2020
DOI: 10.1002/solr.202000440
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Atomic‐ and Molecular‐Level Functionalizations of Polymeric Carbon Nitride for Solar Fuel Production

Abstract: Polymeric carbon nitride (PCN) is a metal‐free semiconductor that has received extensive research attention due to its unique advantages such as low cost, high stability, and visible‐light response. However, pristine PCN is not an ideal photocatalyst because of fast electron–hole recombination and its inert surface for molecular adsorption. Nevertheless, benefiting from the N‐linked tri‐s‐triazine structure, PCN can be readily functionalized through chemical modifications. As such, researchers have made enormo… Show more

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Cited by 18 publications
(7 citation statements)
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“…Some strategies have been applied to regulate the exciton dynamics; for instance, nanostructuring such as forming nanocrystals or quantum dots enhances the multiple exciton generation because of the quantum confinement effect, , and surface plasmon resonance promotes the exciton generation by near-field enhancement and the exciton dissociation via exciton-plasmon coupling . Among them, engineering defects (four main categories according to the dimensions, e.g., the point, line, planar, and volume) has been considered as an effective, comprehensive, and facile way to enhance the performance of photocatalysts, such as increasing light absorption by narrowing the band gap, improving charge transfer and separation via temporarily trapping photogenerated electrons and holes, or maneuvering surface reactions through adsorption and activation of reactant molecules. , In addition, the effect of defects on regulating the exciton dynamics is also explored. , On the positive side, a proper amount of defects in photocatalysts can promote exciton dissociation. , For example, the formation of ordered–disordered chains in the heptazine-based melon (HM) [which is also called polymeric carbon nitride (CN)], which has suitable band structures with the built-in electric field at the abundant ordered–disordered interfaces, can accelerate the exciton dissociation into free electrons and holes and thus effectively enhance the PC performance . Another study shows that the incorporation of oxygen vacancies in the low-dimensional bismuth oxybromide (BiOBr) can promote exciton dissociation because the oxygen vacancies significantly distort the surrounding localization of band-edge states, leading to the instability of excitons .…”
Section: Introductionmentioning
confidence: 99%
“…Some strategies have been applied to regulate the exciton dynamics; for instance, nanostructuring such as forming nanocrystals or quantum dots enhances the multiple exciton generation because of the quantum confinement effect, , and surface plasmon resonance promotes the exciton generation by near-field enhancement and the exciton dissociation via exciton-plasmon coupling . Among them, engineering defects (four main categories according to the dimensions, e.g., the point, line, planar, and volume) has been considered as an effective, comprehensive, and facile way to enhance the performance of photocatalysts, such as increasing light absorption by narrowing the band gap, improving charge transfer and separation via temporarily trapping photogenerated electrons and holes, or maneuvering surface reactions through adsorption and activation of reactant molecules. , In addition, the effect of defects on regulating the exciton dynamics is also explored. , On the positive side, a proper amount of defects in photocatalysts can promote exciton dissociation. , For example, the formation of ordered–disordered chains in the heptazine-based melon (HM) [which is also called polymeric carbon nitride (CN)], which has suitable band structures with the built-in electric field at the abundant ordered–disordered interfaces, can accelerate the exciton dissociation into free electrons and holes and thus effectively enhance the PC performance . Another study shows that the incorporation of oxygen vacancies in the low-dimensional bismuth oxybromide (BiOBr) can promote exciton dissociation because the oxygen vacancies significantly distort the surrounding localization of band-edge states, leading to the instability of excitons .…”
Section: Introductionmentioning
confidence: 99%
“…These results indicate that the structure of DCCN-S becomes disordered and the crystallinity is reduced, probably due to the formation of defect sites. The structure of the samples was also demonstrated by the solid-state 13 C CPMAS-NMR spectra (Fig. S4 †) and FT-IR spectra (Fig.…”
Section: Synthesis Morphology and Structure Of Photocatalystsmentioning
confidence: 74%
“…All binding energies were calibrated using the C 1s peak at 284.8 eV as a reference. The solid-state 13 C cross-polarization magic angle spinning (CP-MAS) nuclear magnetic resonance (NMR) spectra were recorded on an Agilent DD2-500 MHz NMR spectrometer at room temperature. The elemental analysis was performed on a UNICUBE/ OXYCUBE elemental analyzer.…”
Section: Characterizationmentioning
confidence: 99%
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“…An inorganic polymeric semiconductor, C 3 N 4 has attracted enormous interest due to its low cost, high thermal and chemical stability, nitrogen-rich structure, and suitable bandgap (2.7 eV). [92][93][94] In CO 2 reduction, C 3 N 4 -based materials have been employed as photocatalysts [95][96][97] or coupled with metalligand complexes [76][77][78][79][98][99][100][101][102][103][104] to achieve enhanced catalysis. For example, Roy and co-workers 76 deposited cobalt phthalocyanine cyanine on mesoporous C 3 N 4 via a weak p-p stacking interaction for visible-light CO 2 reduction.…”
Section: Deposition Of Co-cyclam On C 3 Nmentioning
confidence: 99%