Fast pyrolysis as an alternative to the valorization of olive mill wastes.

BACKGROUND: The valorization of organic wastes through fast pyrolysis appears to be a highly promising option for decreasing pollutants and reducing consumption of natural resources. For this purpose, three different olive pomace samples were studied to determine how olive crop location and the extraction process could influence bio-oil product distribution. Olive pomace was selected as the feedstock due to the importance of the olive oil industry in Spain. RESULTS: In this study, the conditions of fast pyrolysis were optimized using lignin as a reference, with the optimum conditions being 500 °C, 20 °C ms-1 as the heating rate and 15 s as the vapour residence time. The olive pomace results determined that not only their chemical composition, but also their fat content had a remarkable effect on product distribution obtained after fast pyrolysis. However, whereas high lignin content enhanced phenol production, cellulose decomposed to carboxylic acids. In addition, due to current global warming, the carbon dioxide (CO2 ) burden of the three samples was calculated using mass spectroscopy. The OPGC sample gave off the lowest amount of greenhouse gases, followed by OPMNE and OPMN. CONCLUSIONS: The higher fat content in the sample enhanced carboxylic acid production. The difference in phenol production between OPMN and OPMNE could be attributed to the presence of potassium. From an environmental point of view, the use of olive pomace wastes could reduce CO2 emissions with further research and by developing experimental processes. © 2020 Society of Chemical Industry.

Utilization and reusability of hydroxyethyl cellulose alumina based aerogels for the removal of spilled oil.

Nowadays millions of oil tons are spilled into the environment causing important damage. Therefore, the development of new technologies and materials are needed to remediate this problem. In this study, hydroxyethyl cellulose alumina-based aerogels are synthesized by an environmentally friendly freeze-drying process to be used as sorbents for oil spills. It is demonstrated that the oil retention coefficient depends on the viscosity of the oil and the amount of hydroxyethyl cellulose contained in the aerogel, being 10% the optimal proportion. The aerogel synthetized with this content of hydroxyethyl cellulose displays the most favourable physicochemical and morphological properties to retain different oil spills, achieving 5.5 times its weight in comparison to its dry state. In addition, reusability experiments washing the aerogel with acetone or ethanol after the oil retention are carried out. Results show an improvement after a long washing of the sorbent with acetone, resulting in an oil weight gain of 38.7%.