铅酸电池负极板栅用Al/Pb复合材料的制备及性能

采用熔盐化学镀-金属浴工艺在金属Al表面镀制Pb镀层,并对复合材料的性能进行研究。利用扫描电镜和金相显微镜观察Al/Pb复合材料的表面形貌和结合界面的金相结构,利用万能材料试验机测试Pb镀层与基体的结合力,并对Pb镀层的完整性以及在5 mol/L H2SO4溶液中的耐腐蚀性和循环稳定性进行测试,结果表明:Pb镀层表面平整、光滑、无孔洞,镀层厚度均匀,且Al/Pb结合界面有明显的过渡层,形成了冶金结合;镀层与基体的结合强度均值达2.621 MPa,能够满足铅酸电池板栅的要求;采用熔盐化学镀-金属浴工艺制备的铅镀层的完整性、耐腐蚀性和稳定性满足铅酸电池负极板栅的要求,Al/Pb复合材料可以作为轻质板栅用于铅酸电池负极。

高性能全固态电池Li_(7-x)PS_(6-x)Cl_(x)电解质中氯含量的优化

在全固态电池快速发展的背景下,硫银锗矿型电解质Li_(6)PS_(5)Cl因其高离子导率、加工性能好等特点备受瞩目。电解质中的氯取代显著影响其离子电导率和稳定性等特性,但调节氯含量对界面影响的研究仍有待完善。本文采用固相烧结法制备了x=1.0~1.5的Li_(7-x)PS_(6-x)Cl_(x)电解质,评估氯含量(x=1.0~1.5所对应的氯摩尔分数分别为25%~37.5%)对其理化性质的影响。此外,基于电解质在电池不同部件中的性能表现,结合X光电子能谱与阻抗弛豫时间分布等,系统评估氯含量对界面与性能的影响。Li_(5.7)PS_(4.7)Cl_(1.3)材料在正极中展现出优秀的倍率性能;而对于电解质层,高氯含量材料Li_(5.5)PS_(4.5)Cl_(1.5)将导致正、负极界面劣化,降低循环性能。通过调控氯含量,可平衡离子电导与界面反应,从而提升综合性能。所组装的LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)@Li_(5.7)PS_(4.7)Cl_(1.3)|Li_(6)PS_(5)Cl|LiIn电池,在20 mg/cm^(2)载量、0.5C倍率循环300圈后仍有132.8 mA·h/g的比容量。

过充保护添加剂1,2-二甲氧基-4-硝基苯和1,4-二甲氧基-2-硝基苯在锂离子电池中的应用

在锂离子电池电解液1mol·L-1LiPF6/(碳酸乙烯酯(EC)+碳酸二乙酯(DEC)+碳酸甲乙酯(EMC)(1:1:1,体积比))中分别添加1,2-二甲氧基-4-硝基苯(DMNB1)和1,4-二甲氧基-2-硝基苯(DMNB2)作为防过充添加剂.采用循环伏安(CV)、恒流充放电、过充测试、电化学阻抗谱(EIS)、扫描电子显微镜(SEM)等手段研究了DMNB1和DMNB2的防过充效果,以及添加剂与LiNi1/3Co1/3Mn1/3O2材料的相容性.结果表明:DMNB1和DMNB2的氧化电位都在4.3V(vsLi/Li+)以上,且均能显著提高电池的过充保护性能.100%过充和5V截止电压过充测试表明,DMNB1的防过充性能优于DMNB2.采用基础电解液、添加0.1mol·L-1DMNB1和添加0.1mol·L-1DMNB2电解液的LiNi1/3Co1/3Mn1/3O2/Li电池,0.2C倍率下循环100次,容量保持率分别为98.4%、95.9%和68.1%.证明硝基在添加剂苯环上的取代位置和其电化学性能之间有着密切联系.

电解液组成对LiFePO_4电池低温性能的影响

研究了低温(-20℃)下磷酸铁锂正极材料与电解液的相容性。采用不同溶剂组成的电解液与磷酸铁锂正极组装成LiFePO4/Li半电池,进行电化学测试。结果表明:低温下电池界面阻抗是影响磷酸铁锂电池性能的关键因素;随着界面阻抗的增大,LiFePO4/Li半电池的放电容量显著下降,同时极化加重,放电平台降低,并且其界面阻抗的变化直接与电解液中线性酯和环状酯溶剂的比例相关。在-20℃下,环状酯类溶剂含量(体积分数)为33%的电解液界面阻抗最小,其组装的LiFePO4/Li半电池0.1C倍率下放电容量为113.9 mA·h/g,是常温放电容量的75%。

基于LLZTO@Ag复合层负极改性的硫化物全固态锂电池及其性能

硫化物全固态锂金属电池以其高比能和高安全性得到了越来越多的关注,但是电解质与正负极极材料之间严重的界面问题仍然限制其进一步发展.为解决Li_(6)PS5Cl固态电解质对金属锂不稳定的难点,许多工作提出引入合金负极、引入中间界面层以及电解质直接改性等策略,但是都和实际应用存在一定的差距.考虑到石榴石氧化物固态电解质Li_(6.4)La_(3)Zr_(1.4)Ta_(0.6)O_(12)(LLZTO)具有较高的锂离子电导率和极好的材料稳定性,而Ag金属具有良好的导锂性,因此创新性地提出采用LLZTO与Ag的复合界面层来解决Li6PS5Cl全固态电池的金属负极界面问题,提高全电池的循环稳定性.研究了LLZTO和Ag简单分散复合、均匀分散包覆复合以及纳米球磨复合等不同组成的LLZTO–Ag复合界面层方式对Li6PS5Cl全固态锂金属电池负极界面的改善作用,并探究了优化后的全固态电池的电化学性能.结果表明,纳米球磨复合得到的LLZTO@Ag复合界面层能有效阻止锂枝晶生长和电池短路.在最佳工艺下,全固态锂金属电池的0.1C首圈效率为77.5%,放电比容量为187.3 mA·h·g^(-1),经0.3C循环100圈后容量保持率为81.7%.

Synthesis and properties of single-crystal Ni-rich cathode materials in Li-ion batteries

Single-crystal Ni-rich cathode material LiNi0.88Co0.09Al0.03O2(SC) was synthesized by a high-temperature solid-state calcination method. Physicochemical properties of primary and delithiated SC samples were investigated by X-ray diffractometry, X-ray photoelectron spectroscopy, and transmission electron microscopy. Electrochemical performance was characterized by long-term cycling, cyclic voltammetry, and in-situ impedance spectroscopy. The results indicated that high temperature rendered layered oxides to lose lithium/oxygen in the interior and exterior, and induced cationic disordering. Besides, the solid-phase synthesis process promoted phase transformation for electrode materials, causing the coexisting multi-phase in a single particle. High temperature can foster the growth of single particles, but it caused unstable structure of layered phase.

氮掺杂多孔炭负载Cu_(2)S复合材料的制备及其储锂性能研究

过渡金属硫化物因价格低、比容量高而被认为是一种潜在的锂离子电池负极材料,但不理想的电导率和巨大的体积膨胀阻碍了其实际应用。利用溶胶-凝胶热解吹制法成功地在氮掺杂多孔炭中嵌入Cu_(2)S纳米粒子(Cu_(2)S@NC)。Cu_(2)S@NC作为负极具有良好的循环稳定性和高可逆比容量。氮掺杂多孔炭骨架作为导电桥确保了良好的电子导电性,薄壁结构缩短了锂离子扩散路径,增加了电极离子导电性。测试结果表明,1 A/g循环500次后比容量为407.6 mAh/g,0.1 A/g循环100次后比容量为623.3 mAh/g。该合成路线有望为开发低成本、高性能的转化型金属硫化物负极材料提供一种新的解决方案。

Empirical decay relationship between ionic conductivity and porosity of garnet type inorganic solid-state electrolytes

Ionic conductivity is one of the crucial parameters for inorganic solid-state electrolytes.To explore the relationship between porosity and ionic conductivity,a series of Li_(6.4)Ga_(0.2)La_(3)Zr_(2)O_(12) garnet type solid-state electrolytes with different porosities were prepared via solid-state reaction.Based on the quantified data,an empirical decay relationship was summarized and discussed by means of mathematical model and dimensional analysis method.It suggests that open porosity causes ionic conductivity to decrease exponentially.The pre-exponential factor obeys the Arrhenius Law quite well with the activation energy of 0.23 eV,and the decay constant is averaged to be 2.62%.While the closed porosity causes ionic conductivity to decrease linearly.The slope and intercept of this linear pattern also obey the Arrhenius Law and the activation energies are 0.24 and 0.27 eV,respectively.Moreover,the total porosity is linearly dependent on the open porosity,and different sintering conditions will lead to different linear patterns with different slopes and intercepts.