Effective reducing the mobility and health risk of mercury in soil under thiol-modified biochar amendment

Soil mercury contamination poses health risks. However, effective immobilization techniques are lacking with challenges including low efficiency, limited long-term stability, susceptibility to multi-medium interference, and difficulty in controlling health risks. This study confirmed the feasibility of thiol-modified biochar, and elucidated the underlying mechanisms. Within 32 days of treatment, the leachable mercury decreased from 184.7 μg/L to below the hazardous waste threshold (100 μg/L, HJ/T299-2007, China). After 198 days of treatment, the soil achieved a safe ecological state with a mercury immobilization rate of 79.8-98.2% and a 50% reduction in available methylmercury. Thiol-modified biochar facilitated the conversion of active mercury species (exchangeable, carbonate, and oxide) into stable forms (organic and residual) through complexation and precipitation (e.g., HgS). Soil quality improvements were observed, including enhanced cation exchange capacity, available nitrogen, and total organic carbon. Thiol-modified biochar exhibits long-term effectiveness. After one and two years of treatment, the leachable mercury remained within acceptable health risk limit (hazard quotient < 1) for adults and children, respectively. After three years, the leachable mercury met the Level III groundwater quality standard (< 1 μg/L, GB 14848-2017, China). This study demonstrates an effective strategy for long-term diminishing mercury mobility and health risks in soil. Soil mercury contamination poses a persistent threat to human health, yet the development of efficient and stable passivation materials remains a challenge. The existing immobilization techniques are confronted with challenges such as low efficiency, poor long-term stability, susceptibility to multi-medium interference, and difficulties in controlling health risks. This study confirms the long-term stability of thiol-modified biochar in immobilizing mercury-contaminated soil, effectively mitigating health risks, and elucidates its potential mechanisms. This study demonstrates that thiol-modified biochar effectively diminishes mercury mobility and associated health risks in soil, affirming the viability and sustained effectiveness of this strategy.