Insights into Atomic Level π-Electron Modulations in Supramolecular Carbon Nitride Nanoarchitectonics for Sustainable Green Hydrogen Production

Dharmarajan, Nithinran Panangattu; Fawaz, Mohammed; Likozar, Blaž; Jeon, Chung-Hwan; Yang, Jae-Hun; Vinu, Ajayan; Sathish, C. I.; Talapaneni, Siddulu Naidu; Ramadass, Kavitha; Sadanandan, Aathira M.; Ta, Xuan Minh Chau; Huš, Matej; Perumalsamy, Vibin; Tricoli, Antonio

Title: Insights into Atomic Level π-Electron Modulations in Supramolecular Carbon Nitride Nanoarchitectonics for Sustainable Green Hydrogen Production
Creator: Dharmarajan, Nithinran Panangattu; Fawaz, Mohammed; Likozar, Blaž; Jeon, Chung-Hwan; Yang, Jae-Hun; Vinu, Ajayan; Sathish, C. I.; Talapaneni, Siddulu Naidu; Ramadass, Kavitha; Sadanandan, Aathira M.; Ta, Xuan Minh Chau; Huš, Matej; Perumalsamy, Vibin; Tricoli, Antonio
Relation: ARC.DE190100965 http://purl.org/au-research/grants/arc/DE190100965
Relation: Advanced Energy Materials Vol. 14, Issue 29, no. 2400686
Publisher Link: http://dx.doi.org/10.1002/aenm.202400686
Publisher: John Wiley & Sons
Resource Type: journal article
Date: 2024
Description: Carbon nitrides, metal-free semiconducting materials, have unique molecular structure and semiconducting properties which have inspired researchers to utilize them as photocatalysts for the sustainable production of hydrogen. However, they suffer from a few drawbacks including fast charge-carrier recombination rate and low charge transfer efficiency owing to their amorphous and less conducting wall structure which remain as significant challenge for achieving breakthrough in photocatalytic water splitting. Herein, the study reports a supramolecular approach of coupling thiourea and trimesic acid for designing highly efficient C-doped carbon nitride photocatalysts in which the π-electron density is precisely manipulated. The developed C-doped carbon nitride demonstrates the fine-tuned band positions, the mitigated electron–hole recombination, and enhanced conductivity, resulting in the facilitation of significantly enhanced hydrogen generation through the photocatalytic water splitting under the solar-simulated light. The position and distribution of C-doping in the carbon nitride framework are characterized by using advanced analytical techniques such as X-ray photoelectron spectroscopy, near-edge X-ray absorption fine structure spectroscopy, and electron paramagnetic resonance spectroscopy together with the first-principles studies of the electronic structure and energetics of doping. The remarkable increase in photocatalytic hydrogen generation by using developed C-doped carbon nitride brings one step closer to achieving a green hydrogen economy.
Subject: carbon doping; carbon nitride; hydrogen production; photocatalysis; supramolecular self-assembly; SDG 7; SDG 9; SDG 12; Sustainable Development Goals
Identifier: http://hdl.handle.net/1959.13/1509803
Identifier: uon:56311
Identifier: ISSN:1614-6832
Language: eng
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