Si/Ti_xSi_y复合物的合成及其锂离子电池负极性能研究

通过机械球磨和高温热处理合成得到Si和Ti_xSi_y纳米颗粒复合物Si/Ti_xSi_y,并对该化合物进行X射线能谱(EDX)、X射线衍射(XRD)、透射电子显微镜(TEM)和扫描电子显微镜(SEM)表征.合成的Si/Ti_xSi_y和机械球磨的Si/TiO_2都被用于锂离子电池的负极材料,Si/Ti_xSi_y表现出优越的充放电性能、较好的循环稳定性和倍率性能.     

Ultrafast anode for high voltage aqueous Li-ion batteries

Clustered Mo sulfide Mo₆S₈ (Chevrel phase) demonstrates outstandingly high rate capability in contact with concentrated aqueous Li₂SO₄ solutions. Slow galvanostatic cycling can be performed with good Faradaic efficiency at a moderate capacity of 32.1?mAhg^{? 1} (1e^? reduction of Mo₆S₈), which in combination with 1e^? oxidation process in Li _x Mn₂O₄ cathode, results in equilibrium cell voltage of 1.5?V. Higher rates of charge and discharge have been also achieved within a considerably extended apparent electrochemical stability window involving second two-electron reduction of Mo₆S₈ which leads to apparent cell voltage of 1.85?V, specific capacity about 74.7?mAhg^?1 at 90?% Faradaic efficiency, specific energy of 74?Wh?kg^?1 (related to both electrodes) at extremely high charge–discharge rate of 60?C. Our study highlights the generic feature of Li-ion aqueous cells, namely, a high rate capability coupled with a relatively fast self-discharge which necessitates a more profound understanding of the nature of self-discharge in Li-ion insertion hosts in contact with aqueous solutions.     

Influence of graphene oxide on electrochemical performance of Si anode material for lithium-ion batteries

We have developed a Si/graphene oxide electrode synthesized via ultrasonication-stirring method under alkaline condition. Scanning electron microscopy(SEM), transmission electron microscope(TEM), EDS dot-mapping and high-resolution transmission electron microscopy(HRTEM) results show that Si particles are evenly dispersed on the graphene oxide sheets. The electrochemical performance was investigated by galvanostatic charge/discharge tests at room temperature. The results revealed that Si/graphene oxide electrode exhibited a high reversible capacity of 2825 mAh/g with a coulombic efficiency of 94.6%at 100 mA/g after 15 cycles and a capacity retention of 70.8% after 105 cycles at 4000 mA/g. These performance parameters show a great potential in the high-performance batteries application for portable electronics, electric vehicles and renewable energy storage.     

All boron-based 2D material as anode material in Li-ion batteries

To design the high-energy-density Li-ion batteries, the anode materials with high specific capacity have attracted much attention. In this work, we adopt the first principles calculations to investigate the possibility of a new two dimensional boron material, named BG, as anode material for Li-ion batteries. The calculated results show that the maximum theoretical specific capacity of B_G is 1653 m Ah g~(-1)(LiB1.5).Additionally, the energy barriers of Li ion and Li vacancy diffusion are 330 meV and 110 meV, respectively, which imply fast charge and discharge ability for BGas an anode material. The theoretical findings reported in this work suggest that BGis a potential candidate as anode material of high-energy-density Li-ion batteries.     

In situ measurement of biaxial modulus of Si anode for Li-ion batteries

We report in situ measurement of biaxial moduli of a Si thin-film electrode as a function of its lithium concentration. During lithiation, biaxial compressive stress is induced in the Si film and it undergoes plastic flow. At any state-of-charge (SOC), a relatively small delithiation–relithiation sequence unloads and reloads the film elastically. From the stress and strain changes during a delithiation–relithiation cycle, the biaxial modulus of the film is calculated. Stress change is obtained by measuring the change in substrate curvature using a Multi-beam Optical Sensor; the elastic strain change is obtained from the change in SOC. By repeating these measurements at several different values of SOC, the biaxial modulus was seen to decrease from ca. 70 GPa for Li_0.32Si to ca. 35 GPa for Li_3.0Si. Such a significant reduction in elastic modulus has important implications for modeling stress evolution and mechanical degradation in Si-based anodes.     

High performance silicon nanoparticle anode in fluoroethylene carbonate-based electrolyte for Li-ion batteries

Electrodes composed of silicon nanoparticles (SiNP) were prepared by slurry casting and then electrochemically tested in a fluoroethylene carbonate (FEC)-based electrolyte. The capacity retention after cycling was significantly improved compared to electrodes cycled in a traditional ethylene carbonate (EC)-based electrolyte.     

Surface-fluorinated graphite anode materials for Li-ion batteries

Surface modification of graphite powder has been performed by chemical fluorination using elemental fluorine at 200 °C and 300 °C. This process leads to an increase of the BET surface area due to partial CC bond breaking. Surface analyses performed by secondary ions mass spectrometry have shown that the H + O content at the surface of graphite is significantly decreased by this fluorination treatment. Fluorinated graphite powders have been tested as negative electrodes in Li-ion battery, chronopotentiometry measurements have shown that the fluorinated graphite exhibits better electrochemical performances than raw graphite powder notably due to an increase of the surface area which allows the storage of a higher amount of lithium into the host lattice. In addition, impedance measurements performed in a delithiated state have shown a significant decrease of the total cell resistance, i.e. a decrease of both the charge transfer resistance and the resistance related to the solid electrolyte interface (SEI) layer.     

Microemulsion-mediated sol-gel synthesis of mesoporous rutile TiO2 nanoneedles and its performance as anode material for Li-ion batteries

Mesoporous rutile TiO(2) nanoneedles have been successfully synthesized using a reverse microemulsion-mediated sol-gel method at room temperature. The materials were characterized by X-ray diffraction (XRD), transmission electron microscopy (TEM), and the Bruauner-Emmet-Teller (BET) adsorption method, and their electrochemical properties were investigated by galvanostatic charge and discharge tests. XRD observations revealed the formation of a pure rutile TiO(2) phase. Furthermore, TEM observation revealed the presence of a highly porous needle-like morphology. The electrochemical measurements show that the nanoneedles deliver an initial capacity of 305 mA h g(-1) as anode material for Li-ion batteries and sustain a capacity value of 128 mA h g(-1) beyond 15 cycles. The reported synthesis is simple, mild, energy efficient, and without postcalcination.     

Sol–gel derived nano-crystalline CaSnO3 as high capacity anode material for Li-ion batteries

CaSnO₃ with the distorted-perovskite structure was prepared by sol–gel and high temperature solid-state reaction and electrochemical properties were studied in cell with Li as counter electrode. The sol–gel method gave uniform nano-crystallites (200–300 nm) of CaSnO₃ and was shown to deliver a reversible capacity of 380 mAh/g (0.005–1.0 V; 60 mA/g) with good cycling stability up to 45 cycles. The observed capacity involved in the first-discharge and the reversible capacity values during subsequent charge–discharge cycles show that the electrochemical process in CaSnO₃ is similar to other Sn-containing mixed oxide systems, viz., an initial structural reduction with Sn-metal formation followed by reversible Li–Sn alloy formation. The performance with respect to the attainable capacity, its retention on charge–discharge cycling and rate capability is better than the previously reported best-performing bulk Sn-oxide or ATCO starting materials which reveals that the perovskite structure and Ca-ion play a beneficial role.     

Electrochemical performance of graphene nanosheets as anode material for lithium-ion batteries

Graphene nanosheets (GNSs) were prepared from artificial graphite by oxidation, rapid expansion and ultrasonic treatment. The morphology, structure and electrochemical performance of GNSs as anode material for lithium-ion batteries were systematically investigated by high-resolution transmission electron microscope, scanning electron microscope, X-ray diffraction, Fourier transform infrared spectroscopy and a variety of electrochemical testing techniques. It was found that GNSs exhibited a relatively high reversible capacity of 672 mA h/g and fine cycle performance. The exchange current density of GNSs increased with the growth of cycle numbers exhibiting the peculiar electrochemical performance.     

A novel mesoporous carbon-silica-titania nanocomposite as a high performance anode material in lithium ion batteries

An ordered mesoporous carbon-silica-titania material was prepared using the tetra-constituents co-assembly method. As regards its anode performance in lithium ion batteries, the composite material anode exhibited a high capacity (875 mAh g(-1)), a higher initial efficiency (56%) and an improved rate.     

Macroporous Mn3O4 microspheres as a conversion-type anode material morphology for Li-ion batteries

Journal of Solid State Electrochemistry - Transition metal oxides can electrochemically react with Li+ to result in the formation of Li2O and metal nanoparticles, and thus are good candidates as...     

Matryoshka-type carbon-stabilized hollow Si spheres as an advanced anode material for lithium-ion batteries

Silicon(Si) is regarded as the potential anode for lithium-ion batteries(LIBs), due to the remarkable theoretical specific capacity and low voltage plateau. However, the rapid capacity decay resulting from volume variation and slow electron/ion transportation of Si limit its practical application. Here, matryoshka-type carbon-stabilized hollow silicon spheres(Si/C/Si/C) are synthesized by an aluminothermic reduction and calcination process. The Si/C/Si/C anode materials prepared at 500 ℃(Si/C/Si...     

Porous Si coated with S-doped carbon as anode material for lithium ion batteries

A novel porous Si/S-doped carbon composite was prepared by a magnesiothermic reaction of mesoporous SiO₂, subsequently coating with a sulfur-containing polymer-poly(3,4-ethylene dioxythiophene), and a post-carbonization process. The as-prepared Si composite was homogeneously coated with disordered S-doped carbon with 2.6 wt.%?S in the composite and retained a high surface area of 58.8 m²?g^?1. The Si/S-doped carbon composite exhibited superior electrochemical performance and long cycle life as an anode material in lithium ion cells, showing a stable reversible capacity of 450 mAh g^?1 even at a high current rate of 6,000 mA?g^?1.     

A selenium-doped carbon anode of high performance for lithium ion batteries

Journal of Solid State Electrochemistry - The strong demand on high-performance lithium ion batteries has brought up an attention upsurge in the research society and the commercial market. Carbon...     

Iron sulfide-embedded carbon microsphere anode material with high-rate performance for lithium-ion batteries

Iron sulfide-embedded carbon microspheres were prepared via a solvothermal process and show high specific capacity and excellent high-rate performance as anode material for lithium-ion batteries.     

Goethite nanorods as anode electrode materials for rechargeable Li-ion batteries

Although various transition metal oxides have been reported to act as low potential Li insertion hosts, the oxyhydroxides have remained unexplored to date. We show here that the hydroxide ions present in transition metal oxyhydroxides do not interfere with the lithium uptake and extraction, permitting very good reversibility of the reduction/oxidation reactions. Goethite (α-FeOOH) nanocrystals can uptake and extract large amount of Li via the conversion reaction mechanism, providing a reversible capacity of 500 mA h g⁻¹ at an average potential of 0.85 V vs. Li/Li⁺. The mechanism was examined using a combination of X-ray diffraction, electron microscopy, and the corresponding selected area electron diffractions (SAEDs). The α-FeOOH is reduced into nanoparticles of metallic Fe⁰ embedded in an amorphous matrix of Li₂O and LiOH in the first discharge; the subsequent cyclings are redox reactions between metallic Fe⁰ and Fe₂O₃ clusters.     

High-performance self-organized Si nanocomposite anode for lithium-ion batteries

Silicon is being investigated extensively as an anodic material for next-generation lithium ion batteries for portable energy storage and electric vehicles.However,the large changes in volume during cycling lead to the breakdown of the conductive network in Si anodes and the formation of an unstable solid-electrolyte interface,resulting in capacity fading.Here,we demonstrate nanoparticles with a Si@Mn_(22.6)Si_(5.4)C_4@C double-shell structure and the formation of self-organized Si-Mn-C nanocomposite anodes during the lithiation/delithiation process.The anode consists of amorphous Si particles less than 10 nm in diameter and separated by an interconnected conductive/buffer network,which exhibits excellent charge transfer kinetics and charge/discharge performances.A stable specific capacity of 1100 mAh·g~(-1) at 100 mA·g~(-1) and a coulombic efficiency of 99.2%after 30 cycles are achieved.Additionally,a rate capacity of 343 mAh·g~(-1) and a coulombic efficiency of 99.4%at 12000 mA·g~(-1) are also attainable.Owing to its simplicity and applicability,this strategy for improving electrode performance paves a way for the development of high-performance Si-based anodic materials for lithium ion batteries.     

SnO2 hollow nanospheres assembled by single layer nanocrystals as anode material for high performance Li ion batteries

SnO₂ hollow nanospheres were successfully synthesized via a facile one-step solvothermal method.Characterizations show that the as-prepared SnO₂ spheres are of hollow structure with a diameter at around 50 nm,and especially,the shell of the spheres is assembled by single layer SnO₂ nanocrystals.The surface area of the material reaches up to 202.5 m²/g.As an anode material for Li ion batteries,the sample exhibited improved electrochemical performance compared with commercial SnO₂ particles.After cycled at high current rate of 0.5 C,1 C and 0.5 C for 20 cycles,respectively,the electrode can maintain a capacity of 509 mAh/g.The suitable shell thickness/diameter ratio endows the good structural stability of the material during cycling,which promises the excellent cycling performance of the electrode.The large surface area and the ultra thin shell ensure the high rate performance of the material.