Co3O4 anchored on sepiolite surface grooves for superior adsorption of tetracycline from wastewater

Co3O4 anchored on sepiolite surface grooves for superior adsorption of tetracycline from wastewater

[Display omitted] •Co3O4-Sep was synthesized by co-precipitation and calcination method.•Co3O4 was demonstrated to be anchored on grooves on sepiolite surface, and does not enter the internal channel of sepiolite.•Adsorbent exhibits ultra-high adsorption behavior to tetracycline with 219.53 mg/g.•Co...

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Bibliographic Details
Published in:Separation and purification technology Vol. 323; p. 124367
Main Authors: Zhao, Ning, Ma, Qiyi, Wei, Yanfu, Wang, Shun, Zhong, Xuemin, Zhuang, Guanzheng, Yuan, Peng
Format: Journal Article
Language:English
Published: Elsevier B.V 15-10-2023
Subjects:
Adsorption
Co3O4
Sepiolite
Surface complexation
Tetracycline
Adsorption
Sepiolite
Surface complexation
Co3O4
Tetracycline
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Summary:[Display omitted] •Co3O4-Sep was synthesized by co-precipitation and calcination method.•Co3O4 was demonstrated to be anchored on grooves on sepiolite surface, and does not enter the internal channel of sepiolite.•Adsorbent exhibits ultra-high adsorption behavior to tetracycline with 219.53 mg/g.•Co3O4 is a critical adsorption factor for TC due to surface complexation. Due to the low valence band maximum value, Co3O4 is an outstanding catalyst, but its utilization in adsorption needs to be addressed. In this study, we proposed a novel method for loading aggregation-prone Co3O4 onto sepiolite (Sep) to facilitate tetracycline (TC) adsorption. The XRD, TEM, and FTIR analyses demonstrated that the highly dispersed Co3O4 was successfully anchored on the sepiolite grooves via the Si-OH on the sepiolite surface’s grooves to the cobalt site in Co3O4. We firstly proposed a view of how metal oxide aggregates are confined to the grooves on the surface of sepiolite (via Si-OH at the edges of the grooves on the sepiolite surface). The ultra-high sorption capacity of Co3O4-Sep is 219.53 mg/g for TC, which is three times that of Sep (70.75 mg/g) and Co3O4 (85.29 mg/g). The kinetic and isotherm results fitting suggested that the adsorption of TC on Co3O4-Sep mainly contributed to the multilayer chemisorption adsorption process. Thermodynamic investigations revealed the spontaneous endothermic reaction of TC adsorption on Co3O4-Sep. Co3O4 strengthened the complexation between the composite and functional groups of TC, significantly increasing TC adsorption capacity. In addition, the Co3O4-Sep retained an extraordinary adsorption capacity with the presence of competing ions, at strongly acidic and alkaline pH values and after three cycles. Therefore, this study offers new perspectives on applying cobalt-based materials and demonstrates the potential for antibiotic adsorption in the prepared composites.
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2023.124367