介孔Li_(0.5)La_(0.5)TiO_3的制备及在聚合物/无机纳米复合固体电解质中的应用

首次采用凝胶冷冻干燥法制备孔径为20 nm左右的钙钛矿型Li0.5La0.5Ti O3(LLTO)介孔固体电解质。通过X射线衍射、扫描电镜、比表面与孔隙分析对其晶体结构和介孔结构进行表征。交流阻抗分析结果显示,相比本体LLTO,介孔LLTO的室温晶粒电导率变化不大,但由于晶界数量的增加导致室温晶界电导率有所下降。将制得的介孔LLTO加入(PEO)8∶Li TFSI聚合物电解质中形成聚合物/介孔无机纳米复合固体电解质,其室温导电率达5.38×10-5S/cm,较纯(PEO)8∶Li TFSI提高了4.2倍。

xCa_(0.8)Sr_(0.2)TiO_3-(1-x)Li_(0.5)La_(0.5)TiO_3系陶瓷介电性能的调控

采用烧成法制备了xCa_(0.8)Sr_(0.2)TiO_3-(1-x)Li_(0.5)La_(0.5)TiO_3(CST-LLT)(x=0.4~0.8)系介质陶瓷,表征了其物相组成、结构特征及介电性能。所制备的材料具有钙钛矿结构特征,随着Li_(0.5)La_(0.5)TiO_3组分的减少,1 170~1 260℃烧结的CST-LLT陶瓷介电常数(ε_r)变化范围在154.8~275.2,而品质因数(Q·f)在1 360~1 479GHz内先增加后逐渐减小,谐振频率温度系数(τ_f)变化范围为(-720.6~470.5)×10^(-6)/℃。当x=0.5,烧成温度为1 200℃,保温3h时,可得到理想的介电性能的介质陶瓷:ε_r=230,Q·f=1 455GHz,τ_f=24.5×10^(-6)/℃。

LiFePO_4锂电池正极材料的Li_(0.5)La_(0.5)TiO_3包覆改性

研究了以快离子导体Li_(0.5)La_(0.5)TiO_3(LLTO)包覆的LiFePO_4正极材料的锂离子电池的电化学性能。采用溶剂热法制备锂电池正极材料LiFePO_4,再采用溶胶凝胶法制备的LLTO粉体对LiFePO_4进行包覆,包覆量为LiFePO_4质量分数的1%~4%.通过进行充放电测试、交流阻抗测试及循环伏安测试,研究了不同包覆量对电池的充放电比容量、循环性能及可逆性的影响。发现当LLTO含量为3 wt%,2 C、5 C时,充放电时相对于没有包覆LLTO的电池正极材料的比容量分别提高29.7%、31.6%,30次循环之后,容量损失率减小4.13%,循环伏安曲线上氧化还原峰之间的电位差仅为0.117 V,以3 wt%的LLTO包覆改性LiFePO_4显著提高了电池的电化学性能。

Li_3PO_4对Li_(0.5)La_(0.5)TiO_3/Li_3PO_4复合固体电解质的电性能影响（英文）

利用复阻抗谱分析技术考察了复合Li_3PO_4的Li_(0.5)La_(0.5)Ti O_3(LLTO)固体电解质的离子电导率,同时还利用X射线衍射图谱、扫描电镜观测和相对致密度测量等实验手段研究了LLTO电解质中第二相的分散情况。结果发现,加入Li_3PO_4第二相后,尽管复合固体电解质LLTO拥有比较高的致密度,但是Li_3PO_4会导致离子电导率的降低。通过分析LLTO的晶体结构,晶界的微观结构和锂含量,阐明了LLTO离子电导率恶化的原因,往LLTO基质中分散的Li_3PO_4导致的锂含量和微观结构的变化是引起锂离子传导行为改变的主要原因。

Bi-functions of titanium and lanthanum co-doping to enhance theelectrochemical performance of spinel LiNi_(0.5)Mn_(1.5)O_(4)cathode

Spinel LiNi_(0.5)Mn_(1.5)O_(4)(LNMO)cathode material doped with Ti and La co-doping were synthesized through a solid-state method.The bi-functions of the Ti and La co-doping is realized.On the one hand,the stability of the LiNi_(0.5)Mn_(1.5)O_(4)crystal structure is enhanced and the Mn3t interference inside the material is reduced by the Ti doping.On the other hand,the co-doped La contributes to the formation of Li_(0.5)La_(0.5)TiO_(3)(LLTO)superionic conductor incorporated in the bulk LiNi_(0.5)Mn_(1.5)O_(4)phase,thereby enhancing the Li diffusion.With the help of XRD,FTIR,SEM and STEM techniques,La and Ti in the crystallographic structure and the dispersion of the LLTO superionic conductor in the bulk LNMO spinel are discussed.At the optimized molar ratio of 20:1 between LNMO and LLTO,the composite exhibits the best electrochemical performances in terms of the reversible capacity,rate capability and cycling stability.The lithium ion diffusion coefficient in the bulk LNMO phase is tripled by the LLTO superionic conductor incorporation.

LiFePO4的软化学合成及锂快离子导体修饰

采用溶剂热法制备正极材料LiFePO_4,采用溶胶凝胶法制备Li_(0.5)La_(0.5)TiO_3(LLTO)粉体,并通过酒精悬浮法对LiFePO_4进行修饰,修饰量为LiFePO_4质量的1%~4%,获得了薄壁蜂窝状自组装结构的LiFePO_4上修饰有球状LLTO纳米颗粒的复合正极材料。通过进行充放电测试、交流阻抗测试及循环伏安测试,研究了不同修饰量对电池的充放电比容量、循环性能及可逆性的影响,发现当LLTO含量为3%(w/w)时,以2C和5C倍率放电相对于没有修饰LLTO的LiFePO_4的比容量分别提高29.7%和31.6%,30次循环之后,容量损失率较未改性前减小4.13%,循环伏安曲线上氧化还原峰之间的电位差仅为0.117 V,以3%的LLTO修饰改性的LiFePO_4显著提高了电池的倍率性能、循环性能和低温性能。