Per- and poly-fluoroalkyl substance remediation from soil and sorbents: A review of adsorption behaviour and ultrasonic treatment

Per- and poly-fluoroalkyl substances (PFAS) are xenobiotics, present at variable concentrations in soils and groundwater worldwide. Some of the current remediation techniques being researched or applied for PFAS-impacted soils involve solidification-stabilisation, soil washing, excavation and dispos...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2021-11, Vol.282, p.131025-131025, Article 131025
Main Authors: Uriakhil, Mohammad Angaar, Sidnell, Tim, De Castro Fernández, Andrea, Lee, Judy, Ross, Ian, Bussemaker, Madeleine
Format: Article
Language:English
Subjects:
Adsorption
PFAS
Regeneration
Soil remediation
Ultrasound
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Summary:Per- and poly-fluoroalkyl substances (PFAS) are xenobiotics, present at variable concentrations in soils and groundwater worldwide. Some of the current remediation techniques being researched or applied for PFAS-impacted soils involve solidification-stabilisation, soil washing, excavation and disposal to landfill, on site or in situ smouldering, thermal desorption, ball milling and incineration. Given the large volumes of soil requiring treatment, there is a need for a more environmentally friendly technique to remove and treat PFASs from soils. Sorbents such as granular/powdered activated carbon, ion exchange resins and silicas are used in water treatment to remove PFAS. In this work, PFAS adsorption mechanisms and the effect of pore size, pH and organic matter on adsorption efficacy are discussed. Then, adsorption of PFAS to soils and sorbents is considered when assessing the viability of remediation techniques. Sonication-aided treatment was predicted to be an effective removal technique for PFAS from a solid phase, and the effect of varying frequency, power and particle size on the effectiveness of the desorption process is discussed. Causes and mitigation strategies for possible cavitation-induced particle erosion during ultrasound washing are also identified. Following soil remediation, degrading the extracted PFAS using sonolysis in a water-organic solvent mixture is discussed. The implications for future soil remediation and sorbent regeneration based on the findings in this study are given. •PFAS sorb to surfaces mainly due to hydrophobic and electrostatic interactions.•PFAS adsorption is also affected by pore/particle size, and PFAS concentration.•Soil/sorbent washing is viable for PFAS impacted sorbent/soil regeneration.•Ultrasound enhances desorption due to higher temperatures and more mass transfer.•Particle erosion can be controlled by adjusting particle size, power and frequency.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2021.131025