Effect of N-rGO Decoration on the Structure and Optical Properties of WO3 Nanoplates

Abstract: In this research, tungsten trioxide (WO 3) nanoplates and WO 3 /N-doped reduced graphene oxide (WO 3 /N-rGO) nanocomposites were synthesized with various amounts of N-rGO using the hydrothermal method. X-ray diffraction analysis showed that WO 3 /N-rGO nanocomposites (with 3%, 6%, and 9% of N-rGO) had a hexagonal structure with (200) preferential radial of the crystal plane. According to transmission electron microscopy images, WO 3 has a nanoplate structure with a width within the range of 20-40 nm and length… Show more

“…Compared to WO 3 (0.35 × 10 –4 A/cm 2 ), WO 3 /rGO (0.78 × 10 –4 A/cm 2 ), and WO 3 /N-rGO (2.04 × 10 –4 A/cm 2 ) exhibit stronger photocurrent, which is considered as the strategy of integrating WO 3 with rGO and N-rGO. Graphene can rapidly transfer photogenerated carriers to external circuits due to its high electrical conductivity. , In addition, the photocurrent of WO 3 /N-rGO is 2.6 times as high as that of WO 3 /rGO due to the formation of phase junction between monoclinic WO 3 and orthorhombic WO 3 , − and the doping of N. , The phase junction effectively promotes the separation of electron–hole pairs, while the nitrogen doping lowers the Schottky junction barrier of WO 3 /N-rGO and facilitates the transfer of electrons from WO 3 to N-rGO . The rise–decay dynamics of transient photocurrent measurement provide direct information on trapping, recombination, and charge transport .…”

In Situ Synthesis of Mixed-Phase WO₃ on Nitrogen-Doped Graphene with Enhanced Photoelectric Properties

“…Compared to WO 3 (0.35 × 10 –4 A/cm 2 ), WO 3 /rGO (0.78 × 10 –4 A/cm 2 ), and WO 3 /N-rGO (2.04 × 10 –4 A/cm 2 ) exhibit stronger photocurrent, which is considered as the strategy of integrating WO 3 with rGO and N-rGO. Graphene can rapidly transfer photogenerated carriers to external circuits due to its high electrical conductivity. , In addition, the photocurrent of WO 3 /N-rGO is 2.6 times as high as that of WO 3 /rGO due to the formation of phase junction between monoclinic WO 3 and orthorhombic WO 3 , − and the doping of N. , The phase junction effectively promotes the separation of electron–hole pairs, while the nitrogen doping lowers the Schottky junction barrier of WO 3 /N-rGO and facilitates the transfer of electrons from WO 3 to N-rGO . The rise–decay dynamics of transient photocurrent measurement provide direct information on trapping, recombination, and charge transport .…”

In Situ Synthesis of Mixed-Phase WO₃ on Nitrogen-Doped Graphene with Enhanced Photoelectric Properties