Insights into the Dual Role of Lithium Difluoro(oxalato)borate Additive in Improving the Electrochemical Performance of NMC811||Graphite Cells

Dong, Qingyu; Guo, Feng; Cheng, Zhenjie; Mao, Yayun; Huang, Rong; Li, Fangsen; Dong, Houcai; Zhang, Qingyong; Li, Wei; Chen, Hui; Luo, Zhaojun; Shen, Yanbin; Wu, Xiaodong; Chen, Liwei

doi:10.1021/acsaem.9b01894

Cited by 76 publications

(60 citation statements)

References 40 publications

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“…Similarly, without AEDB, significant cell parameter changes were observed, with the a-axis lattice parameter decreasing by about 1.29 % and the c-axis lattice parameter increasing by about 1.21 % after 100 cycles (Figure 4d), which is evidence of Li deficiency in the fully discharged cathode. [3,11,[53][54][55] This implies that a part of Li + cannot be re-inserted into the structure upon long-term cycling, which could be related to the loss of active Li to graphite anodes. [54] Whereas, when cycled AEDB additive, the changes in lattice parameter values were significantly smaller: the a-axis lattice parameter decreased only by about 0.34 % and the c-axis lattice parameter increased by about 0.53 % after 100 cycles.…”

Section: Additive Effect On the Stabilization Of Ncm851005 Cathodementioning

confidence: 99%

Cross‐Talk‐Suppressing Electrolyte Additive Enabling High Voltage Performance of Ni‐Rich Layered Oxides in Li‐Ion Batteries

et al. 2021

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Control of electrode-electrolyte interfacial reactivity at highvoltage is a key to successfully obtain high-energy-density lithium-ion batteries. In this study, 2-aminoethyldiphenyl borate (AEDB) is investigated as a multifunctional electrolyte additive in stabilizing surface and bulk of both Ni-rich Li-Ni 0.85 Co 0.1 Mn 0.05 O 2 (NCM851005) and graphite electrodes in a cell operated with elevated upper cutoff voltage of 4.4 V vs. Li + /Li. The presence of AEDB in a full-cell inhibits structural degradation of both cathode and anode materials, suppressing crack formation, and reduces metal dissolution at the cathode and metal deposition at the anode. As a consequence, the interfacial resistance is significantly reduced. Moreover, this is a case where "the whole is greater than the sum of the parts": the effect of AEDB in half-cells is rather modest, whereas in full-cells its addition results in tremendous performance improvement. The graphitejjNCM851005 full-cell in the presence of AEDB has a capacity retention of 88 % after 100 cycles, even when the upper cutoff voltage is set to 4.35 V, corresponding to 4.4 V vs Li + /Li, whereas with standard electrolyte under the same conditions it is only 21 %. The study shows a simple and easy approach to using Ni-rich cathodes in an extended voltage window and demonstrates the importance of full-cell testing for electrolyte additive selection.

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Section: Additive Effect On the Stabilization Of Ncm851005 Cathodementioning

confidence: 99%

Cross‐Talk‐Suppressing Electrolyte Additive Enabling High Voltage Performance of Ni‐Rich Layered Oxides in Li‐Ion Batteries

et al. 2021

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“…Thus, it can be concluded that LiDFOB additive has no significant effect on the Li striping/plating behavior and therefore, the improvement in electrochemical performance of the graphite||Li batteries is mainly attributed to the LiDFOB-induced CEI on the graphite cathode. [7,8] To elucidate the effect of LiDFOB-induced CEI on the rate capability of graphite cathodes, graphite||Li cells were charged and discharged at current rates ranging from 1 to 50 C (Figure 3a and Figure S4, Supporting Information). Clearly, when charging/discharging at increasing C rates, the graphite cathode cycled in electrolyte with LiDFOB additive shows a smaller increase in cell polarization up to 50 C (see Figure S4, Supporting Information), further confirming this uniform thin CEI is highly conductive for anions.…”

Section: Resultsmentioning

confidence: 99%

Ultrafast Charging and Stable Cycling Dual‐Ion Batteries Enabled via an Artificial Cathode–Electrolyte Interface

Wang

Zhang

Wang

et al. 2021

Adv Funct Materials

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Low-cost and environment-friendly dual-ion batteries (DIBs) with fast-charging characteristics facilitate the development of high-power energy storage devices. However, the incompatibility between the cathode and electrolyte at high voltage results in low Coulombic efficiency (CE) and short lifespan. Here, the addition of ≈0.5 wt% lithium difluoro(oxalate) borate salt into the electrolyte forms a robust and durable cathode-electrolyte interface (CEI) in situ on the graphite surface, which enables remarkable cycling of the graphite||Li battery with 87.5% capacity retention after 4000 cycles at 5 C and ultrafast rate capability with 88.8% capacity retention under 40 C (4 A g −1 ), delivering high-power of 0.4-18.8 kW kg −1 at energy densities of 422.7-318.8 Wh kg −1 . Taking advantage of this robust CEI, a graphite||graphite full battery demonstrates high reversible capacities of 97.6, 92.8, 88.7, and 85.4 mAh (g cathode) −1 at current rates of 10, 20, 30, and 40 C, respectively. The full battery also shows a long cycling life of over 6500 cycles with 92.4% capacity retention and an average CE of ≈99.4% at 1 A g −1 , which is superior to other dual-graphite (carbon) batteries in the literature. This work offers an effective interface-stabilizing strategy on protecting graphite cathodes and a promising approach for developing DIBs with high-power capability.

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“…Dong et al [130] . considered lithium difluoro(oxalato)borate (LiDFOB) as an additive, which plays a dual role in the formation of the CEI and SEI.…”

Section: Ni‐rich Ternary Cathode Materialsmentioning

confidence: 99%

Nickel‐Rich Layered Cathode Materials for Lithium‐Ion Batteries

Qiu

Yang

et al. 2021

Chemistry A European J

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Nickel‐rich layered transition metal oxides are considered as promising cathode candidates to construct next‐generation lithium‐ion batteries to satisfy the demands of electrical vehicles, because of the high energy density, low cost, and environment friendliness. However, some problems related to rate capability, structure stability, and safety still hamper their commercial application. In this Review, beginning with the relationships between the physicochemical properties and electrochemical performance, the underlying mechanisms of the capacity/voltage fade and the unstable structure of Ni‐rich cathodes are deeply analyzed. Furthermore, the recent research progress of Ni‐rich oxide cathode materials through element doping, surface modification, and structure tuning are summarized. Finally, this review concludes by discussing new insights to expand the field of Ni‐rich oxides and promote practical applications.

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Insights into the Dual Role of Lithium Difluoro(oxalato)borate Additive in Improving the Electrochemical Performance of NMC811||Graphite Cells

Cited by 76 publications

References 40 publications

Cross‐Talk‐Suppressing Electrolyte Additive Enabling High Voltage Performance of Ni‐Rich Layered Oxides in Li‐Ion Batteries

Cross‐Talk‐Suppressing Electrolyte Additive Enabling High Voltage Performance of Ni‐Rich Layered Oxides in Li‐Ion Batteries

Ultrafast Charging and Stable Cycling Dual‐Ion Batteries Enabled via an Artificial Cathode–Electrolyte Interface

Nickel‐Rich Layered Cathode Materials for Lithium‐Ion Batteries

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