodes in secondary batteries

Park

Lee

Kim

et al. 2022

Intl J of Energy Research

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Summary The formation of Li4SiO4 (LSO) coating layer on LiNi0.88Co0.05Mn0.07O2 (LNCM) was achieved by incorporating a new tetraethyl orthosilicate (TEOS)‐dropping coating method. This concept includes the hydrolysis reaction of TEOS on the surface of Ni0.88Co0.05Mn0.07(OH)2 and the subsequent calcination process with lithium source to obtain LSO‐coated LNCM cathode materials successfully during the calcination process. This method provides the driving force for the formation of a more uniform and thin coating layer compared with the traditional wet‐chemical coating method. The bare LNCM and LSO‐coated LNCM showed similar capacity retention rates during room temperature (25°C) cycling, but the capacity retention of LSO‐LNCM (81.6% after 100 cycles) for the cycling test at elevated temperature was significantly increased compared with bare LNCM (63.69% after 100 cycles). Additionally, the Li‐ion accessibility of the coated LNCM electrode was improved by the existence of the Li‐containing coating materials, and the results of analysis by the galvanostatic intermittent titration technique (GITT) confirmed the better Li‐ion diffusivity of the coated sample. These results indicate the high possibility of this novel coating method for application in various materials for developing secondary batteries.

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Novel Thermotolerant and Flexible Polyimide Aerogel Separator Achieving Advanced Lithium‐Ion Batteries

Cited by 54 publications

References 50 publications

Polyimide Aerogels with Excellent Thermal Insulation, Hydrophobicity, Machinability, and Strength Evolution at Extreme Conditions

Polyimide Aerogels with Excellent Thermal Insulation, Hydrophobicity, Machinability, and Strength Evolution at Extreme Conditions

Quasi-Solid-State Polymer Electrolyte Based on Electrospun Polyacrylonitrile/Polysilsesquioxane Composite Nanofiber Membrane for High-Performance Lithium Batteries

Design of a hydrolysis‐supported coating layer on the surface of Ni‐rich cathodes in secondary batteries

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