勘探用Li-Si/LiNO_3-KNO_3-CsNO_3/Cu_3V_2O_8热电池放电性能研究

制备LiNO3-KNO3-CsNO3电解质,对其进行差热分析;制备低温高电位的Li-Si/LiNO3-KNO3-CsNO3/Cu3V2O8单体热电池,研究正极中导电剂CNTs、电解质的添加量及温度等因素对该热电池放电性能的影响。结果表明:在正极中加入CNTs导电剂以及电解质可以改善单体热电池的放电性能,其适宜的添加量分别为5%、30%;加入过量的CNTs及电解质会对电池造成负面影响;温度对单体热电池放电性能的影响非常大,提高温度可在很大程度上提升单体热电池放电性能。

三元体系LiNO_3-NaNO_3-KNO_3相图预测及其热性能研究

采用对称的 Kohler 模型对 LiNO 3-NaNO 3-KNO 3三元体系的相图进行预测,得到三元共晶点为395．50 K,摩尔分数组成为（LiNO 3）＝0．388,（NaNO 3）＝0．102,（KNO 3）＝0．510.对该共晶点组成材料进行 DSC 实验测定,其熔点为397．32 K,而热重 TG 测试表明热稳定温度为868．62 K,表明该材料有可能作为高温蓄热传热材料应用于太阳能热电厂及核能发电厂,工作温度范围为397．32~868．62 K.

铝电极在LiNO3-KNO3熔盐中的电化学行为

采用循环伏安和恒电位电解法考察了铝电极在LiNO3-KNO3熔盐中的电化学行为.实验结果表明,在该熔盐中,锂离子在铝电极上的电还原过程伴随着新生态的锂原子向电极内部的随后扩散步骤;锂原子进入铝电极后与铝发生合金化,形成β-LiAl合金和γ-LiAl合金;锂离子在铝电极上的还原过程受还原态锂在铝基体内的扩散步骤控制.循环伏安实验发现,铝电极在该熔盐中的氧化和还原峰电流都先随循环次数增加而增大,最后基本上趋于稳定.这表明铝电极在该熔盐体系中具有较好的电化学稳定性.

LiNO_3-KNO_3二元相图的热力学优化和计算

引入短程有序—扩展似化学模型来描述Li NO3-KNO3二元体系液相的Gibbs自由能,根据实验测定的相图数据,运用CALPHAD(Calculation of Phase Diagram)技术对该体系进行了热力学优化和计算,优化计算的结果和实测值符合很好。

钻井用Li-Si/LiNO_3-KNO_3-Ca(NO_3)_2/Cu_3V_2O_8热电池放电性能的研究

合成了Cu3V2O8（CVO）作为正极活性物质,并通过X射线衍射光谱法（XRD）对CVO进行表征;制备了Li NO3-KNO3-Ca（NO3）2电解质,并测试了其熔点。通过对Li-Si/Li NO3-KNO3-Ca（NO3）2/CVO单体热电池进行恒流放电测试,探究了导电剂CNT、电解质在正极材料中的添加量以及温度对放电性能的影响。结果表明,在正极中,CNT与电解质的适宜质量分数分别为5%、35%。单体电池的放电性能受温度的影响比较大,温度在250～280℃时,单体电池有较好的放电效果。

An effective artificial layer boosting high-performance all-solid-state lithium batteries with high coulombic efficiency

All-solid-state lithium batteries(ASSLBs)employ high-capacity lithium(Li)metal as the anode and exhibit a higher energy density than that of conventional Li-ion batteries.However,the problems arose from the Li dendrites induce severely parasitic reaction between Li and electrolytes,leading to low coulombic efficiency(CE)and poor cyclic stability.Herein,a poly(vinylidene-co-hexafluoropropylene)/lithium nitrate(PVDF-HFP/LiNO_(3),marked as PFH/LN)artificial layer is employed to modified Li and achieve high CE ASSLBs with polyethylene oxide-Li_(6.4) La_(3)Zr_(1.4)Ta_(0.6)O_(12)(PEO-LLZTO)electrolyte.LN serves as a functionalized additive to facilitate the formation of a robust solid electrolyte interface(SEI),effi-ciently suppressing the formation of Li dendrites.Additionally,LN as a“binder”effectively links PFH with Li,providing good contact.PFH possesses high mechanical strength and moderate flexibility,which can not only physically inhibit the growth of Li dendrites,but also maintain the structural integrity of arti-ficial layer over long-term cycles.Finally,Li/Li cells with such artificial layer demonstrate ultralong cycle life of 1800 and 1000 h under 0.2 and 0.4 mA cm^(-1),respectively.Furtherly,high CE can be achieved when applied in both LiFePO 4 full cells and Li-Cu half cells.This work offers a facile and efficient strategy to greatly promote CE in PEO-based ASSLBs.