Abstract: In recent years, graphene materials play an important role in the application of electronic materials. Therefore, it is very important to seek a good theoretical calculation method to predict the electronic properties and applications of graphene materials. In this paper, graphene as the research axis, by theoretical calculations to provide information to experimental scholars, open the graphene nano-band gap, as a microelectronic material switch; the other hand, the triangular handrail defect graphene nano-band as a new adsorbent, to adsorbe of heavy metal ions. In the first part, the electronic properties of graphene of different sizes and shapes which the energy gap of the graphene decreases with the increase of the carbon number. The size of the band gap will vary with the shape of the graphene nanobands. When the number of external hydrogen atoms is the same, the energy gap is directly proportional to the number of double bonds. In the second part, adsorption of silver ions on the triangular band of graphene nanoribbons can change the semiconducting property into metality, and calculate the B - site (carbon - carbon bond) as the best adsorption position. The third part is the chemical modification of the inner nitrogen and oxygen atoms by using the graphene nanobands with triangular handrail defects. The experimental results show that the middle vacancies can effectively adsorb Fe2 +, Co2 +, Ni2 +, Cu2 + and Zn2 +.