Antil, B.Kumar, L.Ranjan, R.Shenoy, S.Tarafder, K.Gopinath, C.S.Deka, S.2026-02-052021ACS Applied Energy Materials, 2021, 4, 4, pp. 3118-3129https://doi.org/10.1021/acsaem.0c02858https://idr.nitk.ac.in/handle/123456789/23254The emerging metal-free carbon nitride (C3N4) offers prominent possibilities for realizing the highly effective hydrogen evolution reaction (HER). However, its poor surface conductivity and insufficient catalytic sites hinder the HER performance. Herein, a one-dimensional vermicular rope-like graphitic carbon nitride nanostructure is demonstrated that consists of multichannel tubular pores and high nitrogen content, which is fabricated through a cost-effective approach having the final stoichiometry g-C3N4.7 for HER application. The present g-C3N4.7 is unique owing to the presence of abundant channels for the diffusion process, modulated surface chemistry with rich-electroactive sites from N-electron lone pairs, greatly reduced recombination rate of photoexcited exciton pairs, and a high donor concentration (4.26 × 1017 cm3). The catalyst offers a visible-light-driven photocatalytic H2 evolution rate as high as 4910 ? mol h-1 g-1 with an apparent quantum yield of 14.07% at band gap absorption (2.59 eV, 479 nm) under 7.68 mW cm-2 illumination. The number of hydrogen gas molecules produced is 1.307 × 1015 s-1 cm-2, which remained constant for a minimum of 18 h of repeated cycling in the HER without any degradation of the catalyst. In density functional theory calculations, a significant change in the band offset is observed due to N doping into the system in favor of electron catalysis. The theoretical band gap of a monolayer of g-C3N4.7 was enormously reduced because of the presence of additional densities of states from the doped N atom inside the band gap. These impurity or donor bands are formed inside the band gap region, which ultimately enhance the hydrogen ion reduction reaction enormously. © 2021 American Chemical Society.Carbon nitrideCatalystsCost effectivenessDensity functional theoryHydrogen evolution reactionPhotocatalytic activitySurface chemistryCost-effective approachHigh nitrogen contentHydrogen ion reductionPhotocatalytic H2 evolutionPhotocatalytic hydrogen evolutionSurface conductivityTheoretical investigationsVisible-light-drivenEnergy gap