Graphite Encapsulated Metal (GEM) nanoparticles are core-shell composite-structured nano-materials with an inner core of metal and outer shells of graphite layers. Because of the protection of the stable graphite shell which can resist against acid erosion and oxidation, the internal metal can be preserved in server environment and exhibited its characteristics. It has wide application especially for graphite encapsulated iron (Fe-GEM) nanoparticles, for example, wastewater treatment, bio-technology and microwave absorber. However, the production rate and encapsulation efficiency of Fe-GEM is not as high as graphite encapsulated nickel (Ni-GEM) nanoparticles. In 1997 years, Elliott et al., proposed the most fundamental mechanism, Two-Step Mechanism, to explain the detail synthesis process. The encapsulation efficiency and production rate of GEM is affected by the sufficient and uniform carbon vapor in the coalescence area. However, to reach good vapor environment is not easy because of metal vapor, catalysis ability and metal carbide which decisively influences the result. From the result of Encapsulation efficiency of Fe-GEM and Ni-GEM, discussing the factor of iron and limitation of benzene is necessary that benzene can’t diffuse into high temperature coalescence area because of high molecular weight and air convection. To improve the carbon vapor distribution, adding the solid carbon resource, naphthalene, in crucible to enhance the carbon vapor in high temperature coalescence area is valid to raise encapsulation efficiency to 88% and 92% for inner core of iron and nickel respectively. Also, graphite encapsulated aluminum nanoparticles which is support unable to produce because of carbide is successful made. It shows the necessary of excess and uniform carbon vapor in metal vapor. According to the result. It is supported to establish the forming graphite or carbon soot of high temperature coalescence area, phase segregation domain, and low temperature coalescence area, catalytic domain. This procedure is expected to establish a preliminary concept to provide the foundation for more in-depth materials science research in the future.