{"accessLevel": "public", "bureauCode": ["020:00"], "contactPoint": {"fn": "Scott Huling", "hasEmail": "mailto:huling.scott@epa.gov"}, "describedBy": "https://pasteur.epa.gov/uploads/10.23719/1518530/documents/GAC%20Oxidation_Data%20Dictionary%20for%20SDMP.docx", "describedByType": "application/vnd.openxmlformats-officedocument.wordprocessingml.document", "description": "Raw materials, activation methods, and post-activation treatment used in manufacturing granular activated carbon (GAC) results in a spectrum of physicochemical characteristics that potentially impact the adsorption oxidation treatment process. A comprehensive study is lacking that assesses the effect of GAC characteristics on adsorption oxidation treatment of contaminant-spent GAC. Consequently, it is inherently assumed the treatment process is GAC-independent. Here, GACs (n=31) were characterized and used in the hydrogen peroxide (H2O2)-based adsorption oxidation treatment of 2-chlorophenol (2CP)-spent GAC. The GACs exhibited a range in surface area, pore volume distribution, metals content, surface functionality, and H2O2 reaction. Chloride recovery, the treatment metric for 2CP oxidation, indicated a wide range in oxidation (0-49.2%) where bituminous- and wood-based GAC performed best. A selected subset of GACs (n=12), amended with iron, methyl tert-butyl ether, and H2O2, exhibited a range in oxidative treatment (1.1-57.9%). Correlations were established between GAC surface functionality, H2O2 reactivity, adsorption, and contaminant oxidation indicating multiple parameters play a collective and compounding role. The order of GACs successfully used in the treatment process is bituminous-based coal > wood > coconut > peat. Results showed adsorption oxidation treatment is GAC-dependent, and therefore, GAC selection is a key factor in the success of this technology. \n\nThis dataset is associated with the following publication:\nRusevova Crincoli, K., P.K. Jones, and S.G. Huling. Fenton-driven oxidation of contaminant-spent granular activated carbon (GAC): GAC selection and implications.   SCIENCE OF THE TOTAL ENVIRONMENT. Elsevier BV, AMSTERDAM,  NETHERLANDS, 734: 1-9, (2020).", "distribution": [{"downloadURL": "https://pasteur.epa.gov/uploads/10.23719/1518530/GAC%20Oxidation_Sci%20Hub%20Data%20Set%20Vers%202.0.xlsx", "mediaType": "application/vnd.openxmlformats-officedocument.spreadsheetml.sheet", "title": "GAC Oxidation_Sci Hub Data Set Vers 2.0.xlsx"}], "identifier": "https://doi.org/10.23719/1518530", "keyword": ["granular activated carbon", "advanced oxidation", "adsorption", "MTBE", "2-chlorophenol"], "license": "https://pasteur.epa.gov/license/sciencehub-license.html", "modified": "2020-04-14", "programCode": ["020:097"], "publisher": {"name": "U.S. EPA Office of Research and Development (ORD)", "subOrganizationOf": {"name": "U.S. Environmental Protection Agency", "subOrganizationOf": {"name": "U.S. Government"}}}, "references": ["https://doi.org/10.1016/j.scitotenv.2020.139435"], "rights": null, "title": "GAC Oxidation"}