1084 / 2024-09-20 11:15:54
Simulation and parameter determination of the net sorption of phenanthrene by sediment particles
Polycyclic aromatic hydrocarbons, Sorption-desorption model, particles, Temperature, Organic carbon content
Session 57 - Contaminants across the marine continuum: behavior, fate and ecological risk assessment
Abstract Accepted
Donglin Yu / ocean university of China
Jie Shi / 中国海洋大学
 The distribution of polycyclic aromatic hydrocarbons (PAHs) in the ocean is affected by the sorption-desorption process of sediment particles. This process is determined by the concentration of PAHs in seawater, water temperature, and organic matter content of sediment particles. Quantitative relationships between the net sorption rates (=the difference of sorption and desorption rates) and these factors have not been established yet and used in PAH transport models. In this study, phenanthrene was chosen as the representative of PAHs. Three groups of experimental data were collected to address the dependence of the net sorption processes on the initial concentration, water temperature, and organic carbon content representing organic matter content. One-site and two-compartment mass-transfer models were tested to represent the experimental data using various parameters. The results showed that the two-compartment mass-transfer model performed better than the one-site mass-transfer model. The parameters of the two-compartment mass-transfer model include the sorption rate coefficients and  (L g-1 min-1), and the desorption rate coefficients  and  (min-1). The parameters at different temperatures and organic carbon contents were obtained by numerical simulations. Linear relationships were obtained between the parameters and water temperature, as well as organic carbon content. ,  and  decreased linearly, while  increased linearly with temperature. ,  and  increased linearly, while  decreased linearly with organic carbon content. The  values between the simulation results based on the relationships and the experimental results reached 0.96-0.99, which supports the application of the model to simulate sorption-desorption processes at different water temperatures and organic carbon contents in a realistic ocean.