González, CarlosPariente, María IsabelMolina, RaúlEspina, L.G.Masa, MaríaBernal, VicenteMelero, Juan AntonioMartinez, Fernando2023-10-042023-10-042023C. González, M.I. Pariente, R. Molina, L.G. Espina, M.O. Masa, V. Bernal, J.A. Melero, F. Martínez, Increasing biodegradability of a real amine-contaminated spent caustic problematic stream through WAO and CWAO oxidation using a high specific surface catalyst from petcoke, Chemical Engineering Journal, Volume 460, 2023, 141692, ISSN 1385-8947, https://doi.org/10.1016/j.cej.2023.1416921385-8947https://hdl.handle.net/10115/24679The authors thank the financial support of the Community of Madrid through the projects IND2018/AMB-9611 and S2018/EMT-4341 REMTAVARES-CM. Moreover, the authors are grateful to Repsol for providing wastewater samples.Different operating conditions of wet air oxidation and catalytic wet air oxidation have been studied for the treatment of highly concentrated methyldiethanolamine wastewater streams from amine units of acid gas recovery in petrol refineries. These units occasionally generate streams of high methyldiethanolamine content that require special actions to avoid undesirable impacts on the downstream biological process of the petrochemical wastewater treatment plant due to its inhibition effect. The wet air oxidation treatment achieved remarkable removals of methyldiethanolamine, sulfides, chemical oxygen demand and total organic carbon (99%, 95%, 65% and 38%, respectively). Likewise, activated petroleum coke materials from the own refinery plant were tested as catalysts in the process. These materials were prepared under different conditions (chemical activating agent and thermal carbonization process). The catalytic wet air oxidation treatment using an activated petroleum coke was able to remove the methyldiethanolamine at milder operation conditions keeping a similar performance in terms of wastewater treatment removals as compared to the non-catalytic experiments. This technology significantly increased the biodegradability of the treated effluents ranging from 25 to 70 % due to the formation of more biodegradable substrates (acetic acid and ammonium) for further biological treatment.engAttribution-NonCommercial-NoDerivatives 4.0 Internacionalhttp://creativecommons.org/licenses/by-nc-nd/4.0/MethyldiethanolamineWet air oxidationCatalytic wet air oxidationBiodegradabilityPetcokeSpent causticIncreasing biodegradability of a real amine-contaminated spent caustic problematic stream through WAO and CWAO oxidation using a high specific surface catalyst from petcokeinfo:eu-repo/semantics/article10.1016/j.cej.2023.141692info:eu-repo/semantics/openAccess