Herein, TiO_{2} nanopillars (NPs)/N-doped graphene quantum dots (N-GQDs)/g-C_{3}N_{4} QDs heterojunction efficiently suppressed the photogenerated charges recombination and improved photo-to-current conversion efficiency. The introduced N-GQDs and g-C_{3}N_{4} QDs could result in more effective separation of the photogenerated charges, and thus produce a further increase of the photocurrent. TiO_{2} NPs/N-GQDs/g-C_{3}N_{4} QDs were firstly applied as the photoactive materials for the fabrication of the biosensors, and the primers of pcDNA3-HBV were then adsorbed on the TiO_{2} NPs/N-GQDs/g-C_{3}N_{4} QDs modified electrode under the activation of EDC/NHS. With increase of the pcDNA3-HBV concentration, the photocurrent reduced once the double helix between the primers and pcDNA3-HBV formed. The developed photoelectrochemical (PEC) biosensor showed a sensitive response to pcDNA3-HBV in a linear range of 0.01 fmol/L to 20nmol/L with a detection limit of 0.005 fmol/L under the optimal conditions. The biosensor exhibited high sensitivity, good selectivity, good stability and reproducibility.
【저자키워드】 Photoelectrochemistry, TiO(2) NPs/N-GQDs/g-C(3)N(4) QDs, pcDNA3-HBV.,