Aggregation and deposition behaviors of dissolved black carbon with coexisting heavy metals in aquatic solution

The aggregation and deposition behaviors of colloidal or dissolved black carbon (DBC) with coexisting heavy metals are important to understand the fate of DBC and the associated contaminants in environmental and engineering systems. Time-resolved dynamic light scattering (DLS) and quartz crystal mic...

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Bibliographic Details
Published in:Environmental science. Nano 2020-09, Vol.7 (9), p.2773-2784
Main Authors: Xu, Yanghui, Ou, Qin, Liu, Caihong, Zhou, Xiaojun, He, Qiang, Wu, Zhengsong, Huang, Ruixing, Ma, Jun, Lu, Dongming, Huangfu, Xiaoliu
Format: Article
Language:English
Subjects:
Agglomeration
Aggregation
Aggregation behavior
Black carbon
Cadmium
Carbon
Cations
Cleaning
Coagulation
Contact angle
Contaminants
Copper
Deposition
Destabilization
Electronegativity
Frequency shift
Heavy metals
Kinetics
Lead
Light scattering
Metal concentrations
Metal ions
Metals
Microbalances
Photon correlation spectroscopy
Profiles
Properties
Quartz crystal microbalance
Quartz crystals
Rigidity
Silica
Silicon dioxide
Surface roughness
Viscoelasticity
Zinc
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Summary:The aggregation and deposition behaviors of colloidal or dissolved black carbon (DBC) with coexisting heavy metals are important to understand the fate of DBC and the associated contaminants in environmental and engineering systems. Time-resolved dynamic light scattering (DLS) and quartz crystal microbalance with dissipation (QCM-D) techniques were employed to study the effect of cation concentration and properties on the aggregation and deposition behaviors of DBC with divalent heavy metals (Pb 2+ , Cu 2+ , Cd 2+ and Zn 2+ ). The aggregation experiments suggested that divalent heavy metals significantly destabilized DBC due to strong complexation and cation-π interaction, and the destabilization ability of these metal cations was related to their electronegativity (critical coagulation concentration (CCC): Pb 2+ < Cu 2+ < Cd 2+ < Zn 2+ ). The deposition experiments indicated that the presence of heavy metals favored the deposition of DBC on a silica surface, which was characterized by a relatively rigid layer in the initial rapid phase and a relatively swollen layer in the subsequent slow phase. Additionally, the initial deposition rate first increased as the cation concentration increased, while a further increase in cation concentration was unfavorable to the deposition process because of the diffusion limitation. Similarly, the deposited film was more rigid at first and then became more swollen with the increase in cation concentration. Notably, the electronegativity of the metal cation dominated its retention ability (critical deposition concentration (CDC): Pb 2+ < Cu 2+ < Cd 2+ < Zn 2+ ) and surface roughness, while the hydration shell thickness had a greater influence on the viscoelastic properties of the deposited film (rigidity of the adlayer: Pb 2+ > Cd 2+ > Cu 2+ > Zn 2+ ). Overall, these results provide new insights into the aggregation and deposition behaviors of DBC with coexisting heavy metals in aquatic solution, which are helpful to understand the fate of DBC and the associated contaminants. Existing heavy metals promoted aggregation and deposition of dissolved black carbon, which was related to the physicochemical properties of the metal cations.
ISSN:2051-8153
2051-8161
DOI:10.1039/d0en00373e