Tuneable effects of pyrrolic N and pyridinic N on the enhanced field emission properties of nitrogen-doped graphene

Graphene is one of the most potential field emission cathode materials and a lot of work has been carried out to demonstrate the effectiveness of nitrogen doping (N doping) for the enhancement of field emission properties of graphene. However, the effect of N doping on graphene field emission is lacking systematic and thorough understanding. In this study, undoped graphene and N-doped graphene were prepared and characterized for measurements, and the field emission property dependence of the doping content was investigated and the tuneable effect was discussed. For the undoped graphene, the turn-on field was 7.95 V mu m-1 and the current density was 7.3 mu A cm-2, and for the 10 mg, 20 mg, and 30 mg N-doped graphene samples, the turn-on fields declined to 7.50 V mu m-1, 6.38 V mu m-1, and 7.28 V mu m-1, and current densities increased to 21.0 mu A cm-2, 42.6 mu A cm-2, and 13.2 mu A cm-2, respectively. Density functional theory (DFT) calculations revealed that N doping could bring about additional charge and then cause charge aggregation around the N atom. At the same time, it also lowered the work function, which further enhanced the field emission. The doping effect was determined by the content of the pyrrolic-type N and pyridinic-type N. Pyridinic-type N is more favourable for field emission because of its smaller work function, which is in good agreement with the experimental results. This study would be of great benefit to the understanding of N doping modulation for superior field emission properties. Providing insight into the specific tuneable effect of different N doping configurations and N doping ratio on the field emission properties of graphene.

Automated summary

Graphene is a promising material for field emission, and nitrogen doping has been shown to enhance its field emission properties. This study investigated the impact of nitrogen doping on field emission by comparing undoped graphene with different levels of nitrogen doping. The results showed that nitrogen doping reduced the turn-on field and increased the current density. Density functional theory calculations revealed that nitrogen doping introduced additional charge and lowered the work function, leading to enhanced field emission. This study provides valuable insights into the tunable effect of nitrogen doping on the field emission properties of graphene.