Fate of polycyclic aromatic hydrocarbons during composting of activated sewage sludge with green waste.

The level and fate of 16 polycyclic aromatic hydrocarbons (PAHs), targeted by the US Environmental Protection Agency (USEPA), has been studied over 90 days of composting of activated sludge with green waste, under a semi-arid climate. The total PAH calculated from the sum of the amounts of the 16 PAHs in the initial mixture of activated sludge and green waste, was lower than accepted European Union cut-off limits by about 0.48mgkg(-1). The treatment by composting led to a decrease of all PAHs mainly in the stabilization phase, but some differences could be observed between PAHs with three or fewer aromatic rings (N< or = 3) and those with four or more (N> or = 4). The former (except phenanthrene) exhibited a continuous decrease, while the latter PAHs with N of four or more and phenanthrene showed increases in the intermediate stages (30-60 days). This indicates the high potential sorption mainly of PAH with high molecular weight (> or = N4) plus phenanthrene, their tight adsorption makes them inaccessible for microbial attack. The high molecular weight PAHs showed a greater reduction of their bioavailability than those of low molecular weight. Naphthalene, with the lowest molecular weight, showed the smallest decrease (about 67.8%) compared to other PAHs of higher molecular weight (decrease reaching 100%). This is in agreement with the fact that the adsorption is less reversible with increased numbers of fused aromatic rings or an increase of their hydrophobicity.

Structural study of the fulvic fraction during composting of activated sludge-plant matter: elemental analysis, FTIR and 13C NMR.

The starting fulvic structures isolated from an initial mixture of activated sludge and plant matter presented abundant peptide structures and hydrocarbons that absorb in FTIR spectra around (1650 and 1560 cm(-1)) and 1072 cm(-1), respectively. They also present a high resonance signal in the O- and N-alkyl areas of (13)C NMR spectra. As composting proceeded, some changes led to the formation of the molecular structures of fulvic fraction as demonstrated by a decrease of intensity of compounds absorbing around 1072 cm(-1) and an increase of those absorbing around 1140 cm(-1). The resonance of O- and N-substituted alkyl carbon also decreased from 55.7% to 33.8%, with an increase in the intensity of aromatic carbons, alkyls and carboxyls. These data indicate that the microbial community that developed during composting used polysaccharides as an energy source, structures which are supplied in abundance in the initial material. The fulvic fraction of the final compost is much richer in aromatic structures and aliphatic ethers/esters, which are most likely preserved from the original material but probably also synthesized through the microbial activities. The occurrence of alkyl ethers/esters at the end of composting is demonstrated by strong absorbance around 1140 cm(-1) in the FTIR spectra and large peaks at 32 and 174 ppm in the NMR spectra. These structures could also be produced following the creation of ether/ester bonds during the humification process.