Hybrid Reduced Graphene Oxide/GaN Nanocolumns on Flexible Niobium Foils for Efficient Photoelectrochemical Water Splitting

We present the photoelectrochemical (PEC) water-splitting properties of pristine and reduced graphene oxide (rGO)-coated GaN nanocolumns (NCs) on flexible niobium (Nb) metal foils. The structural, optical, and electronic structure analyses of rGO-coated GaN-NCs on Nb foils revealed the formation of a rGO/GaN-NCs hybrid structure. Further, the valence-band studies of pure GaN-NCs shows valence-band maxima at similar to 3.0 eV below the Fermi level, which decreased to similar to 2.8 eV for rGO/GaN-NCs. The PEC measurement performed on pristine GaN-NCs under standard (1 Sun) conditions shows an effective photocatalytic nature with a photocurrent density of similar to 60 mu A/cm2 at 0.8 V (vs Ag/AgCl) in a 1 M oxalic acid electrolyte, which increases to similar to 110 mu A/cm2 for rGO/ GaN-NCs. The efficient PEC characteristics of rGO/GaN-NCs are attributed to the effective charge separation/transport of photogenerated carriers. Furthermore, transient photocurrent measurement reveals that hybrid and pristine GaN-NCs on flexible metal foil have a fast and stable photoresponse in an aqueous solution. The development of a hybrid nitride nanostructure-based PEC device on flexible metal foils paves the way toward developing scalable PEC devices for hydrogen production applications.

Automated summary

We studied the photoelectrochemical properties of reduced graphene oxide-coated GaN nanocolumns on flexible niobium foils. The graphene-coated GaN nanocolumns formed a hybrid structure and showed improved charge separation and transport, leading to enhanced photocurrent density compared to pure GaN nanocolumns. The hybrid nitride nanostructure-based PEC device on flexible metal foils demonstrated fast and stable photoresponse in aqueous solution, suggesting its potential for scalable hydrogen production.