A Phytoremediation Efficiency Assessment of Cadmium (Cd)-Contaminated Soils in the Three Gorges Reservoir Area, China.

To investigate the remediation efficiency of different plant species on cadmium (Cd)-contaminated soil, this study conducted a pot experiment with two woody species ( and ) and two herbaceous species ( and ). Soils were collected from an abandoned coal mine and adjacent pristine natural areas within the dam-adjacent section of the Three Gorges Reservoir Area to establish three soil treatment groups: unpolluted soil (T1, 0.18 mg·kg Cd), a 1:1 mixture of contaminated and unpolluted soil (T2, 0.35 mg·kg Cd), and contaminated coal mine soil (T3, 0.54 mg·kg Cd). This study aimed to investigate the growth status of plants, Cd accumulation and translocation characteristics, and the relationship between them and soil environmental factors. Woody plants exhibited significant advantages in aboveground biomass accumulation. Under T3 treatment, the Cd extraction amount of (224.93 mg) increased by about 36 times compared to T1, and the extraction efficiency (6.42%) was significantly higher than other species. Among the herbaceous species, showed the maximum Cd extraction amount (66.26 mg) and extraction efficiency (3.11%) during T2 treatment. While exhibited a trend of increasing extraction amount but decreasing extraction efficiency with increasing concentration. With the exception of under T1 treatment ( = 0.78), the bioconcentration factor was greater than 1 in both woody ( = 1.39-6.42) and herbaceous species ( = 1.39-3.11). However, herbaceous plants demonstrated significantly higher translocation factors ( = 1.58-3.43) compared to woody species ( = 0.31-0.87). There was a significant negative correlation between aboveground phosphorus (P) content and root Cd ( < 0.05), while underground nitrogen (N) content was positively correlated to aboveground Cd content ( < 0.05). Soil total N and available P were significantly positively correlated with plant Cd absorption, whereas total potassium (K) showed a negative correlation. This study demonstrated that woody plants can achieve long-term remediation through biomass advantages, while herbaceous plants, with their high transfer efficiency, are suitable for short-term rotation. In the future, it is suggested to conduct a mixed planting model of woody and herbaceous plants to remediate Cd-contaminated soils in the tailing areas of reservoir areas. This would synergistically leverage the dual advantages of root retention and aboveground removal, enhancing remediation efficiency. Concurrent optimization of soil nutrient management would further improve the Cd remediation efficiency of plants.