SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2890214554> ?p ?o ?g. }

Showing items 1 to 100 of ±139 with 100 items per page.

W2890214554 endingPage "219" @default.
W2890214554 startingPage "209" @default.
W2890214554 abstract "Simultaneously exploration control of energy band, layer structure and vacancy defect of semiconductor photocatalysts for hydrogen (H2) evolution is highly desirable. For this purpose, the ultrathin graphitic carbon nitride (ug-C3N4) are prepared by intercalated hydrogen bond effect of NO3− for the first time reported. More importantly, the thickness, band gap energy, specific surface area and nitrogen vacancy intensity of ug-C3N4 nanosheets can be controlled by the concentration of NO3− in the inserted layer. The method not only endow ug-C3N4 nanosheets with super large specific surface area and nitrogen vacancy-rich that provide more active sites and speed up the photogenerated charge transfer, but also possess suitable conduction band position and thus more conducive to H2 production. The photocatalytic performance of ug-C3N4 for H2 evolution (836.3 µmol h−1 g−1) and 2-Mercaptobenzothiazole (MBT) decomposition (84%) is significantly enhanced by energy band, layer structure and vacancy defect optimization, which is over 4.0 and 1.75 times higher than the bulk g-C3N4 powder. We firmly believe that the work emblems a significant step toward control engineering for energy conversion and environmental pollution." @default.
W2890214554 created "2018-09-27" @default.
W2890214554 creator A5026729203 @default.
W2890214554 creator A5036009400 @default.
W2890214554 creator A5049392486 @default.
W2890214554 creator A5049470806 @default.
W2890214554 creator A5067453012 @default.
W2890214554 creator A5072279396 @default.
W2890214554 date "2019-02-01" @default.
W2890214554 modified "2023-10-16" @default.
W2890214554 title "Control of energy band, layer structure and vacancy defect of graphitic carbon nitride by intercalated hydrogen bond effect of NO3− toward improving photocatalytic performance" @default.
W2890214554 cites W1799122600 @default.
W2890214554 cites W1980732115 @default.
W2890214554 cites W1987020734 @default.
W2890214554 cites W2032993878 @default.
W2890214554 cites W2039475059 @default.
W2890214554 cites W2068543957 @default.
W2890214554 cites W2150399639 @default.
W2890214554 cites W2154903153 @default.
W2890214554 cites W2155178633 @default.
W2890214554 cites W2175097192 @default.
W2890214554 cites W2308330784 @default.
W2890214554 cites W2323399532 @default.
W2890214554 cites W2335215450 @default.
W2890214554 cites W2346275953 @default.
W2890214554 cites W2372330921 @default.
W2890214554 cites W2517141693 @default.
W2890214554 cites W2551976551 @default.
W2890214554 cites W2560950409 @default.
W2890214554 cites W2561499528 @default.
W2890214554 cites W2565734233 @default.
W2890214554 cites W2566075050 @default.
W2890214554 cites W2583099004 @default.
W2890214554 cites W2587681799 @default.
W2890214554 cites W2602471652 @default.
W2890214554 cites W2618372515 @default.
W2890214554 cites W2623659532 @default.
W2890214554 cites W2626914227 @default.
W2890214554 cites W2727514335 @default.
W2890214554 cites W2747502172 @default.
W2890214554 cites W2749854658 @default.
W2890214554 cites W2756485744 @default.
W2890214554 cites W2758986219 @default.
W2890214554 cites W2759553275 @default.
W2890214554 cites W2763101436 @default.
W2890214554 cites W2769541174 @default.
W2890214554 cites W2772381290 @default.
W2890214554 cites W2775476355 @default.
W2890214554 cites W2784609487 @default.
W2890214554 cites W2786488721 @default.
W2890214554 cites W2789593134 @default.
W2890214554 cites W2792908185 @default.
W2890214554 cites W2793666122 @default.
W2890214554 cites W2801465106 @default.
W2890214554 cites W2803729797 @default.
W2890214554 cites W2860293067 @default.
W2890214554 doi "https://doi.org/10.1016/j.cej.2018.09.112" @default.
W2890214554 hasPublicationYear "2019" @default.
W2890214554 type Work @default.
W2890214554 sameAs 2890214554 @default.
W2890214554 citedByCount "199" @default.
W2890214554 countsByYear W28902145542018 @default.
W2890214554 countsByYear W28902145542019 @default.
W2890214554 countsByYear W28902145542020 @default.
W2890214554 countsByYear W28902145542021 @default.
W2890214554 countsByYear W28902145542022 @default.
W2890214554 countsByYear W28902145542023 @default.
W2890214554 crossrefType "journal-article" @default.
W2890214554 hasAuthorship W2890214554A5026729203 @default.
W2890214554 hasAuthorship W2890214554A5036009400 @default.
W2890214554 hasAuthorship W2890214554A5049392486 @default.
W2890214554 hasAuthorship W2890214554A5049470806 @default.
W2890214554 hasAuthorship W2890214554A5067453012 @default.
W2890214554 hasAuthorship W2890214554A5072279396 @default.
W2890214554 hasConcept C104779481 @default.
W2890214554 hasConcept C108225325 @default.
W2890214554 hasConcept C114221277 @default.
W2890214554 hasConcept C127413603 @default.
W2890214554 hasConcept C140205800 @default.
W2890214554 hasConcept C159985019 @default.
W2890214554 hasConcept C161790260 @default.
W2890214554 hasConcept C171250308 @default.
W2890214554 hasConcept C178790620 @default.
W2890214554 hasConcept C181966813 @default.
W2890214554 hasConcept C185592680 @default.
W2890214554 hasConcept C192562407 @default.
W2890214554 hasConcept C194760766 @default.
W2890214554 hasConcept C2778835725 @default.
W2890214554 hasConcept C2779227376 @default.
W2890214554 hasConcept C42360764 @default.
W2890214554 hasConcept C49040817 @default.
W2890214554 hasConcept C512968161 @default.
W2890214554 hasConcept C65165184 @default.
W2890214554 hasConcept C8010536 @default.
W2890214554 hasConceptScore W2890214554C104779481 @default.
W2890214554 hasConceptScore W2890214554C108225325 @default.
W2890214554 hasConceptScore W2890214554C114221277 @default.
W2890214554 hasConceptScore W2890214554C127413603 @default.