Fig. 9 shows the EDX spectrum from

Fig. 9 shows the EDX spectrum from the scanning electron
microscopy analysis of reminiscent aluminum after depolymerization
of PET by ethanolysis reaction. The peak related to gold is due to
the metallization process before image acquisition. The EDX spectrum
presents two peaks, one at 1.4 keV, attributed to aluminum,
and another at 0.5 keV, related to oxygen, indicating that the thin
layers observed in the micrographs (inserted in Fig. 9) are composed
of aluminum oxide and metallic aluminum. The carbon peak
could be assigned to the polyethylene or residues of PET embedded
at the aluminum surface during delamination process. Fig. 10
shows the XRD pattern of aluminum and the peaks at 2 = 39◦, 43◦,
65◦, 78◦ and 83◦ are characteristics of the cubic structure of metallic
aluminum. The signals at 2 = 32◦, the large signal between 38◦
and 40◦ and the signals at 46◦ and 60◦ refer to the presence of aluminum
oxide [30]. The presence of crystalline polyethylene in the
aluminum surface is confirmed by the signals at 2 = 22◦, 24◦, 36◦
and 55◦ [31,32].
The ethylene glycol (EG) obtained as a product of reaction was
purified by distillation, considering the large difference of boiling
point among the components of reaction medium (ethanol: 78 ◦C;
water: 100 ◦C; ethylene glycol: 197 ◦C). Fig. 11 shows the 1Hspectrum of EG after purification. It can be observed the signal at
 4.2 ppm, regarding to hydroxyl group and the coupling signal
at  3.6 ppm, attributed to the presence of water in the ethylene
glycol sample. Therefore, simple distillation is not enough to completely
remove the water, considering the high solubility among
such components. However, the amount of water present in the
recovered EG after depolymerization reaction does not prevent its
use for applications that do not require high purity, such as liquid
cooling systems.
4. Conclusions
The depolymerization of PET took place by reaction with ethanol
under supercritical conditions. The obtained products in this reaction
are diethyl terephthalate and ethylene glycol. The diethyl
terephthalate is easily obtained through precipitation in water.
On the other hand, ethylene glycol could be purified from ethanol
and water by distillation. The obtained diethyl terephthalate was
of high purity as confirmed by DSC, 1H NMR and 13C NMR.
Therefore, the depolymerization of PET, from multilayer packages,
using ethanol under supercritical conditions has proven to be a
very attractive route, considering the viewpoint of obtaining high
purity products and low time-reaction necessary, once the starting
material is composed of several constituents, and the generated
residues could be easily recovered. Considering the high valueadded
of aluminum and the environmental impact caused by itsinappropriate disposal, the recovery of aluminum-embedded PET
surface by the ethanolysis is extremely advantageous. The PE
obtained during delamination process could be easily recycled by
extrusion. The method can be considered environmentally benign,
since the solvents used (acetone and alcohol) were recovered by
distillation.
Acknowledgements
S. L. Fávaro is grateful to CNPq (Brazil) for her doctoral fellowship.
A. R. Freitas thanks CAPES (Brazil) for the doctoral fellowship.
The authors wish to thank the COMCAP–UEM by the SEM analysis.