Detailed mechanisms of amoxicillin decomposition in supercritical water by ReaxFF reactive molecular dynamics simulation

The abuse of antibiotics in China has aroused widespread concern, and the resistance genes of antibiotics in the natural environment seriously threaten human health. The supercritical water gasification (SCWG) technology is a clean and efficient technology for the treatment of antibiotic wastewater. In this paper, amoxicillin is selected as the representative antibiotic in wastewater, and the detailed mechanisms of amoxicillin decomposition in supercritical water (SCW) are studied by ReaxFF reactive molecular dynamics (MD) simulation. The results show that the decomposition process of amoxicillin in SCW includes carbon ring opening, carbon chain breaking and small molecular compounds conversion. The molecular vibration leads to the breaking of C-N and C-S bonds. The OH radical is vital to the ring opening of benzene ring and the breaking of carbon chain. However, the yield of NO increases with increasing OH radical concentrations. The ReacNetGenerator tool is used for the first time to analyze the migration path of nitrogen and sulfur in the SCWG system. It shows that H2 has a great effect on the transformation of sulfur, and OH radicals dominate the transformation of nitrogen. Decreasing the reaction time and the concentration of OH radicals result in inhibiting the NO production. This study will provide a theoretical guidance for understanding SCWG process of antibiotic-containing wastewater.

Automated summary

This study investigates the decomposition mechanisms of amoxicillin in supercritical water through molecular dynamics simulation. The results show that amoxicillin undergoes carbon ring opening, carbon chain breaking, and small molecular compound conversion in supercritical water. The OH radical plays a vital role in the decomposition process.