锌掺杂提高LiNi_(1/3)Co_(1/3)Mn_(1/3)O_2正极材料的电化学稳定性(英文)

通过共沉淀法与固相法相结合制备了掺锌的高稳定性Li(Ni1/3Co1/3Mn1/3)1-xZnxO2(x=0, 0.02, 0.05)正极材料. 循环伏安(CV)曲线表明Zn掺杂使氧化峰与还原峰的电势差减小到0.09 V, 电化学阻抗谱(EIS)曲线表明Zn 掺杂使电极的阻抗从 266 Ω减小到 102 Ω. Li+嵌入扩散系数从1.20×10-11cm2·s-1增大到 2.54×10-11cm2·s-1. Li(Ni1/3Co1/3Mn1/3)0.98Zn0.02O2正极材料以0.3C充放电在较高的截止电压(4.6 V)下比其他两种材料的电化学循环性能更稳定, 其第二周的放电比容量为176.2 mAh·g-1, 室温下循环 100 周后容量几乎没衰减; 高温(55℃)下充放电循环100周, 其放电比容量平均每周仅衰减0.20%, 远小于其他两种正极材料(LiNi1/3Co1/3Mn1/3O2平均每周衰减0.54%; Li(Ni1/3Co1/3Mn1/3)0.95Zn0.05O2平均每周衰减0.38%). Li(Ni1/3Co1/3Mn1/3)0.98Zn0.02O2正极材料以3C充放电时其放电比容量可达142 mAh·g-1, 高于其他两种正极材料. 电化学稳定性的提高归因于 Zn 掺杂后减小了电极的极化和阻抗, 增大了锂离子扩散系数.

微过充下三元镍钴铝锂离子电池的老化机理

电芯的不一致性及电量不均衡,会导致部分锂离子电池单体出现微过充现象,但此情况对于电池容量的影响未被完全揭示。在不同最高截止电压(4.2 V、4.3 V和4.4 V)下对三元镍钴铝(Li_(x)Ni_(0.80)Co_(0.15)Al_(0.05)O_(2))电池进行恒流充电循环老化实验,采用差分电压分析、电化学阻抗谱(EIS)等测试方法,探究高截止电压循环对电池老化的影响。随着最高截止电压的升高,电池老化速度加快,以2.5 A电流循环280次后,4.2 V、4.3 V、4.4 V下的容量保持率分别为90.30%、88.19%和86.19%。差分电压分析表明,容量衰减加速的原因是正极活性物质损失和活性Li+损失。EIS测试表明,微过充导致固体电解质相界面(SEI)膜阻抗略微升高,电荷转移阻抗升高,且程度随截止电压的升高而增大。

快离子导体Li_(1.5)Y_(0.5)Zr_(1.5)(PO_(4))_(3)包覆层对富镍三元正极材料电化学性能的影响

研发富镍低钴的先进正极材料是目前提高锂离子电池能量密度和降低电池成本的有效办法。然而,随着Ni含量的增加,富镍层状氧化物普遍存在前驱体合成困难、结构不稳定和界面活性高等一系列问题,阻碍了富镍层状氧化物正极材料的市场化推广。本文采用优化的共沉淀法制备出结构稳定的LiNi_(0.8)Mn_(0.1)Co_(0.1)O_(2)(NCM811)正极材料,同时在NCM811材料表面均匀包覆快离子导体Li_(1.5)Y_(0.5)Zr_(1.5)(PO_(4))_(3)涂层,以克服富镍层状氧化物界面结构不稳定和易受电解液腐蚀的难题。在4.5 V高截止电压下,改性样品0.2 C的放电比容量为214.2 mAh·g^(-1),10 C的放电比容量高达158.8 mAh·g^(-1),高于原始样品的203.7 mAh·g^(-1)(0.2 C)和82.7 mAh·g^(-1)(10 C)。同时,改性样品在4.3 V下经1 C循环200次后的容量保持率高达84.7%,高于原始样品(61.94%)。

Tailoring electrolyte enables high-voltage Ni-rich NCM cathode against aggressive cathode chemistries for Li-ion batteries

The LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)(Ni-rich NCM)cathode materials suffer from electrochemical performance degradation upon cycling due to detrimental cathode interface reactions and irreversible surface phase transition when operating at a high voltage(≥4.5 V).Herein,a traditional carbonate electrolyte with lithium difluoro(oxalato)borate(Li DFOB)and tris(trimethylsilyl)phosphate(TMSP)as dual additives that can preferentially oxidize and decompose to form a stable F,B and Si-rich cathode-electrolyte interphase(CEI)that effectively inhibits continual electrolyte decomposition,transition metal dissolves,surface phase transition and gas generation.In addition,TMSP also removes trace H_(2)O/HF in the electrolyte to increase the electrolyte stability.Owing to the synergistic effect of Li DFOB and TMSP,the Li/LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2) half cells exhibit the capacity retention 76.3%after 500 cycles at a super high voltage of 4.7 V,the graphite/LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)full cells exhibit high capacity retention of 82.8%after 500 cycles at 4.5 V,and Li/LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)pouch cells exhibit high capacity retention 94%after 200 cycles at 4.5 V.This work is expected to provide an effective electrolyte optimizing strategy compatible with high energy density lithium-ion battery manufacturing systems.