纳米碳管的电化学贮锂性能

用透射电镜、高分辩透射电镜、X射线衍射和拉曼光谱表征了用催化热解法制备的纳米碳管的结构,研究了纳米碳管的电化学嵌脱锂性能.以纳米级铁粉为催化剂热解乙炔气得到的纳米碳管石墨化程度较低,结构中存在褶皱的石墨层、乱层石墨和微孔等缺陷,具有较高的贮锂容量,初始容量为640mAh/g,但循环稳定性较差.而以纳米级氧化铁粉为催化剂热解乙烯得到的纳米碳管结构比较规则,循环稳定性较好,但贮锂容量较低,初始容量为282 mAh/g.讨论了纳米碳管的结构对其温度特性和不同电流密度下的充放电容量的影响.     

锂离子电池预锂化补锂策略研究进展

锂离子电池(LIBs)因高能量密度和长循环寿命而被广泛用于储能电子产品、电动汽车等众多领域。然而,在锂离子电池首次充放电过程中,固体电解质界面(SEI)膜的形成会造成电解液发生不可逆分解、初始活性Li⁺损失(ALL)和不可逆容量损失,会影响电池体系容量和能量密度的发挥,对于硅基负极电池体系而言尤为显著。基于这一问题,亟需开发各种补锂策略来降低活性锂损失,有效提高电池体系的首次库仑效率(ICE),从而实现更高的能量密度和循环稳定性。结合现阶段所做工作,从正负极角度出发,将预锂化补锂策略分为正极预锂化和负极预锂化,主要包括富锂正极材料、富锂预锂化试剂、惰性锂金属粉、含锂有机溶液等一系列预锂化补锂措施。通过系统的分类、比较与总结后,对预锂化以实现电池的高能量密度和长循环寿命提出建议,有助于为预锂化策略走向商业化提供启示。     

纳米磷酸铁锂的制备及电化学性能研究

利用液相沉淀法合成了纳米级磷酸铁,并以此为铁源,通过碳热还原技术制备了粒径均匀的纳米级球形LiFePO4/C正极材料。经热分析(TG-DSC)、X射线衍射(XRD)、扫描电镜(SEM)、透射电镜(TEM)以及恒电流充放电测试,研究了纳米磷酸铁及纳米磷酸铁锂材料的结构、形貌以及电化学性能。实验结果表明材料的首次放电比容量达161.8 mAh.g-1(0.1C),库仑效率为98.3%;室温下在0.2C、0.5C、1C、2C及5C倍率充放电其首次放电比容量分别为156.5、144、138.9、125.6和105.7 mAh·g-1,材料具有较好的倍率性能。     

过渡金属及其化合物应用于锂硫电池的研究进展

锂硫电池因具有高理论比容量和性价比,被认为是具有发展潜力的新型二次电池。 但是,作为活性物质的单质硫和反应产物是电子绝缘体,充放电过程的中间产物多硫化锂在电解液中易于溶解和迁移引起“穿梭效应”和一系列的副反应,造成活性物质利用率低,电池的电化学稳定性变差。 本文综述了近年来过渡金属纳米材料应用于锂硫电池的研究进展,重点介绍了材料的合成方法以及其抑制多硫化锂溶解并促进其转化的反应机理,并对锂硫电池正极载体材料的发展方向进行了展望。     

全氟烷基膦酸锂电解液的制备与性能研究

选取氯代二异丙基膦(C6H14PCl)为原料, 利用电化学氟化方法, 得到全氟烷基膦酸[(C3F7)2PF3], (C3F7)2PF3与氟化锂(LiF)反应得到全氟烷基膦酸锂(Li[(C3F7)2PF4]), 将其溶于碳酸乙烯酯(EC)和碳酸二甲酯(DMC)质量比为1∶1的混合溶剂中得到电解液, 考察电解液的电导率、抗水性及氧化分解电位. 以LiCoO2为正极, 锂片为负极组装两电极模拟电池体系, 测试得到电池的放电平台为3.7 V; 电池的首次放电比容量为107 mA•h•g－1; 当循环放电40次后, 容量衰减较快, 电池循环50周后, 效率仍保持102%. 交流阻抗图谱表明电解液放电时的阻抗约为140 Ω. 研究结果表明, 全氟烷基膦酸锂有望成为新型锂离子二次电池的电解质盐.     

纳米级锂离子电池正极材料LiFePO4

LiFePO4以其价格低廉、稳定性好和无毒等优点而备受关注.但是非纳米LiFePO4的电子导电率低及扩散系数小限制了其在锂离子电池领域的大规模应用.而纳米电极材料以其特有的优点很好地解决了这些问题.本文主要综述了国内外合成纳米级LiFePO4 的不同方法及所得材料的对电化学性能和相关机理,以及纳米LiFePO4作为锂离子正极材料存在的问烫     

纳米级锂离子电池正极材料LiFePO4

LiFePO₄以其价格便宜,稳定性好,无毒等优点而倍受关注。但是非纳米LiFePO₄的电子导电率低及扩散系数小限制了其在锂离子电池领域的大规模应用。而纳米电极材料以其特有的优点很好的解决了这些问题。本文主要综述了国内外合成纳米级LiFePO₄ 的不同方法及所得材料的对电化学性能和相关机理,以及纳米LiFePO₄作为锂离子正极材料存在的问题。     

纳米级锰酸锂阴极材料的制备及其电化学性能研究

1．引言 锰酸锂阴极材料具有制备工艺简单、价格低廉、环保、安全性能较好等优点，已被国内大多数锂离子电池制造企业作为手机电池的阴极材料。但锰酸锂在高倍率电池中的研究和应用还较少，其原因之一是因为常用的高温固相法合成的锰酸锂产品粒径较大，在几个微米左右，锂离子在其颗粒内部嵌入脱嵌时迁移路径较长，导致其大倍率充，放电性能不佳。     

钴镧掺杂富锂型锰酸锂制备及其性能

应用共沉淀-高温固相法制备钴镧共掺杂富锂型Li1.1Co0.02La0.01Mn2O4材料.X射线衍射(XRD)和扫描电镜(SEM)测试表明,在700~850℃的焙烧温度范围内,合成材料为单相,但随着焙烧温度升高,材料结晶度上升,粒径增大,比表面减小.该材料具有较小的极化电阻,以其作正极(800℃焙烧)组成扣式电池具有最佳电化学性能,1 C倍率50周循环充放电容量保持率达98.5%.     

尖晶石型八面体结构锰酸锂的制备及其电化学性能

采用模板导向法和高温固相法制备尖晶石型八面体结构的LiMn₂O₄锂离子电池正极材料,研究了该材料的结构和电化学性能。 电化学性能研究表明,该电极材料具有良好的循环稳定性和倍率性能,在2.5~4.5 V电压范围,电流密度为100 mA/g时,首周充放电比容量分别为147和179 mA·h/g,循环50周后,其充放电比容量仍分别保持在180/181 mA·h/g。 优良的电化学性能可能归因于尖晶石LiMn₂O₄的形貌结构特征,该方法为制备锂离子电池正极材料提供了思路和依据。     

Simultaneous Carbon Coating and Lithiation of Oxides by Contact Reaction

Chemical lithiation and carbon coating of cathode materials can lead to strongly improved electrochemical properties, especially if the active materials have low electronic conductivity. This behavior is quite often the case for new high‐capacity materials. A novel synthesis method is presented in which the two processes are performed simultaneously by employing Li₂C₂ as both the carbon and the lithium source. In this contact reaction, the acetylide anion C₂^2? is oxidized to carbon and deposited directly on the surface of the active material, while lithium is reductively inserted into the oxidant. Two different synthesis routes are demonstrated: a tribochemical approach at room temperature and heat treatments between 150 and 600 °C. The applicability of these new carbon‐coating methods are demonstrated on various crystalline and amorphous Li_xV₂O₅ phases. The composites obtained were characterized by powder X‐ray diffraction, transmission electron microscopy, and Raman spectroscopy. In addition, electrochemical data confirm the chemical lithiation and show that lithiated Li_xV₂O₅ with specific phases can be prepared selectively.     

纳米硫化镉的合成及其电化学催化性能测试

采用CS2-SDS-正辛醇-水微乳体系制备了硫化镉纳米棒。利用XRD、SEM、TEM对产物进行表征，测试了其对多硫化物电极还原反应的催化性能，并与常规方法合成的大粒度CdS晶体进行对比．结果表明，纳米棒为六方型CdS晶体，直径约12nm．常规法合成的CdS为立方型晶体，平均粒度约为1μm．CdS纳米棒电极对硫化钠／多硫化钠电极反应的电催化活性明显高于大粒度CdS晶体电极．     

单斜ZnP2负极材料的锂化机理及性能

过渡金属磷化物电位低且比容量高, 是有发展前景的锂离子电池(LIBs)负极材料. 其中, ZnP₂属于双活性负极材料, Zn与P都能与Li⁺发生反应, 储Li⁺性能更具有竞争力. 但是, 对于ZnP₂的锂化机理及产物尚不明确. 采用第一性原理计算和电化学测试方法研究了ZnP₂的电子性质和电化学性能, 通过理论计算和实验测试相结合阐述了ZnP₂的锂化机制. 首先, 以密度泛函理论(DFT)计算揭示了ZnP₂的锂化机理、Li⁺扩散路径、势垒和理论比容量(1477 mAh/g). 其次, 通过直流电弧等离子体法及固相烧结法合成ZnP₂, 并测试其首圈放电曲线, 显示放电容量为1439 mAh/g, 与理论计算结果相近. 此外, 薄膜X射线衍射(XRD)检测最终产物成分为LiZn和Li₃P, 与DFT计算结果一致.     

Data‐Driven Materials Exploration for Li‐Ion Conductive Ceramics by Exhaustive and Informatics‐Aided Computations

Interest in all‐solid‐state Li‐ion batteries (LIBs) using non‐flammable Li‐conducting ceramics as solid electrolytes has increased, as safe and robust batteries are urgently desired as power sources for (hybrid) electric vehicles. However, the low Li‐ion conductivities of ceramics have hindered all‐solid‐state LIB commercialization; many researchers have attempted to develop fast Li‐ion conductors. We introduce two efficient high‐throughput computational approaches for materials exploration: (i) exhaustive search and (ii) informatics‐aided prediction. For demonstration, ～400 Li‐ and Zn‐containing oxide (Li?Zn?X?O) compounds of varied crystal structures are extracted from Materials Project datasets. We calculate the migration energies for Li‐ion conduction and the phase stabilities (decomposition energies) of these materials by simulation and apply Bayesian optimization to determine the material with the highest ionic conductivity. The results show much greater efficiency than a random search algorithm.     

Topochemical Path in High Lithiation of MoS2

Lithiation of MoS₂/RGO (reduced graphite oxide) electrodes repeatedly reached experimental capacities larger than 1000 mA · g^–1, corresponding to at least 6 lithium equivalents per gram of MoS₂. At our best knowledge, a convincing explanation is still missing in literature. In most cases, phase separation into Li₂S and elemental Mo was assumed to occur. However, this can only explain capacities up to 669 mA · g^–1, corresponding to an exchange of four Li. Formation of LiMo alloys could resolve the problem but the Li/Mo system does not contain any binary phases. If signs for Li₂S formation were found, indeed experimental capacities were below 700 mAh · g^–1. Here we present a topochemical mechanism, which sustains multiple charge/discharge cycles at 1000 mAh · g^–1, corresponding to an exchange of at least 6 Li per formula unit MoS₂. This topochemical reaction route prevents decomposition into binary phases and thus avoids segregation of the components of MoS₂. Throughout the whole lithiation/delithiation process, distinct layers of Mo are preserved but extended or shrunk by slight movements and reshuffling of sulfur and lithium atoms. On addition of 6 Li per formula unit to MoS₂, all central sulfur atoms are hosted in mutual Mo–S layers such that formal S^2– and Mo^2– anions appear coordinated by lithium cations. Indeed, similar structures are known in the field of Zintl phases. Our first‐principles crystal structure prediction study describes this topological path through conversion reactions during the lithiation/delithiation processes. All optimized phases along the topological path exhibit a distinct Mo layering giving rise to a series of dominant scattering into pseudo 001 reflections perpendicular to these Mo planes. The mechanism we present here explains why such high capacities can be reached reversibly for MoS₂/RGO nano composites     

芳卤化合物的邻位锂化反应和锂卤交换反应

介绍了芳卤化合物的邻位锂化反应和锂卤交换反应的反应机制、控制因素及应用实例,并且比较两种反应的异同点,从而使读者能够更好地掌握这两种非常重要的合成方法,并加以灵活运用。     

Lithiation of optically active oxazolinyloxiranes: configurational stability

The α-lithiation reaction of optically active oxazolinyloxiranes has been investigated. The trapping reaction with D₂O, MeI and acetone affording substituted oxazolinyloxiranes proved that the corresponding lithiated species are configurationally unstable. A stereoconvergency was observed in the case of lithiation-deuteration sequence of two oxazolinyloxiranes.     

纳米锡锌复合氧化物贮锂材料的合成和性质

用液相沉淀-热解法合成了一系列结构和组成不同的锂离子电池纳米锡锌复合氧化物贮锂材料, 通过XRD、TEM和电化学测试对材料进行了表征. 测试结果表明, 非晶态ZnSnO3负极材料的初始可逆贮锂容量为844 mA·h/g, ZnO·SnO2负极材料的初始可逆贮锂容量为845 mA·h/g, SnO2·Zn2SnO4复合物负极材料初始可逆贮锂容量为758 mA·h/g, 循环10周后, 三者的充电容量分别为695, 508和455 mA·h/g, 表明非晶态结构的锡锌复合氧化物具有较好的电化学性质, 随着样品中晶体的形成, 该类型负极材料的贮锂性能下降.     

Biological Effects of Black Phosphorus Nanomaterials on Mammalian Cells and Animals

The remarkable progress of applied black phosphorus nanomaterials (BPNMs) is attributed to BP's outstanding properties. Due to its potential for applications, environmental release and subsequent human exposure are virtually inevitable. Therefore, how BPNMs impact biological systems and human health needs to be considered. In this comprehensive Minireview, the most recent advancements in understanding the mechanisms and regulation factors of BPNMs’ endogenous toxicity to mammalian systems are presented. These achievements lay the groundwork for an understanding of its biological effects, aimed towards establishing regulatory principles to minimize the adverse health impacts.     

Synthesis and Electrochemical Studies of Carbon-modified LiNiPO4 as the Cathode Material of Li-ion Batteries

Well-crystallized olivine LiNiPO₄ and carbon-modified LiNiPO₄(LiNiPO₄/C) were synthesized by a combined solvothermal and solid state reaction method using water-benzyl alcohol two-phase solvent. The structure and morphology of the prepared LiNiPO₄ were systematically characterized by powder X-ray diffraction, scanning electron microscopy and transmission electron microscopy. The LiNiPO₄ particles are up to around 2 μm in diameter while the particle size of LiNiPO₄/C is about 100—200 nm. At a current rate of 0.05 C(1.00 C=167 mA/g, corresponding to one Li⁺ intercalation/deintercalation), LiNiPO₄ and LiNiPO₄/C presented a high initial specific capacity of 157 and 220 mA·h/g, respectively. The capacity of LiNiPO₄/C is 72% larger than that of LiNiPO₄ at 0.1 C. The LiNiPO₄/C cathode exhibits a superior electrochemical performance in comparison with LiNiPO₄, revealing that carbon modifying is an effective method to improve the ionic diffusion and electronic conductivity of cathode material LiNiPO₄. Furthermore, lithium ion diffusion coefficients of LiNiPO₄ and LiNiPO₄/C are 1.80×10^-15 and 1.91×10^-14 cm²/s, respectively, calculated via the data from electrochemical impedance spectra.