Investigation on the Overlithiation Mechanism of LiCoO<sub>2</sub> Cathode for Lithium Ion Batteries

Yu, Lele; Tian, Yexing; Xiao, Xiangheng; Hou, Chen; Xing, Yiran; Si, Yong-Heng; Han, Lu; Zhao, Yujuan

doi:10.1149/1945-7111/abfc9e

Cited by 18 publications

(19 citation statements)

References 43 publications

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“…In this work, a dense LiF-rich CEI was formed on a single-crystalline LiCoO 2 (LCO) cathode after potentiostatic reduction at 1.7 V in 1.0 M LiDFOB-0.2 M LiBF 4 -FEC-DEC electrolyte, since the electrolyte reduction potential of 1.7 V is higher than the reduction potential of LCO cathode. [47,52,[55][56][57][58] LiF-rich CEI restrains the structural damage of LCO, detrimental oxidative decomposition of solvents and dissolution of Co into electrolyte even at the high cut-off voltage of 4.6 V. The LCO with LiF-rich CEI achieved an excellent cyclability with a capacity of 198 mAh g À 1 and retention of 63.5 % over 400 cycles at 0.5C (100 mA g À 1 , 1C rate corresponds to a specific current of 200 mA g À 1 ) as compared to the LiF-free LCO with only 17.4 % of capacity retention. Also, the LCO//graphite full cell with LiF-rich CEI on LCO maintained 85 % of capacity after 500 cycles.…”

Section: Introductionmentioning

confidence: 99%

Formation of LiF‐rich Cathode‐Electrolyte Interphase by Electrolyte Reduction

et al. 2022

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The capacity of transition metal oxide cathode for Li-ion batteries can be further enhanced by increasing the charging potential. However, these high voltage cathodes suffer from fast capacity decay because the large volume change of cathode breaks the active materials and cathode-electrolyte interphase (CEI), resulting in electrolyte penetration into broken active materials and continuous side reactions between cathode and electrolytes. Herein, a robust LiF-rich CEI was formed by potentiostatic reduction of fluorinated electrolyte at a low potential of 1.7 V. By taking LiCoO 2 as a model cathode, we demonstrate that the LiF-rich CEI maintains the structural integrity and suppresses electrolyte penetration at a high cut-off potential of 4.6 V. The LiCoO 2 with LiF-rich CEI exhibited a capacity of 198 mAh g À 1 at 0.5C and an enhanced capacity retention of 63.5 % over 400 cycles as compared to the LiF-free LiCoO 2 with only 17.4 % of capacity retention.

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Section: Introductionmentioning

confidence: 99%

Formation of LiF‐rich Cathode‐Electrolyte Interphase by Electrolyte Reduction

et al. 2022

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“…However, the lithiation depth of the cathode needs to be moderate, otherwise it may lead to structural degradation. For example, when the over‐discharge reaches 1.2 V, LiCoO 2 begins to decompose into CoO [110] …”

Section: Electrochemical Prelithiationmentioning

confidence: 99%

“…For example, when the over-discharge reaches 1.2 V, LiCoO 2 begins to decompose into CoO. [110] Similarly, when the cubic LiMn 2 O 4 is lithiated to the tetragonal Li 2 Mn 2 O 4 , the volume change will cause poor reversibility in long cycling. Aravindan et al designed a cycling route that using Li 1.26 Mn 2 O 4 prelithiated by half-cell to supply the lithium loss of the α-Fe 2 O 3 anode in the 1st cycle.…”

Section: Cathodementioning

confidence: 99%

Prelithiation Reagents and Strategies on High Energy Lithium‐Ion Batteries

Zhou

Chen

Gao³

et al. 2022

Chemistry A European J

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Lithium-ion batteries (LIBs) have been widely employed in energy-storage applications owing to the relatively higher energy density and longer cycling life. However, they still need further improvement especially on the energy density to satisfy the increasing demands on the market. In this respect, the irreversible capacity loss (ICL) in the initial cycle is a critical challenge due to the lithium loss during the formation of solid electrolyte interphase (SEI) layer on the anode surface. The strategy of prelithiation was then proposed to compensate for the ICL in the anode and recover the energy density. Here, various methods of the prelithiation are summarized and classified according to the basic working mechanism. Further, considering the critical importance and promising progress of prelithiation in both fundamental research and real applications, this Review article is intended to discuss the considerations involved in the selection of prelithiation reagents/strategies and the electrochemical performance in full-cells. Moreover, insights are provided regarding the practical application prospects and the challenges that still need to be addressed.

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“…The discharge curves, which show a sharp increase of discharging slope at the voltage below 3.8 V versus Li/Li + , are similar to those batteries using liquid electrolyte and LCO cathode. [79][80][81] The similarity in discharging curves indicates that the LCO within the CPE was well maintained in its phase and structure during the sintering process. Initial structural characterization is essential for the investigation of the dynamic delithiation and lithiation effects on SSLB.…”

Section: Electrochemical Performance and Characterization Of Sslbmentioning

confidence: 99%

“…A plateau at ≈1.25 V versus Li/Li + is assigned to the reaction of LCO and Li-ions to form Co 3 O 4 and Li 2 O, that is, Equation (1), while the plateau at ≈0.96 V versus Li/Li + is the reaction of cobalt oxides (Co 3 O 4 and CoO) and Liions to form Li 2 O and metallic Co, that is, Equations ( 2) and ( 3), according to Shu et al [89] It is also noticed that the specific capacity of LCO is much lower for the SSLB (232 mA h g −1 to 0.5 V vs Li/Li + ) than that for using liquid electrolyte cells (≈1000 mA h g −1 ), where the plateau at ≈0.96 V versus Li/Li + only delivers 96 mA h g −1 for the SSLB while that for liquid electrolyte cells is about 800 mA h g −1 . [79,89,101] Furthermore, the discharge plateaus at ≈1.25 and ≈0.96 V versus Li/Li + were no more observed in the 2nd discharge cycle. Unlike liquid electrolytes which can penetrate through the newly formed materials to provide Li-ion conductive paths, the much lower specific capacity and the disappearing of the two discharge plateaus at ≈1.25 and ≈0.96 V versus Li/Li + can be explained by the reduction of Li-ion conductive paths through LCO after LCO was decomposed into cobalt oxides and Li 2 O.…”

Section: In Operando Tem Investigation Of Structural Variation and Fa...mentioning

confidence: 99%

All‐Solid‐State Garnet‐Based Lithium Batteries at Work–In Operando TEM Investigations of Delithiation/Lithiation Process and Capacity Degradation Mechanism

et al. 2022

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Li7La3Zr2O12 (LLZO)‐based all‐solid‐state Li batteries (SSLBs) are very attractive next‐generation energy storage devices owing to their potential for achieving enhanced safety and improved energy density. However, the rigid nature of the ceramics challenges the SSLB fabrication and the afterward interfacial stability during electrochemical cycling. Here, a promising LLZO‐based SSLB with a high areal capacity and stable cycle performance over 100 cycles is demonstrated. In operando transmission electron microscopy (TEM) is used for successfully demonstrating and investigating the delithiation/lithiation process and understanding the capacity degradation mechanism of the SSLB on an atomic scale. Other than the interfacial delamination between LLZO and LiCoO2 (LCO) owing to the stress evolvement during electrochemical cycling, oxygen deficiency of LCO not only causes microcrack formation in LCO but also partially decomposes LCO into metallic Co and is suggested to contribute to the capacity degradation based on the atomic‐scale insights. When discharging the SSLB to a voltage of ≈1.2 versus Li/Li+, severe capacity fading from the irreversible decomposition of LCO into metallic Co and Li2O is observed under in operando TEM. These observations reveal the capacity degradation mechanisms of the LLZO‐based SSLB, which provides important information for future LLZO‐based SSLB developments.

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Investigation on the Overlithiation Mechanism of LiCoO₂ Cathode for Lithium Ion Batteries

Cited by 18 publications

References 43 publications

Formation of LiF‐rich Cathode‐Electrolyte Interphase by Electrolyte Reduction

Formation of LiF‐rich Cathode‐Electrolyte Interphase by Electrolyte Reduction

Prelithiation Reagents and Strategies on High Energy Lithium‐Ion Batteries

All‐Solid‐State Garnet‐Based Lithium Batteries at Work–In Operando TEM Investigations of Delithiation/Lithiation Process and Capacity Degradation Mechanism

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Investigation on the Overlithiation Mechanism of LiCoO2 Cathode for Lithium Ion Batteries

Cited by 18 publications

References 43 publications

Formation of LiF‐rich Cathode‐Electrolyte Interphase by Electrolyte Reduction

Formation of LiF‐rich Cathode‐Electrolyte Interphase by Electrolyte Reduction

Prelithiation Reagents and Strategies on High Energy Lithium‐Ion Batteries

All‐Solid‐State Garnet‐Based Lithium Batteries at Work–In Operando TEM Investigations of Delithiation/Lithiation Process and Capacity Degradation Mechanism

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Investigation on the Overlithiation Mechanism of LiCoO₂ Cathode for Lithium Ion Batteries