Overcharge Investigations of LiCoO<sub>2</sub>/Graphite Lithium Ion Batteries with Different Electrolytes

Wang, Jun; Du, Leilei; Liu, Zhongbo; Zou, Xianshuai; Tang, Xiwu; Cao, Zongze; Wang, Chaoyang; Xiong, Dejun; Shi, Qiao; Qian, Yunxian; Deng, Yonghong

doi:10.1021/acsaem.9b01520

Cited by 15 publications

(15 citation statements)

References 55 publications

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“…The high terminal voltage at rupture possibly came from increase in cell internal resistance, which could originate from decomposition of electrode and electrolyte and separator shutdown. [ 18,30 ] It has been observed that LIBs overcharged at a 3 C rate had higher voltage at rupture compared with LIBs overcharged at 1 C rate. [ 39 ] The high overcharging rate can be the reason for the observed high voltage at rupture in this study.…”

Section: Resultsmentioning

confidence: 99%

“…To analyze the effect of charging rate on heat generation within the pouch cell, cell #1 was CC charged at 1 C rate up to 5.4 V. After reaching around 5.4 V, gas generation and electrode degradation in LIB became obvious. [ 11,30 ] Cell #1 was then CC charged at 5 C rate until explosion. Cell #2 was CC charged at 5 C rate constantly until cell explosion.…”

Section: Methodsmentioning

confidence: 99%

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Operando Monitoring of Electrode Temperatures During Overcharge‐Caused Thermal Runaway

Parekh

Pol

et al. 2021

Energy Tech

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Lithium‐ion batteries’ (LIBs) failure due to abusive cycling conditions can result in thermal runaway, which calls for reliable real‐time battery thermal safety monitoring. Herein, an effective method for LIB thermal runaway detection using a resistant temperature detector (RTD) is compared with a conventional battery surface temperature measurement. A direct electrode temperature measurement technique based on additive manufacturing‐enabled application of miniature RTDs for measurement of internal temperature within large‐capacity Li‐ion pouch cells is used. The miniature RTDs are embedded in a customized electrochemically inactive polymeric substrate for real‐time thermal safety monitoring during overcharge abuse. Electrode temperature profiles under different conditions of overcharge (at 1 and 5 C rate, charged until battery explosion) are analyzed and mechanisms of heat generation in LIBs during overcharge‐induced thermal runaway are investigated. The internal RTDs detect the onset temperature of the solid−electrolyte interface decomposition ≈10 s earlier than the sensors attached to the battery surface. A maximum temperature gradient of ≈200 °C is observed between the electrode and the battery surface during overcharge‐induced thermal runaway. The internal RTDs are shown as a possible guide for sensor placement location to capture the maximum temperature within the LIBs during abuse events.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Operando Monitoring of Electrode Temperatures During Overcharge‐Caused Thermal Runaway

Parekh

Pol

et al. 2021

Energy Tech

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“…XPS measurements were conducted on a Thermo Fisher K -alpha (USA) XPS system to study CEI and SEI films . GC-MS measurements were adopted to analyze the electrolyte decomposition on a Thermo Scientific ISQ device . LC-QTOF-MS was performed on Xevo G2-XS QTOF (Waters Corporation, USA) to have a deeper investigation of the decomposition of the electrolyte qualitatively and quantitatively …”

Section: Methodsmentioning

confidence: 99%

“…The commercial electrolyte system usually comprises carbonate solvent and lithium salt, which undergoes reduction during the first charge–discharge cycle. As a result, SEI and CEI layers consisting of inorganic and organic decomposition compounds are formed. , In an ideal condition, the SEI and the CEI act as protective layers to prevent further electrolyte decomposition by the prohibition of the electron transport in the successive charge–discharge cycling . Through the surface films, lithium ions could intercalate into the electrode material without the structural changes of the host.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Fluoroethylene Carbonate for Improving High-Temperature Performance of LiNi_0.8Mn_0.1Co_0.1O₂||SiO_x@Graphite Lithium-Ion Batteries

Wang

Tang³

et al. 2020

ACS Appl. Energy Mater.

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LiNi 0.8 Mn 0.1 Co 0.1 O 2 ||SiO x @graphite has received great attention in both academia and industry because it has the highest energy density among state-of-the-art commercial lithium-ion batteries. However, it suffers from severe capacity decay during high-temperature cycling or storage, which still needs to be addressed for its commercialization. In this work, fluoroethylene carbonate (FEC) is employed as an additive or a cosolvent to improve the high-temperature performance of 1 Ah LiNi 0.8 Mn 0.1 Co 0.1 O 2 ||SiO x @graphite pouch cells. By adding 5% FEC as additive, the capacity retention increases from 54.5% to 67.0% after 100 cycles at 45 °C. The use of FEC as a cosolvent further increases the capacity retention to 83.3%. The improvement is ascribed to the multifunctional effects from FEC, preventing electrolyte decomposition, mitigating the resistance increment and Mn ions dissolution with the formation of the interface films, which consist of LiF and LiPO x F y species. Therefore, the employment of FEC is of great importance for the development of high-energy-density lithium-ion batteries.

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“…The higher device voltage increases the probability of over-oxidation on the fast-switching ECP component before the reaction of the ion-storage materials reaches equilibrium (MO x + y Li + + y e – = Li y MO x ). Additionally, high device voltage leads to problems including interfacial electrolyte decomposition . Therefore, to stabilize ECP-based hybrid electrochromic devices, a low device voltage is beneficial. , This requires the MCC transition-metal oxide material to exhibit excellent charge-balancing capability in an electroactive window that is closely matched with that of the ECPs.…”

Section: Introductionmentioning

confidence: 99%

Stabilizing Hybrid Electrochromic Devices through Pairing Electrochromic Polymers with Minimally Color-Changing Ion-Storage Materials Having Closely Matched Electroactive Voltage Windows

Wang

Chen

et al. 2021

ACS Appl. Mater. Interfaces

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Conjugated electrochromic polymers hold great promises for next-generation color-changing windows and displays. One of the major roadblocks in their solid-state electrochromic devices is the relatively poor cycling stability. Finding ion-storage materials as a charge-balancing component is critical in improving their electrochemical cycling stability. A key criterion for the selection of ion-storage materials is to match their electroactive voltage windows with the paired electrochromic polymers. Thus, we developed a nanostructured, amorphous vanadium oxide (VO x ) ion-storage material that exhibits high transmissivity, minimal color interference, and excellent charge-balancing capability in a closely matched electroactive window with the paired electrochromic polymers. High-performance magenta-to-transmissive hybrid electrochromic devices constructed from pairing the polymer with the VO x can be reversibly switched for 50 000 cycles with an optical loss less than 5%.

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Overcharge Investigations of LiCoO₂/Graphite Lithium Ion Batteries with Different Electrolytes

Cited by 15 publications

References 55 publications

Operando Monitoring of Electrode Temperatures During Overcharge‐Caused Thermal Runaway

Operando Monitoring of Electrode Temperatures During Overcharge‐Caused Thermal Runaway

Multifunctional Fluoroethylene Carbonate for Improving High-Temperature Performance of LiNi_0.8Mn_0.1Co_0.1O₂||SiO_x@Graphite Lithium-Ion Batteries

Stabilizing Hybrid Electrochromic Devices through Pairing Electrochromic Polymers with Minimally Color-Changing Ion-Storage Materials Having Closely Matched Electroactive Voltage Windows

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Overcharge Investigations of LiCoO2/Graphite Lithium Ion Batteries with Different Electrolytes

Cited by 15 publications

References 55 publications

Operando Monitoring of Electrode Temperatures During Overcharge‐Caused Thermal Runaway

Operando Monitoring of Electrode Temperatures During Overcharge‐Caused Thermal Runaway

Multifunctional Fluoroethylene Carbonate for Improving High-Temperature Performance of LiNi0.8Mn0.1Co0.1O2||SiOx@Graphite Lithium-Ion Batteries

Stabilizing Hybrid Electrochromic Devices through Pairing Electrochromic Polymers with Minimally Color-Changing Ion-Storage Materials Having Closely Matched Electroactive Voltage Windows

Contact Info

Product

Resources

About

Overcharge Investigations of LiCoO₂/Graphite Lithium Ion Batteries with Different Electrolytes

Multifunctional Fluoroethylene Carbonate for Improving High-Temperature Performance of LiNi_0.8Mn_0.1Co_0.1O₂||SiO_x@Graphite Lithium-Ion Batteries