A Coupled Thermal Desorption Process for Decontamination of Polycyclic Aromatic Hydrocarbon from Soil: Important Role of the Steam Injection

Thermal desorption (TD) has been widely used for remediation of soils contaminated with volatile/semi-volatile contaminants. There is a need to reduce the temperature of TD technology to minimize energy consumption and soil damage. The effect of low-temperature TD coupled with steam injection (SI) o...

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Bibliographic Details
Published in:Water, air, and soil pollution air, and soil pollution, 2023-10, Vol.234 (10), p.642-642, Article 642
Main Authors: Ye, Chunmei, Sima, Jingke, Zhou, Dong, Chen, Yaojun, Yang, Jie, Yan, Yuwei
Format: Article
Language:English
Subjects:
air
Aromatic compounds
Aromatic hydrocarbons
Atmospheric Protection/Air Quality Control/Air Pollution
Boiling points
Climate Change/Climate Change Impacts
Contaminants
Decontamination
Desorption
Distillation
Earth and Environmental Science
energy
Energy consumption
Environment
Environmental monitoring
Flow rates
Flow velocity
Hydrogeology
Injection
Low temperature
Physicochemical processes
Physicochemical properties
Polycyclic aromatic hydrocarbons
Remediation
Removal
Soil
Soil contamination
Soil investigations
Soil pollution
Soil properties
Soil remediation
Soil Science & Conservation
Soil temperature
Soils
steam
Steam distillation
Steam flow
Stripping (distillation)
temperature
water
Water Quality/Water Pollution
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Summary:Thermal desorption (TD) has been widely used for remediation of soils contaminated with volatile/semi-volatile contaminants. There is a need to reduce the temperature of TD technology to minimize energy consumption and soil damage. The effect of low-temperature TD coupled with steam injection (SI) on the remediation of PAH-contaminated soil was investigated in this study. It was shown that the addition of SI to the TD at both 150 and 250 °C improved the removal of LPAHs from soil, with better performance at 150 °C, especially for LPAHs with boiling points between 295 and 340 °C. In contrast, the addition of SI to the TD at both 150 and 250 °C reduced the removal of HPAHs from soil, particularly at 250 °C. Under TD at 150 °C, the removal of LPAHs and HPAHs were further promoted and limited with increasing SI flow rates, respectively. It was noted that the introduction of steam in the low-temperature TD only promoted the removal of LPAHs, and the effect was better with higher steam flow rate. The addition of 4 g/min steam to TD at 150 °C could accelerate 259.18% of the removal process of LPAHs, and could improve the removal of LPAHs by 17.88% while reducing the energy consumption by 29.18%. This promotion is likely attributed to the fact that the introduced steam facilitates the release of LPAHs inside the soil matrix through steam replacement, steam distillation, and stripping. In addition, the addition of SI to the TD has little effect on soil physicochemical properties.
ISSN:0049-6979
1573-2932
DOI:10.1007/s11270-023-06659-0