溶剂热制备锂电池负极材料CNT-ZnFe2O4及其电化学性能

为了改善锂离子电池负极材料ZnFe₂O₄导电性差和循环寿命低的缺点,利用溶剂热反应方法制备了ZnFe₂O₄,并通过复合碳纳米管对ZnFe₂O₄进行改性。充放电测试结果表明：经过50次充放电后,碳纳米管复合改性后的ZnFe₂O₄容量保持在860 mA·h·g^-1,具有较好的循环稳定性。碳纳米管具有良好的导电性与导热性,改善了ZnFe₂O₄导电性差的缺点。     

电池正极材料中Li+运动特性的7Li NMR研究

利用变温⁷LiNMR实验对Li-电池正极材料LiMn₂O₄和LiCoO₂中Li⁺的运动特性进行了研究,结果表明,随实验温度的提高,LiMn₂O₄的⁷LiNMR谱线窄化,表明其中Li⁺迁移能力增加,而LiCoO₂的谱线无变化.此外随温度提高,LiMn₂O₄的⁷Li的T₁变短,而LiCoO₂的T₁变长,产生这种不同变化趋势的原因在于LiMn₂O₄和LiCoO₂晶相结构的差异造成其中Li⁺迁移能力的差别,它们各自的相关时间τ_c使⁷Li核的T₁分别位于T₁-τ_c曲线极小点两侧.     

Improvement of electrochemical properties of the spinel LiMn2O4 using a Cr dopant effect

A series of LiCr_xMn_2−xO₄ spinels were synthesised by the Pechini method which enables dopant Cr ions to distribute at Mn sites homogeneously. Neutron diffraction and EDS analysis confirmed that Cr ions do occupy 16d sites (octahedral intestial) evenly in the spinel structure. The Cr dopant effect improves the cyclability of spinel LiMn₂O₄ electrodes and decreases the self-discharge rate substantially. Cyclic voltammetry and AC impedance spectroscopy were employed to characterise the reactions of lithium insertion into and extraction from LiCr_xMn_2−xO₄ electrodes. It was found that a thicker surface layer was formed on the surface of the pure LiMn₂O₄ electrode than on the LiMn₂O₄ electrode.     

Lithium extraction/insertion from LiMn2O4 — effect of crystallinity

Effect of host crystallinity on lithium extraction/insertion of LiMn₂O₄ was studied. LiMn₂O₄ powders with different crystallinity were prepared via lithium-manganese-tartrates by heat treatment at various temperatures above 300 °C. First charge-discharge capacity around 4 V depended on lattice parameter a₀ and lattice strain . On the other hand, the first discharge capacity around 3 V was found to be independent of these parameters.     

Electron density distribution of LiMn_2O_4 cathode investigated by synchrotron powder x-ray diffraction

Electron density plays an important role in determining the properties of functional materials. Revealing the electron density distribution experimentally in real space can help to tune the properties of materials. Spinel Li Mn2 O4 is one of the most promising cathode candidates because of its high voltage, low cost, and non-toxicity, but suffers severe capacity fading during electrochemical cycling due to the Mn dissolution. Real-space measurement of electron distribution of Li Mn2 O4 experimentally can provide direct evaluation on the strength of Mn–O bond and give an explanation of the structure stability.Here, through high energy synchrotron powder x-ray diffraction(SPXRD), accurate electron density distribution in spinel Li Mn2 O4 has been investigated based on the multipole model. The electron accumulation between Mn and O atoms in deformation density map indicates the shared interaction of Mn–O bond. The quantitative topological analysis at bond critical points shows that the Mn–O bond is relatively weak covalent interaction due to the oxygen loss. These findings suggest that oxygen stoichiometry is the key factor for preventing the Mn dissolution and capacity fading.     

A low cost composite quasi-solid electrolyte of LATP,TEGDME,and LiTFSI for rechargeable lithium batteries

The composite quasi solid state electrolytes(CQSE) is firstly synthesized with quasi solid state electrolytes(QSE) and lithium-ion-conducting material Li_(1.4)Al_(0.4)Ti_(1.6)(PO_4)_3(LATP), and the QSE consists of [LiG4][TFSI] with fumed silica nanoparticles. Compared with LATP, CQSE greatly improves the interface conductance of solid electrolytes. In addition,it has lower liquid volume relative to QSE. Although the liquid volume fraction of CQSE is droped to 60%, its conductivity can also reach 1.39 × 10~(-4)S/cm at 20℃. Linear sweep voltammetry(LSV) is conducted on each composite electrolyte.The results show the possibility that CQSE has superior electrochemical stability up to 5.0 V versus Li/Li+. TG curves also show that composite electrolytes have higher thermal stability. In addition, the performance of Li/QSE/Li Mn_2O_4 and Li/CQSE/Li Mn_2O_4 batteries is evaluated and shows good electrochemical characteristics at 60℃.     

Enhancement of electrochemical performance in lithium-ion battery via tantalum oxide coated nickel-rich cathode materials

Nickel-rich cathode materials are increasingly being applied in commercial lithium-ion batteries to realize higher specific capacity as well as improved energy density. However, low structural stability and rapid capacity decay at high voltage and temperature hinder their rapid large-scale application. Herein, a wet chemical method followed by a post-annealing process is utilized to realize the surface coating of tantalum oxide on LiNi_0.88Mn_0.03Co_0.09O₂, and the electrochemical performance is improved. The modified LiNi_0.88Mn_0.03Co_0.09O₂ displays an initial discharge capacity of ～ 233 mAh/g at 0.1 C and 174 mAh/g at 1 C after 150 cycles in the voltage range of 3.0 V-4.4 V at 45℃, and it also exhibits an enhanced rate capability with 118 mAh/g at 5 C. The excellent performance is due to the introduction of tantalum oxide as a stable and functional layer to protect the surface of LiNi_0.88Mn_0.03Co_0.09O₂, and the surface side reactions and cation mixing are suppressed at the same time without hampering the charge transfer kinetics.     

An electrochemical investigation of Li intercalation in the sol-gel LiMn2O4 spinel oxide

An alternative approach for obtaining the LiMn₂O₄ spinel phase is provided by the use of the sol-gel method in aqueous solution. The main electrochemical properties of the sol-gel LiMn₂O₄ phase are reported. In addition to chronopotentiometric and voltammetric experiments, the kinetics of the electrochemical insertion–extraction of lithium in Li_xMn₂O₄ (0.25<x<1) has been investigated using ac impedance spectroscopy. The strong variation of the chemical diffusion coefficient D_Li vs x, in the range 10⁻⁸–10⁻¹¹ cm² s⁻¹ (D_Li is found to be maximum for x=0.55) is critically discussed.     

Preparation of LiMn2O4 thin films by a sol–gel method

LiMn₂O₄ thin films were prepared by a sol–gel method using spin-coating and annealing processes. Anhydrous Mn(CH₃COCHCOCH₃)₃ (manganese acetylacetonate) and LiCH₃COCHCO–CH₃ (lithium acetylacetonate) were chosen as source materials. The film electrochemical properties depended on the drying temperature even when subjected to the same annealing conditions. The discharge capacity of annealed film increased as the drying temperature was increased. However, the rate of capacity fading during cycling increased as the drying temperature was increased.     

Probing the improved stability for high nickel cathode via dual-element modification in lithium-ion

One of the major hurdles of nickel-rich cathode materials for lithium-ion batteries is the low cycling stability, especially at high temperature and high voltage, originating from severe structural degradation, which makes this class of cathode less practical. Herein, we compared the effect of single and dual ions on electrochemical performance of high nickel (LiNi_0.88Mn_0.03Co_0.09O₂, NMC) cathode material in different temperatures and voltage ranges. The addition of a few amounts of tantalum (0.2 wt%) and boron (0.05 wt%) lead to improved electrochemical performance. The co-modified LiNi_0.88Mn_0.03Co_0.09O₂ displays an initial discharge capacity of 234.9 mAh/g at 0.1 C and retained 208 mAh/g at 1 C after 100 cycles at 45 ℃, which corresponds to a capacity retention of 88.5%, compared to the initial discharge capacity of 234.1 mAh/g and retained capacity of 200.5 mAh/g (85.6%). The enhanced capacity retention is attributed to the synergetic effect of foreign elements by acting as a surface structural stabilizer without sacrificing specific capacity.     

Surface chemistry of alkyl and perfluoro ethers: a FTIR and ab initio study of adsorption and decomposition of CF3OCF3 on an Al2O3 surface

The adsorption and thermal decomposition of perfluorodimethyl ether, (CF₃)₂O, on a high-surface-area Al₂O₃ surface was investigated by FTIR under both vacuum and pressure conditions. IR spectra in the 4000-1050 cm⁻¹ range were collected and the spectral assignments were assisted by quantum chemical ab initio calculations. The spectral evidence indicated that (CF₃)₂O decomposed to form adsorbed fluoroformate, FCOO (ads). Increases of temperature (up to 525 K) caused the FCOO (ads) to convert to hydrogen formate, HCOO (ads). Surface hydroxyl groups participated in the decomposition of (CF₃)₂O and the conversion of FCOO (ads) to HCOO (ads). A decomposition mechanism is proposed.     

Inductively coupled plasma—atomic emission spectrometry (ICP-AES): an analytical technique for the chemical characterization of perovskite ceramic semiconductors

The possibilities of inductively coupled plasma-atomic emission spectrometry (ICP-AES) for the chemical characterization (dopants, impurities, and macroconstituents) of perovskite ceramic semiconductors (PTC thermistors, varistors, manganites, cobaltites) are shown. The dissolution of the samples is achieved by five methods: (a) decomposition with HCl in a Teflon-lined pressure vessel, (b) decomposition with HF + H₂SO₄ in a Teflon-lined pressure vessel, (c) decomposition with (NH₄)₂SO₄ + H₂SO₄ in a platinum dish, (d) fusion with Na₂CO₃ + Na₂B₄O₇ in a platinum crucible, (e) fusion with Li₂B₄O₇ in a graphite crucible. The spectral interferences and the inter-element effects are studied and corrected. The detection limits are comprised, approximately, between 0.00001% and 0.1%. High sensitivity and good precision are attained.     

In situ formed FeS2@CoS cathode for long cycling life lithium-ion battery

Pyrite FeS₂ exhibits an ultrahigh energy density (1671 W·h·kg^-1, for the reaction of FeS₂+4Li=Fe+2Li₂S) in secondary lithium-ion batteries, but its poor cycling stability, huge volume expansion, the shuttle effect of polysulfides, and slow kinetic properties limit its practical application. In this work, we synthesize a composite structure material CoS on FeS₂ surface (FeS_x@CoS, 1 < x ≤ 2) by using a cobalt-containing MOF to improve its cycle stability. It is found that CoS inhibits the side reactions and adsorbs polysulfides. As a result, the modified FeS₂ shows a higher discharge capacity of 577 mA·h·g^-1 (919 W·h·kg^-1) after 60 cycles than 484 mA·h·g^-1 (778 W·h·kg^-1) of bare pyrite FeS₂. This efficient strategy provides a valuable step toward the realization of high cycling stability FeS₂ cathode materials for secondary lithium-ion batteries and enriches the basic understanding of the influence of FeS₂ interfacial stability on its electrochemical performances.     

无锂助熔剂B_2O_3对Li_(1.3)Al_(0.3)Ti_(1.7)(PO_4)_3固体电解质离子电导率的影响

采用固相法制备锂离子电池用固体电解质磷酸钛锂铝Li_(1.3)Al_(0.3)Ti_(1.7)(PO_4)_3(LATP),研究了不同烧结温度以及助熔剂对LATP固体电解质离子电导率的影响.采用X射线衍射、能谱分析、扫描电镜和交流阻抗等方法,研究样品的结构特征、元素含量、形貌特征以及离子导电性能.结果表明,在900?C烧结可以获得结构致密、离子电导率较高的纯相LATP陶瓷固体电解质.与添加助熔剂Li BO2的样品进行对比实验发现,采用B_2O_3代替LiBO_2作为助熔剂也可以提高烧结样品的离子电导率,并且电解质的离子电导率随助熔剂添加量的增大,先增大后减小,其中添加质量百分比为2%的B_2O_3的样品具有最高的室温离子电导率,为1.61×10~(-3)S/cm.     

Theoretical study of novel B–C–O compounds with non-diamond isoelectronic

Two novel non-isoelectronic with diamond(non-IED)B–C–O phases(tI16-B₈C₆O₂and mP16-B₈C₅O₃)have been unmasked.The research of the phonon scattering spectra and the independent elastic constants under ambient pressure(AP)and high pressure(HP)proves the stability of these non-IED B–C–O phases.Respective to the common compounds,the research of the formation enthalpies and the relationship with pressure of all non-IED B–C–O phases suggests that HP technology performed in the diamond anvil cell(DAC)or large volume press(LVP)is an important technology for synthesis.Both tI16-B₈C₆O₂and tI12-B₆C₄O₂possess electrical conductivity.mP16-B₈C₅O₃is a small bandgap semiconductor with a 0.530 eV gap.For aP13-B₆C₂O₅,mC20-B₂CO₂and tI18-B₄CO₄are all large gap semiconductors with gaps of 5.643 eV,6.113 eV,and 7.105 eV,respectively.The study on the relationship between band gap values and pressure of these six non-IED B–C–O phases states that tI16-B₈C₆O₂and tI12-B₆C₄O₂maintain electrical conductivity,mC20-B₂CO₂and tI18-B₄CO₄have good bandgap stability and are less affected by pressure.The stress-strain simulation reveals that the max strain and stress of 0.4 GPa and 141.9 GPa respectively,can be sustained by tI16-B₈C₆O₂.Studies on their mechanical properties shows that they all possess elasticity moduli and hard character.And pressure has an obvious effect on their mechanical properties,therein toughness of tI12-B₆C₄O₂,aP13-B₆C₂O₅,mC20-B₂CO₂and tI18-B4CO4 all increases,and hardness of mP16-B₈C₅O₃continue to strengthen during the compression.With abundant hardness characteristics and tunable band gaps,extensive attention will be focused on the scientific research of non-IED B–C–O compounds.     

n(Zn)：n(Ga)比值对合成ZnGa2O4结构及光致发光性能的影响

以ZnO和HGaO₂为原料,用不同配比合成出系列ZnGa₂O₄,并对其晶体结构和发光性能进行了研究。用荧光分光光度计检测了ZnGa₂O₄的激发和发射光谱,用X射线衍射仪检测了ZnGa₂O₄的衍射图谱,用热重差热仪绘制了TGA-DAT曲线。对检测结果分析认为:1.ZnGa₂O₄属于尖晶石结构,稍过量的Zn或Ga能进入ZnGa₂O₄结构中,并对ZnGa₂O₄的晶格常数产生一定影响。2.ZnGa₂O₄存在两个自激发光中心,当Ga稍过量时,自激发光中心是四面体镓氧键[T_d(Ga-O)],最大激发波长约248nm,最大发射波长约367nm;当Zn稍过量时,自激发光中心是八面体镓氧键[O_h(Ga-O)],最大激发波长约270nm,最大发射波长约441nm。当n(Zn):n(Ga)在理论值附近,激发和发射光强度最大,而且光谱峰位发生了红移。3.ZnGa₂O₄的热稳定性能非常好。上述结论对研究ZnGa₂O₄基质或掺杂的发光材料具有一定意义。     

钙基载氧体煤化学链燃烧脱硫试验研究

在钙基载氧体燃煤化学链燃烧技术过程中由于煤气化产物与载氧体之间的副反应导致反应过程中产生大量的SO₂气体。本文选择MAC铁矿石,CaO和石灰石作为脱硫剂,在小型加压固定床上研究不同温度、压力、Ca/S比条件下SO₂气体的脱除问题。结果表明,单独采用CaSO₄载氧体时,随温度升高SO₂气体浓度逐渐增加。添加铁矿石后,SO₂排放浓度降低,主要与Fe₂O₃能够催化抑制CaSO₄分解有关。添加CaO和石灰石脱硫剂后,随温度、压力以及Ca/S比增加,两种脱硫剂的脱硫效率均增加,且在相同的实验条件下得到的CaO的脱硫效果更佳。     

Pressure and solvent induced low-temperature synthesis of monodisperse superparamagnetic nanocrystals: The case of Fe3O4 in alkanols

The synthesis of nanoparticles via the decomposition of organometallic compounds has been studied extensively, but the effect of pressure has received little attention. Here we firstly focus on the pressure effect, and utilize it as well as the solvent and temperature effects to develop a “green” cheap low-temperature (140–200 °C) strategy via the decomposition of iron oleate in alcohol (or other alkanols) using oleic acid as the protecting reagent. The obtained monodisperse Fe₃O₄ nanocrystals (NCs) exhibit satisfying superparamagnetism. The mechanism of the process has been investigated and it was shown both high pressure and alkanol as the solvent can facilitate the formation of magnetite NCs. Furthermore, the solvent used in the preparation can control the shape, size and dispersion of NCs. In addition, the effects of reactant concentration, reaction time, temperature, and the mol ratio of oleic acid on the Fe₃O₄ NCs have also been discussed.     

Superconducting oxide formation in the Yb---Ba---Cu---O system

Conditions for forming YbBa₂Cu₄O₈, Yb₂Ba₂Cu₃O_7−δ and YbBa₂Cu₃O_7−δ were determined in oxygen at 1.0 atm pressure by experiments with oxidized Yb---Ba---Cu---Ag alloys. YbBa₂Cu₃O_7−δ formed in less than 10 s when oxidized alloy ribbons were baked in the 805°C–890°C range. Large amounts of Ba₂Cu₃O₅ formed below 870°C. Yb₂Ba₄Cu₇O_15−δ and YbBa₂Cu₄O ₈ then formed in the 10²s–10³s range at temperatures in the 840°C–870°C and <840°C ranges, respectively. Ba₂Cu₃O₅ decomposition supplied Cu²⁺ and O²⁻ for the rapid transformation of YbBa₂Cu₃O_7−δ grains into Yb₂Ba₄Cu₇O_15−δ grains by intercalation. Intercalation was much slower in the absence of Ba₂Cu₃O₅. All of these transformation products underwent coarsening with increasing bake time. Rapid YbBa₂Cu₄O₈ and Yb₂Ba₄Cu₇O_15−δ formation, compared to the slow formation of these phase types when Yb was substituted by Y, Is due to the differing effects of Y and Yb on formation kinetics. Superconducting oxide-silver composite ribbons containing mainly YbBa₂Cu₃O_7−δ, Yb₂Ba₄Cu₇O_15−δ or YbBa₂Cu₄O₈ can be prepared from Yb---Ba ---Ba---Cu---Ag alloys.     

石墨烯在Al_2O_3(0001)表面生长的模拟研究

基于密度泛函理论的广义梯度近似法,对用化学气相沉积法在蓝宝石(α-Al_2O_3)(0001)表面上生长石墨烯进行理论研究.研究结果表明:CH_4在α-Al_2O_3(0001)表面上的分解是吸热过程,由CH_4完全分解出C需要较高能量及反应能垒,这些因素不利于C在衬底表面的存在.在α-Al_2O_3(0001)表面,石墨烯形核的活跃因子并不是通常认为的C原子,而是CH基团.通过CH基团在α-Al_2O_3(0001)表面上的迁移聚集首先形成能量较低的(CH)_x结构.模拟研究(CH)_x对揭示后续石墨烯的形核生长机理具有重要意义.