The DPG powders manufactured in the experiment was applied to the anode material for lithium ion secondary battery, and the capacity of the battery was good. The reversible capacity of DPG powders was over 400 mA/g , even higher than the theoretical value 372mAh/g. However, the irreversibility of the battery reached 30%.In the HBr rinsed DPG powders, we found one different diffraction peak in the XRD pattern. The conception of experiments was finding out the possible structure of the derivatives. At the same time, we calculated the content of the derivative in the DPG powders. Finally, we compared the results of the DPG powders which was manufactured with the different concentration of HBr we used SEM(scanning electron microscopy) to observe the changes on the surface, and used XRD(X-ray diffraction) and EDX(energy dispersive spectrometer) to carry out qualitative analysis, and then decided the possible structure of the derivatives. In the end, we used Rietveld Method to estimate the content of the different derivatives in the DPG powders. Results from the experiment indicated that there were at least three different kinds of components in the DPG powders: Hexagonal Graphite, Orthorhombic Carbon, Iron Oxide(Fe2O3). Meanwhile, the content of the three kinds of the derivatives changed with the concentration of HBr and used. We found that content of the Hexagonal Graphite increased with the concentration of HBr we used. However, the content of the Orthorhombic Carbon decreased with the concentration of HBr we used. It indicated that the Orthorhombic Carbon was more reactive with HBr than the Hexagonal Graphite for the poor crystallinity.