Tunable synthesis of cage-like Co3O4/N–C composite and nest-like Co3O4 for oxidative degradation of Bisphenol A

The ZIF-67 crystals synthesized in anhydrous ethanol were directly calcined in air to obtain cage-like Co3O4/nitrogen doped carbon (Co3O4/N–C) composite and nest-like Co3O4 aggregate, respectively, by mediating the calcination temperature in air. The structure of the calcined samples was investigate...

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Published inJournal of solid state chemistry Vol. 304; p. 122550
Main Authors Bai, Lei, He, Jiaxin, Liu, Lei, Guan, Zhongyue, Wang, Guiling
Format Journal Article
LanguageEnglish
Published Elsevier Inc 01.12.2021
Subjects
Bisphenol A
Cage-like Co3O4
Catalytic oxidation
Cobalt organic framework
Bisphenol A
Cage-like Co3O4
Catalytic oxidation
Cobalt organic framework
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Abstract The ZIF-67 crystals synthesized in anhydrous ethanol were directly calcined in air to obtain cage-like Co3O4/nitrogen doped carbon (Co3O4/N–C) composite and nest-like Co3O4 aggregate, respectively, by mediating the calcination temperature in air. The structure of the calcined samples was investigated by X-ray diffraction, electron microscope, X-ray Photoelectron Spectroscopy and so on. It was suggested that the existence of N doped carbon in the cage-like Co3O4 was received at lower temperature. The two nanocrystals were employed as catalysts for the oxidative degradation of Bisphenol A (BPA) in the presence of persulfate and the results indicated that the cage-like Co3O4/N–C with a degradation rate of 0.053 min−1, having a smaller particle size and synergistic effect of Co3O4 with nitrogen-doped carbon, demonstrated a higher persulfate activation and reusability for the degradation of BPA compared with the degradation rate (0.017 min−1) of nest-like Co3O4. The present study could provide new insights for the application of metal organic frameworks to synthesize composite nanomaterials for environmental purpose. Cage-like Co3O4/N–C and nest-like Co3O4 was synthesized for the oxidative degradation of Bisphenol A. The degradation rate over cage-like Co3O4/N–C with a smaller particle size and synergistic effect of Co3O4 with nitrogen-doped carbon was about three-fold higher than nest-like Co3O4. [Display omitted] 1)Cage-like Co3O4/N–C and nest-like Co3O4 were synthesized.2)Co3O4/N–C displayed a three-fold higher activity for Bisphenol A degradation compared with Co3O4.3)The enhanced performance was due to the smaller size and synergistic effect of Co3O4 with nitrogen-doped carbon.
AbstractList The ZIF-67 crystals synthesized in anhydrous ethanol were directly calcined in air to obtain cage-like Co3O4/nitrogen doped carbon (Co3O4/N–C) composite and nest-like Co3O4 aggregate, respectively, by mediating the calcination temperature in air. The structure of the calcined samples was investigated by X-ray diffraction, electron microscope, X-ray Photoelectron Spectroscopy and so on. It was suggested that the existence of N doped carbon in the cage-like Co3O4 was received at lower temperature. The two nanocrystals were employed as catalysts for the oxidative degradation of Bisphenol A (BPA) in the presence of persulfate and the results indicated that the cage-like Co3O4/N–C with a degradation rate of 0.053 min−1, having a smaller particle size and synergistic effect of Co3O4 with nitrogen-doped carbon, demonstrated a higher persulfate activation and reusability for the degradation of BPA compared with the degradation rate (0.017 min−1) of nest-like Co3O4. The present study could provide new insights for the application of metal organic frameworks to synthesize composite nanomaterials for environmental purpose. Cage-like Co3O4/N–C and nest-like Co3O4 was synthesized for the oxidative degradation of Bisphenol A. The degradation rate over cage-like Co3O4/N–C with a smaller particle size and synergistic effect of Co3O4 with nitrogen-doped carbon was about three-fold higher than nest-like Co3O4. [Display omitted] 1)Cage-like Co3O4/N–C and nest-like Co3O4 were synthesized.2)Co3O4/N–C displayed a three-fold higher activity for Bisphenol A degradation compared with Co3O4.3)The enhanced performance was due to the smaller size and synergistic effect of Co3O4 with nitrogen-doped carbon.
ArticleNumber 122550
Author Bai, Lei
He, Jiaxin
Wang, Guiling
Liu, Lei
Guan, Zhongyue
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crossref_primary_10_1007_s10971_022_05834_9
crossref_primary_10_1016_j_jssc_2023_124409
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Keywords Bisphenol A
Cage-like Co3O4
Catalytic oxidation
Cobalt organic framework
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Snippet The ZIF-67 crystals synthesized in anhydrous ethanol were directly calcined in air to obtain cage-like Co3O4/nitrogen doped carbon (Co3O4/N–C) composite and...
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StartPage 122550
SubjectTerms Bisphenol A
Cage-like Co3O4
Catalytic oxidation
Cobalt organic framework
Title Tunable synthesis of cage-like Co3O4/N–C composite and nest-like Co3O4 for oxidative degradation of Bisphenol A
URI https://dx.doi.org/10.1016/j.jssc.2021.122550
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