All Organic S-Scheme Heterojunction PDI-Ala/S-C₃N₄ Photocatalyst with Enhanced Photocatalytic Performance

Abstract: Organic photocatalysts have attracted attention owing to their suitable redox band positions, low cost, high chemical stability, and good tunability of their framework and electronic structure. As a novel organic photocatalyst, PDI-Ala (N,N'-bis(propionic acid)-perylene-3,4,9,10tetracarboxylic diimide) has strong visible-light response, low valence band position, and strong oxidation ability. However, the low photogenerated charge transfer rate and high carrier recombination rate limit its application. Due to … Show more

“…8A). In general, lower PL intensity means efficient charge separation, indicating higher photocatalytic performance [63][64][65] . Since PL intensity of PCNS-CoNiFeP and PCNS is lower than that of CNS, indicating that P doping of CNS and loading of highly dispersed CoNiFeP decrease the recombination of photogenerated electron-hole pairs, due to the improved charge trapping by the introduced P and CoNiFeP cocatalysts as the electron traps.…”

P-Doped g-C₃N₄ Nanosheets with Highly Dispersed Co_0.2Ni_1.6Fe_0.2P Cocatalyst for Efficient Photocatalytic Hydrogen Evolution

“…8A). In general, lower PL intensity means efficient charge separation, indicating higher photocatalytic performance [63][64][65] . Since PL intensity of PCNS-CoNiFeP and PCNS is lower than that of CNS, indicating that P doping of CNS and loading of highly dispersed CoNiFeP decrease the recombination of photogenerated electron-hole pairs, due to the improved charge trapping by the introduced P and CoNiFeP cocatalysts as the electron traps.…”

P-Doped g-C₃N₄ Nanosheets with Highly Dispersed Co_0.2Ni_1.6Fe_0.2P Cocatalyst for Efficient Photocatalytic Hydrogen Evolution

“…Direct Z-scheme heterojunctions are also termed as S-scheme heterojunctions 80 . A direct Z-scheme heterojunction consists of staggered band alignment, with charge transfer mechanism completely different from type II heterojunction 79,81…”

“…80 A direct Z-scheme heterojunction consists of staggered band alignment, with charge transfer mechanism completely different from that of a type II heterojunction. 79,81 The photo-generated electrons in the conduction band of the semiconducting material with a high reduction potential (semiconductor B) and holes in the valence band of the semiconducting material with a high oxidation potential (semiconductor A) are reserved for photocatalytic reactions. 79 When two semiconductors come in close contact, initially the diffusion of electrons occur from semiconductor B possessing a high reduction potential to semiconductor A with a high oxidation potential.…”

Engineering Schottky-like and heterojunction materials for enhanced photocatalysis performance – a review

“…Photocatalysis technology holds enormous potential in addressing environment and energy issues because it converts inexhaustible solar energy into storable chemical energy. [1,2] Specifically, under light irradiation, some redox reactions can occur on the surface of photocatalysts; these reactions include water splitting to hydrogen and oxygen, [3,4] CO 2 reduction to organic fuels, [5][6][7][8] NO removal, [9,10] N 2 fixation, [11][12][13] contaminant degradation, [14,15] bacteria disinfection, [16] and so on. The most common photocatalysts are semiconductors, such as TiO 2 , [17] CdS, [18,19] and graphitic carbon nitride (g-C 3 N 4 ).…”

g‐C₃N₄‐Based 2D/2D Composite Heterojunction Photocatalyst