The polymer tested in SOLFORPLAS, polyethylene, has been successfully pre-degraded using physico-chemical treatments, which are in addition environmentally friendly. These excluded the extruder technology for the moment, which was found to induce changes in the polymer structure only at extremely high temperatures, representing thus a less sustainable alternative. The physico-chemical treatments finally applied successfully reduced the molecular weight and increased the carbonyl index (oxidation) of the polymer, indicating that its long carbon chains were effectively broken down, and its chemical structure oxidized. Scanning Electron Microscopy (SEM) images revealed clear fissures in this pre-treated material, providing a detailed characterization of such an early degradation process. This represents a crucial milestone within the Project SOLFORPLAS, since no microorganism can degrade polyethylene by itself, unless the polymer is previously pretreated before exposed to the microorganisms.
We next characterized the biological degradation of polyethylene, by screening in vitro 32 microorganism(s) including bacteria, yeasts and fungi. Based on our results, yeasts represented the best candidates for polymer degradation. In particular, five yeasts were particularly promising, notable for their ability to degrade lipids and grow on n-paraffins as sole carbon source. All the analyzed parameters confirmed that these yeasts survived in the presence of polyethylene as the sole carbon source for a month, preferring the pre-treated material than the non-modified polyethylene. Although we did not detect a reduced molecular weight or a modified FTIR spectra of the polymer, yeast adhesion to the non-modified and especially to the modified polyethylene was observed by fluorescence microscopy and SEM. More importantly, this attachment led to small but significant losses in absolute plastic weight.