Combined effects of aqueous suspensions of fullerene and humic acid on the availability of polycyclic aromatic hydrocarbons: Evaluated with negligible depletion solid-phase microextraction

The wide application of engineered carbon nanomaterials, such as fullerene (C₆₀), will inevitably result in their introduction into the aqueous environment. Interactions of C₆₀ with abundant natural organic matter (NOM) will likely alter the bioavailability of organic compounds to aquatic organisms. The availability of 12 types of polycyclic aromatic hydrocarbons (PAHs) in various aqueous suspensions of fullerene (nC₆₀) prepared by different methods, e.g., in humic acid (HA) and particularly in combined systems of nC₆₀ and HA, was investigated by negligible depletion solid-phase microextraction (nd-SPME). The results showed that HA accelerated the rate constants (k₂) of almost all PAH uptakes to the nd-SPME fibers compared with the solutions without the matrix; the combined matrices of nC₆₀ and HA significantly promoted the k₂ of highly hydrophobic PAHs (logK_OW 5.81-6.20), whereas they retarded that of less hydrophobic ones (logK_OW 3.82-4.63) (p<0.05). Remarkable or minor reduction of free concentration of PAH was observed in the combined system of nC₆₀ and HA depending on the properties of individual PAHs. Sorption coefficients (K_HA, K_C60 and K_C60+HA) of various PAHs in different matrices were provided, and matrix concentrations showed no significant effects. For highly hydrophobic PAHs (logK_OW 5.16-6.20), the logK_C60+HA>=logK_HA>logK_C60, whereas for less hydrophobic PAHs (logK_OW 3.8-4.63), the K_matrix values in various matrices showed no noticeable trend. In addition, higher K_C60 values were obtained for aqu/nC₆₀ than for son/nC₆₀ for most highly hydrophobic PAHs. The above results suggest that hydrophobicity plays an important role in determining K_matrix in addition to the matrix effects. The interactions between nC₆₀ and HA have critical or minor impacts on availability, and thus bioavailability, of PAHs. This paper contributes to the understanding of the bioavailability mechanisms of organic pollutants in the aquatic environment with both nC₆₀ and NOM.