PEO基聚合物电解质及其锂硫电池性能研究

锂硫电池由于具有高的理论比能量引起了广泛关注,然而传统液态锂硫电池由于多硫化物的“穿梭效应”以及安全问题而限制了其应用,全固态锂硫电池可显著提高电池安全性能并有望解决多硫化物的穿梭问题. 本文采用传统的溶液浇铸法制备了具有不同的[EO]/[Li⁺]的PEO-LiTFSI聚合物电解质,并将其应用于锂硫电池. 研究发现,虽然[EO]/[Li⁺] = 8的聚合物电解质具有更高的离子电导率,但是[EO]/[Li⁺] = 20的电解质与金属锂负极间的界面阻抗更低,界面稳定性更好. Li|PEO-LiTFSI([EO]/[Li⁺]=20)|Li对称电池在60 °C,电流密度为0.1 mA·cm^-2时可稳定循环超过300 h,而Li|PEO-LiTFSI ([EO]/[Li⁺]=8)|Li对称电池循环75 h就出现了短路现象. 基于PEO-LiTFSI([EO]/[Li⁺]=20)电解质的锂硫电池首圈放电比容量为934 mAh·g^-1,循环16圈后放电比容量为917 mAh·g^-1以上. 而基于PEO-LiTFSI ([EO]/[Li⁺]=8)电解质的锂硫电池,由于与锂负极较低的界面稳定性不能够正常循环,首圈就出现了严重过充现象.     

尖晶石型高熵氧化物的制备和电化学性能

采用溶液燃烧法制备了化学组成均一的尖晶石型（Cr_0.2Fe_0.2Mn_0.2Ni_0.2M_0.2）₃O₄（M=Co,Zn,Mg）高熵氧化物（HEOs）纳米晶粉体,并将3种高熵氧化物用作锂离子电池负极材料,研究了活性过渡金属Co和Zn阳离子与非活性Mg阳离子对电化学性能的影响.结果表明,由于具有高构型熵稳定的晶体结构,3种高熵氧化物均表现出优异的循环稳定性,其中含有非活性Mg离子的高熵氧化物（Cr_0.2Fe_0.2Mn_0.2Ni_0.2Mg_0.2）₃O₄不仅具有更高的初始比容量（1300 mA·h/g）和倍率性能（在3 A/g电流密度下比容量约为450 mA·h/g）,且在循环500次后Li⁺的扩散系数为其它2种高熵氧化物的3倍以上.（Cr_0.2Fe_0.2Mn_0.2Ni_0.2Mg_0.2）₃O₄电化学性能提高的原因是非活性Mg离子不仅避免了锂化过程中活性物质的团聚,还提高了锂离子的扩散系数.     

一种有助于稳定锂金属循环的富氟化位点框架结构

锂金属是下一代高能量密度二次电池的理想负极材料,然而它的应用仍然受制于较差的循环稳定性。近期,二维氟化界面被广泛用于改善锂金属负极的成核机制、沉积形貌和循环稳定性。本工作通过将体积缩小化的氟化石墨颗粒与锂离子传导网络结合,获得了一种富氟化位点的三维框架结构。实验结果证明此类三维氟化结构可显著提升锂金属负极在不同电流密度和容量下的循环稳定性,且优于二维氟化界面结构。通过本工作的研究,证明了相较于单纯的二维氟化界面,三维锂离子传导网络和富氟化位点的合理结合可以成为一种改进的界面结构用于锂金属负极保护,为高能量密度锂金属电池的负极保护提供了新的设计思路。     

三维介孔钴酸锌立方体的制备及其优异的储锂性能

采用简易、温和、实际耐用的水热方法制备了新型三维介孔立方体结构的钴酸锌纳米材料。每个钴酸锌立方体的边长大约在3-4μm之间,并由大量的纳米粒子和密集的孔隙所构成。通过氮吸附/脱附手段测试发现所制备的钴酸锌纳米材料具有较大的比表面积(41.4 m2?g~(-1))和介孔(6.32 nm)特性。使用钴酸锌纳米材料作为锂离子电池负极,金属锂作为正极组装锂电池并测试了材料的储锂性能。研究发现该电极材料在较高的电流密度下循环100周后,仍能呈现较高的可逆容量和超强的循环稳定性。这种优异的储锂性能主要归因于钴酸锌纳米材料的新型结构,这种介孔立方体结构能够加速锂离子的扩散,增加电极与电解液的接触面积并缓解锂离子嵌入/嵌出期间产生的体积膨胀。     

添加Li+对MgO催化性能的影响

本文以IR、TPD、丁烯异构化及直接脱氢反应为手段,对不同Li⁺添加量的MgO催化剂进行了研究。结果表明,表面低配位氧集团是催化剂的主要活性物种,起碱中心作用;表面金属离子起L酸中心作用。酸、碱中心的数目、强度随Li⁺添加量不同而呈规律性变化。这种变化影响了酸、碱中心的协同作用,从而影响其催化活性。     

Preparation,Structure and Magnetic Properties of Lithium Substituted NiO by Molten Salt Method

A typical Li⁺ substituted NiO compound, Li_0.29Ni_0.71O, was synthesized by molten nitrate method. The effects of Li⁺ substitution on the structure and magnetic properties of NiO were investigated. X-Ray diffraction(XRD), scanning electron microscope(SEM) and high-resolution transmission electron microscope(HRTEM) analyses confirm the cubic structure of Li_0.29Ni_0.71O, with a primary particle size of 150 nm. Analysis of the Ni X-ray photoelectron spectroscopy(XPS) shows the transformation from Ni²⁺ to Ni³⁺ induced by Li⁺ substitution. Two magnetic transitions were observed at 225 and 55 K which were assigned to the ferrimagnetic ordering and spin glass transition, respectively. The different magnetic behavior with respect to that of NiO was attributed to the break of superexchange interaction Ni²⁺-O-Ni²⁺ and the formation of different spin clusters after non-magnetic Li⁺ doping.     

碳空心球/硫复合材料制备和电化学性能研究

采用PMMA为模板制备碳空心球材料,并以碳空心球材料为导电骨架与硫材料复合制得碳空心球/硫复合材料. SEM和TEM照片显示,硫材料能均匀地填充在碳空心球的孔道和腔体内部. 采用恒电流充放电测试碳空心球/硫复合电极的电化学性能. 结果表明,在100 mA·g^-1、500 mA·g^-1、1 A·g^-1、2 A·g^-1 和5 A·g^-1电流密度下,碳空心球/硫复合电极可逆放电容量分别为1145 mAh·g^-1、824 mAh·g^-1、702 mAh·g^-1、586 mAh·g^-1和395 mAh·g^-1,呈现出较优异的倍率循环寿命.     

NaTiSi2O6/C复合材料用于锂离子电池负极材料

The development of human society and the continuously emerging environmental problems call for cleaner energy resources. Lithium-ion batteries, since their commercialization in the early 1990s, have been an important power source of mobile phones, laptops as well as other portable electronic devices. Their advantages include environment-friendliness, light weight, and no memory effect compared with lead-acid or nickel-cadmium batteries. Electrode materials play an important role in the performance of lithium-ion batteries. The traditional commercial anode material, graphite, has a theoretical specific capacity of 372 mAh·g^-1 and working potential close to 0 V (vs Li⁺/Li), making it prone to the formation of lithium dendrite, which may cause short circuit especially when large current is applied. Another commercial anode material Li₄Ti₅O₁₂, which also undergoes an intercalation reaction during lithiation process, has a theoretical specific capacity of 175 mAh·g^-1 along with three lithium-ion intercalations per formula unit. This is relatively small, and it has a relatively high working potential of 1.55 V (vs Li⁺/Li), which reduces its output voltage and specific energy when assembled in full battery. To overcome the shortcomings mentioned above, it is essential to search for new anode materials that are low-cost, environment-friendly, and easy to synthesize. Silicate materials have gained widespread attention owing to their low cost and facile synthesis. Herein, we report for the first time a novel titanosilicate, NaTiSi₂O₆, synthesized by sol-gel and solid sintering. It is isostructural to pyroxene jadeite NaAlSi₂O₆, belonging to monoclinic crystal system with a space group of C2/c. By in situ pyrolysis and carbonization of glucose, nanosized NaTiSi₂O₆ mixed with carbon was successfully obtained with a specific surface area of 132 m²·g^-1, calculated according to the Brunauer–Emmett–Teller formula. The specific charge/discharge capacity in the first cycle at current density of 0.1 A·g^-1 is 266.6 mAh·g^-1 and 542.9 mAh·g^-1, respectively, with an initial coulombic efficiency of 49.1%. After 100 cycles, it retains a specific charge capacity of 224.1 mAh·g^-1, corresponding to a capacity retention rate of 84.1%. The average working potential of NaTiSi₂O₆ is 1.2–1.3 V (vs Li⁺/Li), slightly lower than that of Li₄Ti₅O₁₂. The reaction mechanism while charging and discharging was determined by in situ X-ray diffraction test as well as selected area electron diffraction. The results showed that NaTiSi₂O₆ undergoes an intercalation reaction during lithiation process, with two lithium-ion intercalations per formula unit. This makes NaTiSi₂O₆ a new member of the silicate anode material family, and may provide insights into the development of new silicate electrode materials in the future.     

纳米MgO掺杂改善LiNi1/3Co1/3Mn1/3O2正极材料

将氢氧化物共沉淀法制备的(Ni_1/3Co_1/3Mn_1/3)（OH）₂在500℃热处理5 h得到具有尖晶石结构、纳米尺寸的氧化物M₃O₄(M=Ni_1/3Co_1/3Mn_1/3).将其与LiOH及不同量的纳米MgO混合均匀,并在850℃热处理24 h制备了Li(Ni_1/3Co_1/3Mn_1/3)_1/xMg_xO₂（x=0,0.01,0.02,0.03,0.04,0.05）正极村料.随着Mg掺杂量的增大,正极材料的晶胞参数增大;少量的Mg掺杂增大了锂离子的扩散系数,而过度掺杂却使锂离子扩散系数有所降低,其中Li(Ni_1/3Co_1/3Mn_1/3)_0.98Mg_0.02O₂的锂离子扩散系数最大,其脱出和嵌入扩散系数分别为D_Li-dein=29.20×10^-11cm²·S^-1和D_Li-in=4.760×10^-11cm²·s^-1;其以3C倍率充放电的平均放电比容量为139.3 mAh·g^-1,比未掺杂的原粉约高9.5 mAh·g^-1;另外其循环性能也得到了大幅度改善.     

二硒化钼纳米球储锂和储镁的性能和机理研究

二硒化钼是一种二维过渡金属硫族化合物材料,凭借其具有较快的离子迁移率、较弱的范德华力的层状结构,在锂离子电池的应用研究中吸引了广泛的关注。同时在镁离子电池应用中表现出潜在的研究前景。然而,有关二硒化钼在锂离子电池中的报道多集中在如何提高储锂性能上,对其离子存储机理缺乏深入研究。此外,在储镁性能和机理上均没有报道。本项工作通过湿化学和高温煅烧两步法合成了二硒化钼纳米球,当二硒化钼纳米球用作锂离子电池负极材料时,在5 A·g^-1的电流密度下展示了高于100 mAh·g^-1的优异高倍率容量;同时,作为镁离子电池正极材料时,在20 mA·g^-1的电流密度下表现出了120 mAh·g^-1的高储镁可逆容量。另外,通过电化学、原位和非原位X射线衍射表征技术,分别揭示了二硒化钼纳米球低平台发生的转化式和高平台发生的类锂硒电池反应并存的储锂机理,以及赝电容式为主,嵌入式为辅的储镁机理。本项工作不仅为二维过渡金属硫族化合物材料的储锂机理提供了深刻的理解,同时也为新型层状储能材料的设计开发提供了方向。     

亲锂的三维二硫化锡@碳纤维布用于稳定的锂金属负极

金属锂由于其高的比容量,低的电极电势和轻质等特点被认为是下一代高能量密度锂金属二次电池负极材料的最佳选择。然而,充放电循环中不均匀的锂沉积会导致严重的体积变化和大量的锂枝晶形成,从而影响了电池的库伦效率甚至会带来严重的安全隐患。为此,本文设计了一种亲锂的三维二硫化锡@碳纤维布复合基底材料,并作为集流体将其应用于金属锂电池上。一者,高比表面积的三维碳纤维骨架可以适应充放电过程中的体积变化并且有效地降低局部电流密度,从而确保锂的均匀沉积。二者,表面修饰的SnS2层在锂沉积过程中可以形成Li-Sn合金界面层,诱导锂的沉积并降低过电势。最终,实验结果表明:使用所制备的复合集流体与金属锂搭配组成的半电池可以在5 mA·cm^-2的高电流密度下以>98%的库伦效率稳定循环100周以上。此外,在承载10 mAh·cm^-2的金属锂后,复合的锂负极无论是在对称电池还是与磷酸铁锂组装成的实际电池中,均可以在高的电流密度下实现稳定的循环。我们相信这一复合的集流体构建策略对于设计安全稳定的锂金属电池或器件具有重要意义。     

多孔碳纳米片的合成及在钠离子电池中的应用

本文以氯化钠为硬模板、硝酸镍为金属源、葡萄糖为碳源,在氮气气氛中于750 ^oC通过一步热解法合成嵌镍碳纳米片,然后经酸处理得到多孔碳纳米片. 通过扫描电镜（SEM）、透射电镜（TEM）、拉曼光谱（Raman）和比表面积测定（BET）表征多孔碳纳米片的形貌和结构. 结果显示：多孔碳纳米片孔分布均匀,孔径大小均一;经过酸处理后,碳材料的石墨化程度降低;具有较大的比表面积（约340 m²•g^-1）. 电化学测试表明,电极在100mA•g^-1电流密度下,经过200周循环放电后比容量可维持在309.4 mAh•g^-1,甚至在1000 mA•g^-1 的大电流下其放电比容量仍然可达到173mAh•g^-1,表现出良好的循环稳定性和倍率性能,其在钠离子电池负极材料方面具有潜在的应用前景.     

镶嵌于NH2-MIL-125 (Ti)衍生氮掺多孔碳中的花状超细纳米TiO2作为高活性和稳定性的锂离子电池负极材料

由于具有高安全性和优异的循环稳定性,二氧化钛(TiO₂)作为负极材料被广泛地应用于锂离子电池领域。但是较差的导电性和离子传输速率限制了TiO₂的进一步应用和发展。鉴于此,我们以花状NH₂-MIL-125 (Ti)为前驱体和硬模板,成功合成出了具有花状结构的超细纳米TiO₂/多孔氮掺杂碳片(N-doped porous carbon)复合物(记为FL-TiO₂/NPC)。过程中所制备的纳米TiO₂-金属有机构架(Ti-MOF)展现出由二维褶皱多孔纳米片堆积、组装而成的花状结构。一方面,二维褶皱纳米片包含TiO₂纳米颗粒可以增大活性物质与电解液的接触面积;另一方面,氮掺杂多孔碳基体可以提高整体复合物的导电性和结构完整性。将所获得的FL-TiO₂/NPC作为负极组装成的锂半电池, 在0.5 A·g^-1、300圈后仍有384.2 mAh·g^-1以及在1 A·g^-1、500圈仍有279.1 mAh·g^-1的比容量。进一步性能测试表明,在2 A·g^-1、2000圈长循环测试后,其仍能保持256.5 mAh·g^-1的比容量和接近100%的库伦效率。该优异的电化学活性和稳定性主要起源于材料独特的花状结构。我们的合成策略为今后制备高储锂性能的金属氧化物/多孔氮掺杂碳负极提供了一种新的思路。     

Molecular orbital theory of the hydrogen bond : XXXII. The effect of H and Li association on the A---T and G---C pairs

Ab initio molecular orbital calculations have been performed to determine the structures and stabilization energies of the A---T and G---C base pairs and their complexes with H⁺ and Li⁺, H⁺ and Li⁺ association stabilizes the A---T pair except for Li⁺ association at O₄ in thymine. Protonation of thymine stabilizes the A---T pair to a greater extent than protonation of adenine. The association of H⁺ and Li⁺ with guanine stabilizes the G---C pair, but protonation of cytosine destabilizes G---C. Changes in the structures of the hydrogen bonds in the A---T and G---C pairs reflect changes in hydrogen bond strengths.     

Spectroscopic, mass spectrometry, and semiempirical investigations of a new 2-(2-methoxyethoxy)ethyl ester of Monensin A and its complexes with monovalent cations

A new 2-(2-methoxyethoxy)ethyl ester of Monensin A (MON7) has been synthesized and its capability of complex formation with Li⁺, Na⁺, and K⁺ cations has been studied by ESI MS, ¹H and ¹³C NMR, FT-IR, and PM5 semiempirical methods. ESI mass spectrometry indicates that MON7 forms complexes with Li⁺, Na⁺, and K⁺ of exclusively 1:1 stoichiometry which are stable up to cv = 70 V. The formation of complexes between MON7 and Na⁺ cations is strongly favored. Starting from about cv = 90 V fragmentation of the respective complexes is observed, primarily characterized by several dehydration steps. The structures of the MON7 complexes with Li⁺, Na⁺, and K⁺ cations are stabilized by intramolecular hydrogen bonds in which the OH groups are always involved. The structures are visualized and discussed in detail. It has been proved that the formation of a pseudo crown ring structure formed by MON7 is preferred in complexes with Na⁺ cations.     

Observation Of Mode Selective Vibrational Excitation Of SF6 By Collisions With 4–10 eV Li And H Ions

Structured time of flight spectra of both Li⁺ and H⁺ ions scattered from ground state SF₆, have been measured at angles (5.0° v_c.m. 16.6°) less than the rainbow angle at E_c.m., = 4.3 eV and 9.7 eV, respectively. The structure can be arttributed to vibrational excitation of the v₃ mode by H⁺ and excitation of the v₄ mode by Li⁺. The relative transition probabilities obey a Poisson distribution and can be explained by a simple forced oscillator model.     

Fe2O3-MWNTs Composite with Reinforced Concrete Structure as High-performance Anode Material for Lithium-ion Batteries

AFe₂O₃-MWNTs(multi-walled carbon nanotubes) composite with a reinforced concrete structure was fabricated employing a two-step method, which involves a sol-gel process followed by high-temperature in situ sintering. This Fe₂O₃-MWNTs composite, intended to be used as an anode material for lithium-ion batteries, maintained a reversible capacity as high as 896.3 mA·h/g after 100 cycles at a current density of 100 mA/g and the initial coulombic efficiency reached 75.5%. The rate capabilities of the Fe₂O₃-MWNTs composite, evaluated using the ratios of capacity at 100, 200, 500, 1000, 2000 and 100 mA/g after every 10 cycles, were determined to be 904.7, 852.1, 759.0, 653.8, 566.8 and 866.3 mA·h/g, respectively. Such a superior electrochemical performance of the Fe₂O₃-MWNTs composite is mainly attributed to the reinforced concrete construction, in which the MWNTs function as the skeleton and conductive network. Such a structure contributes to shortening the transport pathways for both Li⁺ and electrons, enhancing conductivity and accommodating volume expansion during prolonged cycling. This Fe₂O₃-MWNTs composite with the designed structure is a promising anode material for high-performance lithium-ion batteries.     

Structure and stability of endohedral X@Si20H20 complexes (X = Li, Na, K, Be, Mg, Ca)

The structure and stability of endohedral X@Si₂₀H₂₀ complexes (X = Li^0/+, Na^0/+, K^0/+, Be^0/2+, Mg^0/2+, Ca^0/2+) have been studied at the B3LYP/6-31G* level of density functional theory. It is found that complexes with X = Na^0/+, K^0/+, Mg and Ca^0/2+ are energy minimum structures with X at the cage center in I_h symmetry, while those with X = Li^0/+, Be^0/2+, Mg²⁺ have off-centered structures with X towards one pentagon face in C_5v symmetry. Large electron or charge transfer between the Si₂₀H₂₀ cage and the encapsulated X has been observed.     

Vibrational frequencies and infrared intensities of acetonitrile coordinated with metal cations: an ab initio study

Vibrational frequencies and infrared intensities have been calculated at the 6-31G and 6-31G^** levels for acetonitrile and for the complexes of acetonitrile with Li⁺ and Na⁺ cations. The changes in the infrared characteristics from an isolated acetonitrile to acetonitrile coordinated with metal cations (Li⁺ and Na⁺) have been evaluated. The ab initio calculations predict an essential increase of the intensities of the stretching CN, C-C and deformation CH₃, CCN vibrations in the complexes of acetonitrile with Li⁺ and Na⁺ cations.     

一种新型物理交联型凝胶聚合物电解质的制备与表征

以甲氧基聚乙二醇甲基丙烯酸酯(MPEGM)和十六烷基聚乙二醇甲基丙烯酸酯(HPEGM)为单体, 三乙二醇二甲醚(TEGDME)为增塑剂, 与锂盐(高氯酸锂, LiClO₄)和光引发剂(安息香二甲醚, DMPA)复合制成光敏体系, 经紫外(UV)固化得到物理交联型凝胶聚合物电解质(GPE)薄膜. 用红外(IR)光谱、差热分析(DSC)、拉伸测试和交流阻抗(AC) 等方法对聚合物基体和电解质的性能进行了研究.结果表明: 当共聚物P(MPEGM-co-HPEGM)中HPEGM含量为50%(w)时, 十六烷基链段(C₁₆)在聚氧化乙烯(PEO)链段静电斥力的作用下发生聚集, 自组装形成了物理交联, 提高了共聚物的空间稳定性; 温度和电解质中各组分的含量对电导率均有较大的影响, 综合性能较好的电解质在30℃时电导率可达0.87×10^-3 S·cm^-1; 采用循环伏安法测得该电解质的电化学窗口为0~4.5 V (vs. Li/Li⁺), 可以满足锂离子电池的应用要求; 组装成的LiFePO₄/GPE/Li电池, 在30℃下以0.1 C和0.2 C倍率进行充放电测试, 首次放电容量分别为154.7和148.0 mAh·g^-1.