石榴石型立方相Li_(7)La_(3)Zr_(2)O_(12)固态电解质的制备及储锂性能

石榴石型立方相Li_(7)La_(3)Zr_(2)O_(12)(LLZO)具有高的离子电导率和热稳定性,在固态锂电池领域颇具应用前景。煅烧温度对制备高性能立方相LLZO至关重要。为此,首先采用不同煅烧温度(1050℃、1100℃、1150℃、1200℃、1250℃)制备了LLZO,然后将10%磺酸甜菜碱改性的聚偏二氟乙烯(SB-PVDF)与90%LLZO复合制备固态电解质膜,并研究其电化学储锂性能。结果表明:在最优煅烧温度1200℃时制备的LLZO为纯立方相结构,相对致密度高达92.4%,离子电导率为1.21×10^(-4)S/cm,活化能为0.335eV,相应的固态锂电池在1.0C充放电时的放电比容量为124.3mAh/g,循环200圈后容量保持率为93.4%,优于其他样品。

Li_(7)La_(3)Zr_(2)O_(12)基氧化铝薄膜的制备及对固态电解质应用性能的影响

Li_(7)La_(3)Zr_(2)O_(12)(LLZO)具有离子电导率高、电化学窗口宽、与锂负极相容性好的特点,在锂离子电池领域成为了传统有机液态电解质的潜在替代品。然而,LLZO极易与空气中的CO_(2)、H_(2)O反应生成副产物Li_(2)CO_(3),致使LLZO离子电导率降低,甚至丧失。针对这一问题,本研究采用先旋涂后烧结的方法在LLZO表面构筑氧化铝薄膜,借助致密氧化铝薄膜阻隔LLZO与空气的直接接触的特性,改善和提高LLZO的空气-水稳定性。结果表明,采用该方法可在LLZO表面构筑厚度约为13.34μm的无定形氧化铝薄膜层。该薄膜层有效提高了LLZO对气体的阻隔性,增大了LLZO表面疏水特性,在一定程度上抑制了Li_(2)CO_(3)的生成。同时,由于渗入LLZO中氧化铝对空隙的填充作用,强化了离子传输特性,使负载薄膜后LLZO的离子传导的活化能从0.40 eV降低至0.28eV,离子电导率从4.48×10^(5)S·cm^(-1)提高到5.06×10^(-5)S·cm^(-1),提高了13%。

低成本Nb掺杂Li_(7)La_(3)Zr_(2)O_(12)固态电解质的性能与应用研究

固态电池因其在能量密度、循环寿命和安全性等方面的优异性能受到关注。其核心组件为固态电解质材料。具有石榴石结构的Li_(7)La_(3)Zr_(2)O_(12)(LLZO)氧化物固态电解质由于具备宽电化学窗口、良好的离子传导性、稳定的化学性能及简单的制备工艺等特点而得到广泛研究。本研究采用Nb元素对LLZO进行掺杂,成功制备得到Li_(6.75)La_(3)Zr_(1.75)Nb_(0.25)O_(12)(LLZNO)氧化物固态电解质,其离子电导率达到了7.79×10^(-4)S/cm,且制备成本与未掺杂的LLZO相比无明显增加。将其涂覆在聚乙烯(PP)隔膜表面形成PP-LLZNO隔膜,表现出良好的热稳定性和离子电导率。与Al_(2)O_(3)涂覆隔膜或固态电解质Li_(6.75)La_(3)Zr_(1.75)Ta_(0.25)O_(12)(LLZTO)涂覆隔膜组装的电池相比,组装了PP-LLZNO涂覆隔膜的扣式电池和软包电池的容量保持率分别达到了84.99%(50圈)和57.40%(100圈),展现出更优异的性能。因此,高离子电导率和低成本LLZNO的制备对固态电解质的大规模生产及在固态电池中的广泛应用具有一定的参考意义。

双掺杂提升Li_(7)La_(3)Zr_(2)O_(12)锂离子传导能力

Li_(7)La_(3)Zr_(2)O_(12)(LLZO)固体电解质由于优越的综合性能,而极有可能应用于全固态锂电池。但其较低的锂离子电导率影响了电池性能。为进一步提高其锂离子传导能力,采用一定量Ga掺杂锂位将其稳定为立方相,并将不同半径的Cr^(3+),Sc^(3+),Gd^(3+)分别掺杂锆位,并研究它们对LLZO结构及性能的影响。结果表明,Ga,Sc共掺时制备的Li_(6.4)Ga_(0.25)La_(3)Zr_(1.85)Sc_(0.15)O_(12)具有最高的室温离子电导率,可达1.20×10^(-3 )S/cm,而活化能仅为0.22 eV。

烧结助剂ZnO对Li_(6.5)La_(3)Zr_(1.5)Nb_(0.5)O_(12)固态电解质离子电导率及循环稳定性的影响

采用固相合成法制备Li_(6.5)La_(3)Zr_(1.5)Nb_(0.5)O_(12)(简称LLZNO)固态电解质,分析了质量分数为0.00%~2.00%的ZnO对LLZNO离子电导率和循环稳定性的影响。采用X射线衍射仪、扫描电子显微镜、电化学阻抗谱以及恒流充放电测试,探究了样品的晶体结构、断面形貌、离子电导率及其对锂循环稳定性。结果表明:随着样品中ZnO质量分数的增加,样品烧结气孔数量明显减少,断面形貌平整。当ZnO的质量分数为0.50%时,样品为立方相,室温离子电导率提升了14.63%;在80h(40次)的恒流充放电循环中,电压保持稳定,具有良好的循环性能。

Al_(0.25)Li_(6.25)La_(3)Zr_(2)O_(12)包覆LiCoO_(2)降低锂离子电池界面阻抗

本论文通过固相烧结法制备Al_(0.25)Li_(6.25)La_(3)Zr_(2)O_(12)(LLZO)包覆的LiCoO2(LCO)材料,以提高其界面稳定性并降低界面阻抗为目的。实验结果表明,电化学性能明显得到改善。在3.0-4.62 V的电压区间充放电50圈,包覆后材料的比容量保持率为70%,高于未包覆的65%。此外,包覆后材料的电荷转移电阻从22.5Ω降低至15.0Ω,倍率性能得到较大改善。本工作研究了固态电解质LLZO包覆钴酸锂对电性能的影响,对快充钴酸锂电池材料的设计具有较大参考意义。

石榴石型Li_(7)La_(3)Zr_(2)O_(12)固态电解质离子电导率及电极界面问题研究进展

石榴石型Li_(7)La_(3)Zr_(2)O_(12)(LLZO)固态电解质因高安全性且对锂金属稳定成为固态锂电池的关键材料。但是,石榴石型固态电解质离子电导率还有待提高以及固-固界面不良接触导致的界面电阻大等问题使LLZO基固态电池的实际应用受到了限制。从石榴石型LLZO结构角度出发,探讨了锂离子输运机制并综述了提高离子电导率的策略及最新成果。针对固态锂电池无法避免的界面问题,从LLZO固态电解质与同为固态的电极接触方面,总结了优化界面的具体方法。最后,提出了石榴石型固态电解质未来可研究的方向,并促进其在全固态锂电池中的发展和应用。

Mo,Al掺杂的Li_(7)La_(3)Zr_(2)O_(12)基复合固态电解质的制备及全固态电池性能研究

通过固态电解质构建的全固态锂离子电池具有极高的安全性及可靠性,是目前锂离子电池领域的研究热点。其中复合固态电解质既改善了聚合物电解质力学性能差、离子电导率低等缺点又解决了无机固态电解质的界面接触等问题。本文通过溶胶-凝胶法制备了掺杂了Al、Mo的Li_(7)La_(3)Zr_(2)O_(12)粉体,并将其与PEO(聚环氧乙烷)复合,利用溶液浇筑法制备了不同比例的复合固态电解质,考察其在全固态电池中的性能。通过X射线衍射(XRD)、扫描电子显微镜(SEM)、差示扫描量热仪(DSC)等测试手段对Li_(6.65)Al_(0.05)La_(3)Zr_(1.9)Mo_(0.1)O_(12)粉体以及复合固态电解质进行了材料表征。同时利用电化学工作站、电池充放电测试系统测试了复合固态电解质在全固态电池中的应用性能。与纯PEO电解质相比,复合15%Li_(6.65)Al_(0.05)La_(3)Zr_(1.9)Mo_(0.1)O_(12)的电解质电化学窗口为4.79V,可以在0.2mA/cm^(2)下稳定循环500h,在0.1C倍率下,循环100圈容量保持率为89.9%。

石榴石固态电解质材料Li_(6.4)Al_(0.2)La_(3)Zr_(2)O_(12)的制备及性能

采用固相反应法制得Al掺杂的固态电解质材料Li_(6.4)Al_(0.2)La_(3)Zr_(2)O_(12)(LALZO),利用扫描电子显微镜(SEM)、X射线衍射仪(XRD)和交流阻抗谱等检测手段表征了所得样品的晶体结构与电化学性能,研究了不同烧结方式对材料的结构、微观形貌和电化学性能的影响,探究了固相反应过程机理.研究结果表明:混合料加热到425℃时开始生成立方相LALZO,更高温度下立方相LALZO经由Li_(0.5)Al_(0.5)La_(2)O_(4)和Li_(2)ZrO_(3)等中间相转化生成;425℃预反应后再经1000℃烧结可得到纯的立方相LALZO;与聚环氧乙烷(PEO)组成复合固态电解质时,该材料在30℃下离子电导率可达3.61×10^(-5)S/cm,具有良好的电化学性能.

Structural,electronic,and Li-ion mobility properties of garnet-type Li_(7)La_(3)Zr_(2)O_(12) surface:An insight from first-principles calculations

Garnet-type Li_(7)La_(3)Zr_(2)O_(12)(LLZO) is a promising solid-state electrolyte for Li-ion batteries,but Li-dendrite's formation greatly limits the applications.In this paper,we systematically investigate the stability,electronic properties,and Li-ion mobility of the LLZO surface by the ifrst-principles calculations.We consider the(110) and(001) slab structures with different terminations in the t-and c-LLZO.Our results indicate that both(110) and(001) surfaces prefer to form Li-rich termination due to their low surface energies for either t-or c-LLZO.Moreover,with the decrease of Li contents the stability of Li-rich surfaces is improved initially and degrades later.Unfortunately,the localized surface states at the Fermi level can induce the formation of metallic Li on the Li-rich surfaces.In comparison,Li/La-termination has a relatively low metallic Li formation tendency due to its rather low diffusion barrier.In fact,Li-ion can spontaneously migrate along path II(Li3→Li2) on the Li/La-T(001) surface.In contrast,it is more difficult for Li-ion diffusion on the Li-T(001) surface,which has a minimum diffusion barrier of 0.50 eV.Interestingly,the minimum diffusion barrier decreases to 0.34 eV when removing four Li-ions from the Li-T(001) surface.Thus,our study suggests that by varying Li contents,the stability and Li-ion diffusion barrier of LLZO surfaces can be altered favorably.These advantages can inhibit the formation of metallic Li on the LLZO surfaces.

Li_(6.6)La_(3)Zr_(1.6)V_(0.4)O_(12)复合PEO基固态电解质的制备及其性能研究

复合固态电解质因其在提高能量密度和安全性方面的潜力而备受关注。通过固相烧结合成Li_(6.6)La_(3)Zr_(1.6)V_(0.4)O_(12),并将Li_(6.6)La_(3)Zr_(1.6)V_(0.4)O_(12)作为一种活性填料和聚氧化乙烯制备复合固态电解质。与纯聚氧化乙烯电解质相比,Li_(6.6)La_(3)Zr_(1.6)V_(0.4)O_(12)复合固态电解质膜不仅具有更好的离子电导率(25℃时为1.9×10^(-5)S·cm^(-1),80℃时为4.3×10^(-3)S·cm^(-1)),其锂离子转移数也有所提高,达到0.79。LiFePO_(4)/固态电解质/Li组装电池的初始放电容量达到177.4 m A·h·g^(-1);在高倍率(1 C)下,电池的比容量仍然为103.2 mA·h·g^(-1);复合固态电解质对称锂电池在50℃下可连续工作1000 h,无短路。Li_(6.6)La_(3)Zr_(1.6)V_(0.4)O_(12)作为活性离子导体,提高了固态电解质的整体性能。

固态电解质锂镧锆氧(Li_(7)La_(3)Zr_(2)O_(12))制备及第一性原理研究

固态电解质(SSE)是锂离子电池(LIB)的关键材料.Li_(7)La_(3)Zr_(2)O_(12)(LLZO)固体电解质是全固态锂离子电池开发中的关键部分.采用高温固相法制备了不同烧结温度后的四方Li_(7)La_(3)Zr_(2)O_(12)(t-LLZO)和立方Li_(7)La_(3)Zr_(2)O_(12)(c-LLZO),分析了两种样品的结构性能.800℃下烧结12小时的t-LLZO呈四方相,晶格尺寸为a=b=13.13064,c=12.66024,离子电导率为3.42×10^(-8) S·cm^(-1);1000℃下烧结12小时的c-LLZO呈立方相,晶格尺寸为a=b=c=13.03544,离子电导率为8.48×10^(-5) S·cm^(-1).另基于密度泛函理论(DFT)的第一性原理计算了四方相和立方相的LLZO固体电解质材料的能带结构、晶格参数、态密度和键布居.通过理论计算解释了四方相LLZO离子电导率低于立方相LLZO的原因.

石榴石型Li_(7)La_(3)Zr_(2)O_(12)固态锂金属电池的界面问题研究进展

固态锂金属电池具有高能量密度、高安全性、宽工作温度范围、长服役寿命等优势,是下一代锂电池体系的重要发展方向之一。作为典型的氧化物固态电解质,Li_(7)La_(3)Zr_(2)O_(12)(LLZO)具有锂离子电导率高、电化学窗口较宽、机械强度高和热稳定性好等优点,因此LLZO固态锂金属电池受到业界的广泛关注。但是,LLZO固态锂金属电池还存在锂枝晶穿透固态电解质生长造成电池短路、电解质/电极界面电阻过高等问题,影响其实际应用。这些问题与LLZO的显微结构特征、正极材料与LLZO的化学和电化学相容性、正极与电解质的界面结合性、金属锂负极对LLZO的浸润性等因素有关。本文总结了以上问题的解决策略。对于正极侧,通过活性颗粒表面包覆、三维固态电解质界面构筑、柔性聚合物或凝胶电解质中间层引入、正极活性颗粒与柔性或黏性离子传导材料复合等手段,可改善正极与LLZO的相容性,并降低正极界面电阻。对于负极界面,消除LLZO电解质表面碳酸锂、引入反应活性或柔性中间层、调控金属锂负极组成等方法,可改善锂对LLZO的浸润性,降低负极界面电阻。最后,本文对未来研究和发展方向给出了建议。

基于第一性原理计算的Li_(7)La_(3)Zr_(2)O_(12)固态电解质的研究进展

Li_(7)La_(3)Zr_(2)O_(12)固态电解质具备高离子电导率、对锂金属负极良好的化学稳定性以及宽电化学窗口等特点,被视为最具发展和应用前景的固态电解质之一。基于密度泛函理论计算的第一性原理计算是从量子力学出发,在电子层面计算个体和总体的电子和原子行为。将第一性原理计算与Li_(7)La_(3)Zr_(2)O_(12)固态电解质研究相结合可以在原子尺度上预测和解释电解质材料的性质和行为,同时将计算和系统模型相结合有助于解释该电池系统复杂的实验表征结果。概括了第一性原理计算在Li_(7)La_(3)Zr_(2)O_(12)固态电解质中的应用,总结Li_(7)La_(3)Zr_(2)O_(12)的电子结构和晶体结构等微观结构特征,分析了锂负极与电解质的接触角、锂离子的迁移以及电解质热力学性质等物理化学性质,最后对第一性原理计算在固态电解质研究的未来方向进行展望。

Li_(6.4)La_(3)Zr_(1.4)Ta_(0.6)O_(12)固态电解质膜的制备与性能研究

采用溶液浇筑法制备以聚偏氟乙烯为基的Li_(6.4)La_(3)Zr_(1.4)Ta_(0.6)O_(12)以及Li_(7)La_(3)Zr_(2)O_(12)的固态电解质膜,探讨两者对复合固态电解质离子电导率以及其他性能的影响;并将Li_(6.4)La_(3)Zr_(1.4)Ta_(0.6)O_(12)与LiFePO_(4)正极以及负极Li组装成固态电池,研究其电化学性能。研究发现:Li_(6.4)La_(3)Zr_(1.4)Ta_(0.6)O_(12)复合聚合物电解质膜的离子电导率为8.35×10^(-5) S/cm,比Li_(7)La_(3)Zr_(2)O_(12)更高;Li_(6.4)La_(3)Zr_(1.4)Ta_(0.6)O_(12)复合固态电解质膜的电化学稳定窗口达到5.6 V。该电池在室温下具有优良的综合电特性,表明聚偏氟乙烯-Li_(6.4)La_(3)Zr_(1.4)Ta_(0.6)O_(12)复合膜是一种较好的固态锂电池电解质膜。

固态无机电解质Li_(7)La_(3)Zr_(2)O_(12)的改性研究进展

作为一种固态无机电解质材料,石榴石型立方相Li_(7)La_(3)Zr_(2)O_(12)具有较高的室温锂离子电导率、较宽的电化学窗口和优良的热稳定性等特点,是高安全性、高能量密度固态锂离子电池实现商业化应用的关键。阐述了Li_(7)La_(3)Zr_(2)O_(12)的晶体结构与锂传导机理,综述了元素掺杂、聚合物电解质复合、烧结助剂引入、表面包覆或修饰等方式对Li_(7)La_(3)Zr_(2)O_(12)的物相结构稳定性、界面阻抗与相容性、烧结活性、离子电导率等进行改性的最新研究进展。最后,针对Li_(7)La_(3)Zr_(2)O_(12)在产业化应用中所面临的障碍与挑战,提出了制备新工艺的开发、离子电导率的多重改性以及柔性复合电解质膜的结构设计与优化等应对策略,为推动高性能固态锂离子电池的发展提供依据。

From protonation & Li-rich contamination to grain-boundary segregation: Evaluations of solvent-free vs. wet routes on preparing Li_(7)La_(3)Zr_(2)O_(12) solid electrolyte

Garnet-type Li_(7)La_(3)Zr_(2)O_(12)(LLZO) has been recognized as a candidate solid electrolyte for high-safety Lianode based solid-state batteries because of its electro-chemical stability against Li-metal and high ionic conductivity. Solvent(e.g., isopropanol(IPA)) has been commonly applied for preparing LLZO powders and ceramics. However, the deterioration of the proton-exchange between LLZO and IPA/absorbed moisture during the mixing and tailoring route has aroused less attention. In this study, a solvent-free dry milling route was developed for preparing the LLZO powders and ceramics. For orthogonal four categories of samples prepared using solvent-free and IPA-assisted routes in the mixing and tailoring processes, the critical evaluation was conducted on the crystallinity, surficial morphology, and contamination of ascalcinated and as-tailored particles, the cross-sectional microstructure of green and sintered pellets,the morphology and electro-chemical properties of grain boundaries in ceramics, as well as the interfacial resistance and performance of Li anode based symmetric batteries. The wet route introduced Li-rich contaminations(e.g., Li OH·H)_(2)O and Li)_(2)CO)_(3)) onto the surfaces of LLZO particles and Li-Ta-O segregations at the adjacent and triangular grain boundaries. The LLZO solid electrolytes prepared through dry mixing in combination with the dry tailoring route without the use of any solvent were found to the optimal performance. The fundamental material properties in the whole LLZO preparation process were found, which are of guiding significance to the development of LLZO powder and ceramic production craft.

石榴石型固态电解质Li_(7)La_(3)Zr_(2)O_(12)的改性研究现状

固态电解质是高安全性、高能量密度的全固态锂电池的核心部件,其典型代表Li_(7)La_(3)Zr_(2)O_(12)(LLZO)具有高离子电导率、高机械强度、高电化学稳定性、低界面阻抗以及对锂金属负极良好的稳定性等优势,是科研人员重点关注的对象之一,但与液态电解质相比,目前LLZO仍存在低离子电导率和与电极固-固界面接触等问题。本文主要简介了LLZO的晶体结构、改性方式等对其离子电导率及界面阻抗的影响,同时对LLZO现存的问题进行了总结,对LLZO的未来发展方向进行了展望,为探索全固态锂电池的实际生产应用提供理论指导。

Ta、Ba共掺杂石榴石型Li_(7)La_(3)Zr_(2)O_(12)电解质的制备及性能研究

传统锂离子电池采用有机电解液体系,能量密度难以进一步提升,同时存在一定的安全隐患。采用无机固体电解质构建全固态锂电池,在提高电池能量密度同时可兼顾安全性问题。在众多无机固体电解质中,Li_(7)La_(3)Zr_(2)O_(12)(LLZO)石榴石电解质具有离子电导率高、与金属锂接触稳定等优势,成为受人关注的材料。为了进一步提高该材料的导电性,采用固相法合成Ta、Ba共掺杂LLZO(Li_(7-x+y)La_(3-y)Ba_(y)Zr_(2-x)Ta_(x)O_(12))电解质,采用X射线衍射、扫描电子显微镜和电化学阻抗法分析样品的物相结构、微观形貌及离子电导率。结果表明,Ta^(5+)掺杂能够稳定立方相结构,Ba^(2+)作为掺杂剂和烧结剂,促进晶粒生长和陶瓷致密化,从而降低总电阻。其中,Li_(6.45)La_(2.95)Ba_(0.05)Zr_(1.4)Ta_(0.6)O_(12)样品在室温下的总电导率为1.07×10^(-3) S·cm^(-1),活化能为0.378 eV。Ta^(5+)/Ba^(2+)共掺杂有利于制备高致密度和高电导率的石榴石型电解质材料。

Duality of Li_(2)CO_(3) in Solid-State Batteries

Solid-state batteries(SSBs)have been considered the most promising technology because of their superior energy density and safety.Among all the solid-state electrolytes(SEs),Li_(7) La_(3) Zr_(2) O_(12)(LLZO)with high ionic conductivity(3×10^(−4) S/cm)has been widely investigated.However,its large-scale production in ambient air faces a challenge.After air exposure,the generated Li_(2)CO_(3) layer deteriorates the ionic conductivity and interfacial wettability,thus greatly compromising the electrochemical performance of SSBs.Many works aim to eliminate this layer to recover the pristine LLZO surface.Unfor-tunately,few articles have emphasized the merits of Li_(2)CO_(3).In this review,we focus on the two-sidedness of Li_(2)CO_(3).We discuss the various characteristics of Li_(2)CO_(3) that can be used and recapitulate the strategies that utilize Li_(2)CO_(3).Insulating Li_(2)CO_(3) is no longer an obstacle but an opportunity for realizing intimate interfacial contact,high air stability,and outstand-ing electrochemical performance.This review aims to off er insightful guidelines for treating air-induced Li_(2)CO_(3) and lead to developing the enhanced air stability and electrochemical performance of LLZO.