Your search keyword '"Sun, Yuanyuan"' showing total 2 results

1. A comparative study of DNAPL migration and transformation in confined and unconfined groundwater systems.

Author

Shi, Junxiang, Chen, Xiaohui, Ye, Bo, Wang, Zhewen, Sun, Yuanyuan, Wu, Jichun, and Guo, Hongyan

Subjects

*GROUNDWATER, *GROUNDWATER pollution, *HAZARDOUS waste sites, *MULTIPHASE flow, *COMPARATIVE studies

Abstract

• Development of a novel device and method for studying multiphase migration and transformation of organic pollutants. • Comparative analysis of DNAPL multiphase migration and transformation in unconfined and confined groundwater systems. • Validation of experimental results through numerical simulation of contaminated site. To explore the migration and transformation process of dense non-aqueous liquid (DNAPL) pollutants' multiphase flow, specifically nitrobenzene (NB), in confined groundwater (CG) versus unconfined groundwater (UG), a two-dimensional sandbox experimental device was designed and constructed. This involved constructing a vadose zone-UG- aquitard-CG structure, which was then subjected to different scenarios. Real-time analysis and numerical simulation methods were established and employed, with a particular focus on the detailed investigation results of actual contaminated site. The study found that when the same amount of NB was injected, the special structure of the CG layer resulted in a more pronounced reverse diffusion of NB in both the dissolved and NAPL phases. This was especially true for the dissolved phase, which was more likely to diffuse reversely. Meanwhile, CG did not directly interact with the vadose zone, and there was no loss of gas phase NB after the leakage in CG. As a result, higher concentrations of dissolved phase NB were generated, leading to the emergence of a larger area of NB contaminant plumes with CG flow. Importantly, the simulation study of the actual site and the laboratory experimental results were found to be validated, further validating the conclusion that direct leakage of NB into CG results in a higher concentration and larger area of dissolved phase contaminant plume, causing more serious pollution to the groundwater environment. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

2. Application of spectral induced polarization for characterizing surfactant-enhanced DNAPL remediation in laboratory column experiments.

Author

Deng, Yaping, Shi, Xiaoqing, Zhang, Zhenyu, Sun, Yuanyuan, Wu, Jichun, and Qian, Jiazhong

Subjects

*INDUCED polarization, *GROUNDWATER remediation, *ANALYTICAL chemistry, *SOIL pollution, *PORE water

Abstract

The widespread presence of entrapped dense non-aqueous phase liquid (DNAPL) in the subsurface poses a continuing challenge to groundwater remediation. Cost-effective and high-resolution subsurface characterization is a critical issue for further DNAPL recovery due to the complexity of DNAPL source zone architecture (SZA). Geophysical techniques provide a noninvasive, spatially continuous and cost-effective way for monitoring the DNAPL remediation process. In particular, the spectral induced polarization (SIP) method has shown great potential in environmental problems. In this study, we performed real-time SIP measurements on DNAPL contaminated soil in columns to quantitatively assess the ability of SIP method for monitoring surfactant-enhanced DNAPL remediation process. Chemical data was simultaneously collected during the remediation process to verify the results obtained by SIP method. Taking account into the variations of subsurface environment, we conducted a series of column flushing experiments under different flow rate, surfactant concentrations and fluid salinities. The results highlight that SIP method is able to effectively monitor the DNAPL remediation process, as well as to evaluate the remediation efficiency under different conditions. The variations in the flow rate, the concentration of surfactant and the salinity of pore water not only affect remediation effectiveness, but also have an impact on the SIP signatures. This study shows that SIP performs better for monitoring DNAPL remediation at a relatively low flow rate of ~ 0.4 m/d, low surfactant concentration of 5000 mg/L and high salinity of 1.0 S/m, with an error of saturation estimation (RMSE S) <0.1. • The SIP method was effectively applied to monitor the surfactant-enhanced DNAPL remediation process in column experiments. • The in-phase conductivity increases while the phase decreases during the continuous surfactant flushing. • The DNAPL saturation and remediation efficiency estimated by SIP method was in good accordance with the chemical analysis. • The SIP method performs better under the condition of low flow rate, low surfactant concentration and high fluid salinity. [ABSTRACT FROM AUTHOR]

Published

2020