The thesis was divided into three parts. The first part presented the preparation of conducting particles. The second part illustrated the synthesis of poly(3,4-ethylenedioxythiolphene):poly(styrenesulfonate) (PEDOT:PSS). In the last part, we combined these two conductive materials into ECAs for optimizing the resistivity with less silver weight percentage. Conductive particles were investigated by Particle Size Analyzer and SEM to ensure the suitable size and flake morphology in ECAs. We also showed the samples with sensitization and activation process had less graphite exposure, and confirmed self-activation method could replace Pd-activation method in eletroless plating process by EDX, XRD and ICP analysis. In addition, the performance of silver eletroless plating on graphene surface was better than it on graphite/graphene composite particles. Conductivity measurements showed that using nitrogen-pretreatment water and dialysis would help the polymerization and purification of PEDOT:PSS, thus increasing the conductivity. Adding organic solvent would transform the morphology of PEDOT:PSS film, which had huge influence on conductivity. In this study, the best conductivity of PEDOT:PSS film was 321.5 S/cm, which reached as PEDOT:PSS weight ratio was 1:1 and with 7.5 wt% DMSO. In the study of preparing electrically conductive adhesives, higher curing temperature and lower pressure got lower resistivity. Adding alkyl-thiol as dispersant would decrease the resistivity, and the best of them was butanethiol. In addition, adding PEDOT:PSS also did decrease the resistivity, but it was not so effective at high filling ratio. Silver plated graphene particles without butanethiol as dispersant would dramatically enhance the resistivity. After surface modification with butanethiol, silver plated graphene particles turned to be beneficial for decreasing resistivity. In this thesis, the better resistivity of ECAs were 1.02x10-4 ohm-cm(Ag 44.43 wt%) and 1.55x10-4 ohm-cm(Ag 38.87 wt%).