SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4225499042> ?p ?o ?g. }

Showing items 1 to 100 of ±160 with 100 items per page.

W4225499042 endingPage "2220" @default.
W4225499042 startingPage "2209" @default.
W4225499042 abstract "Nickel oxide (NiO) nanoparticles were formed using the chemical precipitation method. The effect of the calcination process on the structural parameters, optical bandgap, and photocatalytic performance was investigated. The structural characteristics were carried out using X-ray diffraction (XRD), Fourier transforms infrared spectroscopy (FTIR), and scanning electron microscope (SEM). The XRD analysis reveals that the formed NiO crystallized in an fcc crystal structure and the calcination process influences the crystallite size, microstrain, dislocation density, and average surface area. For example, the smallest and largest particle sizes (19.13 nm and 27.63 nm) were achieved for the samples prepared at 800 °C for 4 h and 900 °C for 2 h, respectively. Based on the diffuse reflectance spectroscopy analysis, the energy bandgap has the lowest values (3.33 eV) for the prepared NiO that calcinated at 800 °C for 2 h compared with other samples. The formation of a Ni–O stretching vibration mode is revealed by FTIR, and the broadness of the absorption band confirms that the NiO samples are nanocrystals. The morphology of the prepared NiO reveals the formation of spherical nanoparticles for NiO calcinated at 700 °C, while dodecahedron-like shapes were observed for NiO calcinated at 800 and 900 °C. The photocatalytic performance of NiO nanoparticles as catalysts for the degradation of indigo carmine dye was investigated under ultraviolet–visible irradiation up to 3 h. The best degradation efficiency was found to be 76% for NiO calcinated at 800 °C for 4 h, which belonged to the smallest crystallite size of 19.13 nm, and the highest surface area of 47.02 m2 g−1. The superior and excellent performance of this sample compared to other samples was confirmed by achieving the highest reaction rate constant (4.51 × 10−3 min−1). The proposed photodegradation mechanism shows the importance of increasing the time required for the recombination process between the positive holes and the excited electrons, which is the best possible when using the optimum photocatalyst sample that was prepared at 800 °C for 4 h." @default.
W4225499042 created "2022-05-05" @default.
W4225499042 creator A5011796882 @default.
W4225499042 creator A5014006816 @default.
W4225499042 creator A5020895631 @default.
W4225499042 creator A5026207503 @default.
W4225499042 creator A5045452431 @default.
W4225499042 creator A5059115034 @default.
W4225499042 date "2022-03-16" @default.
W4225499042 modified "2023-10-16" @default.
W4225499042 title "Thermal-Induced Effects on the Structural and Photocatalytic Properties of Nickel Oxide Nanoparticles for Indigo Carmine Dye Removal" @default.
W4225499042 cites W1609950518 @default.
W4225499042 cites W1963902583 @default.
W4225499042 cites W1979198258 @default.
W4225499042 cites W1982120982 @default.
W4225499042 cites W1982639668 @default.
W4225499042 cites W1993591690 @default.
W4225499042 cites W1995646472 @default.
W4225499042 cites W1999970590 @default.
W4225499042 cites W2007868549 @default.
W4225499042 cites W2031606847 @default.
W4225499042 cites W2044343929 @default.
W4225499042 cites W2045117816 @default.
W4225499042 cites W2052413866 @default.
W4225499042 cites W2057484061 @default.
W4225499042 cites W2060429741 @default.
W4225499042 cites W2065139675 @default.
W4225499042 cites W2068804185 @default.
W4225499042 cites W2076674413 @default.
W4225499042 cites W2086290196 @default.
W4225499042 cites W2114450502 @default.
W4225499042 cites W2147193630 @default.
W4225499042 cites W2289575450 @default.
W4225499042 cites W2417850334 @default.
W4225499042 cites W2609774438 @default.
W4225499042 cites W2790478711 @default.
W4225499042 cites W2791945475 @default.
W4225499042 cites W2799935603 @default.
W4225499042 cites W2809580262 @default.
W4225499042 cites W2887475994 @default.
W4225499042 cites W2890016613 @default.
W4225499042 cites W2890206834 @default.
W4225499042 cites W2892017031 @default.
W4225499042 cites W2896035458 @default.
W4225499042 cites W2902833313 @default.
W4225499042 cites W2904793139 @default.
W4225499042 cites W2905766031 @default.
W4225499042 cites W2954556586 @default.
W4225499042 cites W2954987932 @default.
W4225499042 cites W2965919592 @default.
W4225499042 cites W2970591540 @default.
W4225499042 cites W2990924428 @default.
W4225499042 cites W2992734329 @default.
W4225499042 cites W2996659290 @default.
W4225499042 cites W2999633082 @default.
W4225499042 cites W3000531483 @default.
W4225499042 cites W3005192711 @default.
W4225499042 cites W3013046662 @default.
W4225499042 cites W3042306864 @default.
W4225499042 cites W3046660240 @default.
W4225499042 cites W3089103483 @default.
W4225499042 cites W3134498678 @default.
W4225499042 cites W3159740672 @default.
W4225499042 cites W3159889239 @default.
W4225499042 cites W3162651607 @default.
W4225499042 cites W3184677078 @default.
W4225499042 cites W3194830223 @default.
W4225499042 cites W3201489853 @default.
W4225499042 cites W3204265606 @default.
W4225499042 cites W3207149197 @default.
W4225499042 cites W3209235348 @default.
W4225499042 cites W3213524501 @default.
W4225499042 cites W4200083900 @default.
W4225499042 cites W4206134005 @default.
W4225499042 cites W4206464841 @default.
W4225499042 cites W4212773790 @default.
W4225499042 doi "https://doi.org/10.1007/s10904-022-02277-1" @default.
W4225499042 hasPublicationYear "2022" @default.
W4225499042 type Work @default.
W4225499042 citedByCount "3" @default.
W4225499042 countsByYear W42254990422022 @default.
W4225499042 countsByYear W42254990422023 @default.
W4225499042 crossrefType "journal-article" @default.
W4225499042 hasAuthorship W4225499042A5011796882 @default.
W4225499042 hasAuthorship W4225499042A5014006816 @default.
W4225499042 hasAuthorship W4225499042A5020895631 @default.
W4225499042 hasAuthorship W4225499042A5026207503 @default.
W4225499042 hasAuthorship W4225499042A5045452431 @default.
W4225499042 hasAuthorship W4225499042A5059115034 @default.
W4225499042 hasBestOaLocation W42254990422 @default.
W4225499042 hasConcept C113196181 @default.
W4225499042 hasConcept C127413603 @default.
W4225499042 hasConcept C137637335 @default.
W4225499042 hasConcept C13965031 @default.
W4225499042 hasConcept C155672457 @default.
W4225499042 hasConcept C156328458 @default.
W4225499042 hasConcept C159985019 @default.
W4225499042 hasConcept C160892712 @default.