The effect of black carbon on the chemical degradability of PCB1 via TENAX desorption technology from the perspective of adsorption states

The effect of black carbon on the chemical degradability of PCB1 via TENAX desorption technology from the perspective of adsorption states

Chemical degradation is one of the crucial methods for the remediation of hydrophobic organic compounds (HOCs) in soil/sediment. The sequestration effect of black carbon (BC) can affect the adsorption state of HOCs, thereby affecting their chemical degradability. Our study focused on the chemical de...

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Bibliographic Details
Published in:Chemosphere (Oxford) Vol. 286; p. 131583
Main Authors: Xu, Weijian, Zhang, Jin, Shen, Yutao, Yu, Hao, Chen, KeZhen, Zhu, Yinghong, Shen, Chaofeng, Lou, Liping
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-01-2022
Subjects:
Desorption
Electron transfer
HOCs
nZVI/Ni
Electron transfer
BC
Desorption
nZVI/Ni
HOCs
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Summary:Chemical degradation is one of the crucial methods for the remediation of hydrophobic organic compounds (HOCs) in soil/sediment. The sequestration effect of black carbon (BC) can affect the adsorption state of HOCs, thereby affecting their chemical degradability. Our study focused on the chemical degradability of 2-Chlorobiphenyl (PCB1) sequestrated on the typical BC (fly ash (FC), soot (SC), low-temperature biochar (BC400) and high-temperature biochar (BC900)) by iron-nickel bimetallic nanomaterials (nZVI/Ni) based on TENAX desorption technology. The results showed that PCB1 adsorbed in various states were simultaneously dechlorinated by nZVI/Ni. Specifically, rapid-desorption-state PCB1 tended to degrade more easily than resistant-desorption-state PCB1. Moreover, the degradation mechanism varied according to the type of BC. In the case of FC and SC, the degradation rate was lower than the desorption rate for the PCB1 in rapid and slow desorption states, and the degradation rate of PCB1 in the resistant desorption state was negligible. The PCB1 on FC and SC was first desorbed from BC and then degraded. However, in terms of BC400 and BC900, the degradation rate was higher than the desorption rate, and the degradation rate of the resistant-desorption-state PCB1 was 1.4 × 10−2 h−1 and 4.1 × 10−2 h−1, respectively. The graphitized structure of BC900 can directly transfer electrons, so more than 90% of the resistant-desorption-state PCB1 could be degraded. In addition, BC may affect the longevity of nZVI/Ni, thereby affecting its degradability. Therefore, the chemical degradability of BC-adsorbed HOCs should be comprehensively evaluated based on the adsorption state and the properties of BC. [Display omitted] •The degradability of PCB1 on BC in different adsorption states was different.•nZVI/Ni could simultaneously degrade PCB1 in various adsorption states.•PCB1 in a rapid desorption state tended to degrade more easily.•The electron transfer effect of BC promoted the degradation of undesorbable PCB1.
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ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2021.131583