Similarly, previous works about the graphene/sulfur nano-composites did not exhibit a good electrochemical
performance either, especially at high current rates over 1 C, although a graphene is generally regarded to have a high selleckchem electrical conductivity [27, 28]. This study proves that a sulfur/GHCS nano-composite is an effective method to overcome these problems and shows an easy, convenient, and scalable method to fabricate a graphitic hollow carbon sphere. Figure 1 Schematic diagram for the process to synthesize a graphitic hollow carbon sphere. (a) Homogenous mixture of silica sphere and JPH203 Fe-Pc, (b) decomposition of Fe-Pc at 500°C to 600°C, (c) graphitization of carbon shell at 900°C by the catalytic action of
Fe nanoparticles, and (d) hollow carbon sphere after HF etching. Figure 2 Characterization of graphitic hollow carbon sphere made from Fe-Pc. (a) SEM and (b) TEM images, (c) X-ray diffraction pattern, and (d) Raman spectra together with the one made from sucrose. Figure 3 Nitrogen adsorption/desorption isotherm and the corresponding BJH pore size distribution. Nitrogen adsorption/desorption isotherm at 77 K for the graphitic hollow carbon sphere synthesized in this work and the corresponding BJH pore size distribution from the desorption branch (inset). Figure 4 SEM images, XRD patterns, and thermogravimetric analysis. SEM images of the graphitic hollow carbon sphere (a) before and (b) after sulfur impregnation. MK5108 molecular weight (c) The XRD patterns of the mixture of the graphitic hollow carbon and sulfur before and after the heat treatment at 155°C in vacuum, and (d) the TGA recorded for the sulfur-impregnated graphitic hollow carbon in N2 atmosphere at a heating rate of 10°C/min. Figure 5 EDX compositional analysis (profiling 4��8C along the red line). A single particle of the sulfur-impregnated graphitic
hollow carbon sphere showing the presence of sulfur (yellow) in the composite. Figure 6 Li-S cell made of sulfur/graphitic hollow carbon sphere nano-composite cathode. (a) Cycling performance and (b) discharge–charge profiles. The current rate was C/10 for the initial three cycles and C/2 afterwards. Figure 7 Discharge capacities and discharge–charge profiles of Li-S cell. (a) Discharge capacities and (b) discharge–charge profiles at the various current rates. Filled blue squares in (a) represent the discharge capacities of sulfur/carbon black nano-composite made by ball milling for comparison. Figure 8 TEM image and discharge–charge profiles. (a) TEM image of the sulfur/carbon black nano-composite made by simple ball milling and (b) discharge–charge profiles at various current rates of the Li-S cell made of ball-milled nano-composite.
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