MoS2 nanosheet arrays supported on hierarchical nitrogen-doped porous carbon(MoS2@C)have been synthesized by a facile hydrothermal approach combined with high-temperature calcination.The hierarchical nitrogen-doped porous carbon can serve as three-dimensional conductive frameworks to improve the electronic transport of semiconducting MoS2.When evaluated as anode material for lithium-ion batteries,the MoS2@C exhibit enhanced electrochemical performances compared with pure MoS2 nanosheets,including high capacity(1305.5 mA h g-1 at 100 mA g-1),excellent rate capability (438.4 mA h g-1 at 1000 mA g-1).The reasons for the improved electrochemical performances are explored in terms of the high electronic conductivity and the facilitation of lithium ion transport arising from the hierarchical structures of MoS2@C. 相似文献
Amorphous MnO2 has been prepared from the reduction of KMnO4 in ethanol media by a facile one‐step wet chemical route at room temperature. The electrochemical properties of amorphous MnO2 as cathode material in sodium‐ion batteries (SIBs ) are studied by galvanostatic charge/discharge testing. And the structure and morphologies of amorphous MnO2 are investigated by X‐ray diffraction (XRD ), scanning electron microscopy (SEM ), transmission electron microscopy (TEM ) and Raman spectra. The results reveal that as‐synthesized amorphous MnO2 electrode material exhibits a spherical morphology with a diameter between 20 and 60 nm. The first specific discharge capacity of the amorphous MnO2 electrode is 123.2 mAh •g−1 and remains 136.8 mAh •g−1 after 100 cycles at the current rate of 0.1 C. The specific discharge capacity of amorphous MnO2 is maintained at 139.2, 120.4, 89, 68 and 47 mAh •g−1 at the current rate of 0.1 C, 0.2 C, 0.5 C, 1 C and 2 C, respectively. The results indicate that amorphous MnO2 has great potential as a promising cathode material for SIBs . 相似文献
Starting from readily available oleic and erucic acid, macrocyclic nonadecalactone (C19) and tricosalactone (C23) can be synthesized in polymerization grade purity in a four‐step reaction sequence. Ring‐opening polymerization (ROP) of these strainless macrolactones can be performed utilizing an enzyme as a catalyst. Despite the missing ring‐strain as key driving force for smaller (strained) lactones, high molar masses (M n ≈ 105 g mol−1) can be accessed in an entropically driven ROP. Polyester‐19 and polyester‐23 prepared feature melting temperatures well above 100 °C. Further analysis of the mechanical properties of these materials displays the resemblance to polyethylene. For example, Young's moduli on the order of 600 MPa are observed as a result of the high crystallinity of the polymer.
[4]Cyclo-9, 9-dimethyl-2, 7-fluorenylene ([4]CF) was used as a model compound to explore the steric strain effect on the structures and photoelectrical properties of materials. A series of strained cyclic polyfluorene materials, [n]CFs (n=3-8), was designed. It was found that the strain energy decreased and the energy gap increased as the number of n and ring diameter increased. The ionization potential and electronic affinity tended to increase and decrease as the strain energy decreased at the same number of [n]CFs, respectively. With a balance between hole and electron reorganization energies in the system, these compounds demonstrated great potential as ambipolar materials. It was also found that [n]CFs showed an obvious blue shift in their emission spectra wavelengths (λem2) as the strain energy decreased. Steric strain provides a powerful tool for the design of multifunctional semiconductors in organic optoelectronics. 相似文献
