Development and characterisation of a nanostructured hybrid material with vitamin B12 and bagasse-derived activated carbon for anaerobic chlordecone (Kepone) removal
| Autor: | Thierry Cesaire, Hansjörg Grützmacher, Mohammed Chaker Ncibi, Corine Jean-Marius, Serge Lavoie, Sarra Gaspard, Ronald Ranguin |
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| Rok vydání: | 2020 |
| Předmět: |
Chemistry
Health Toxicology and Mutagenesis Langmuir adsorption model General Medicine 010501 environmental sciences 01 natural sciences Pollution chemistry.chemical_compound symbols.namesake Adsorption Environmental chemistry medicine symbols Environmental Chemistry Hybrid material Mesoporous material Bagasse Phosphoric acid Martinique 0105 earth and related environmental sciences Activated carbon medicine.drug |
| Zdroj: | Environmental Science and Pollution Research. 27:41122-41131 |
| ISSN: | 1614-7499 0944-1344 |
| Popis: | Intensive use of the chlorinated pesticide chlordecone from the 1970s to 1993 to prevent crop damage in banana plantations of Guadeloupe and Martinique led to diffuse pollution of soils and surface waters, affecting both fauna and human beings in the contaminated areas. Since 2001, drinking water production plants have been equipped with filters containing activated carbon that must be treated after saturation. The objective of this work is to produce a hybrid material composed of activated carbon and vitamin B12 (VB12) for the degradation of chlordecone (CLD). The preparation of such a hybrid material is carried out by non-covalent fixation to achieve an eco-friendly solution for the serious environmental problem of contamination by chlorinated pesticides. It is thus proposed to degrade CLD by a physico-chemical treatment allowing salvage of the catalyst, which is adsorbed on the carbon surface to generate less waste that is inexpedient to treat. Activated carbon (AC) is produced locally from available sugarcane bagasse subjected to phosphoric acid activation. The main characteristics of this material are a major mesoporous structure (0.91%) and a specific (BET) surface area ranging from 1000 to 1500 m2 g-1. The experimental results showed that BagP1.5 has a high adsorption capacity for VB12 due to its large surface area (1403 m2 g-1). The binding of VB12 to the bagasse-derived AC is favoured at high temperatures. The adsorption is optimal at a pH of approximately 6. The maximum adsorption capacity of VB12 on the AC, deduced from the Langmuir model, was 306 mg g-1, confirming the high affinity between the two components. The hybrid material was characterised by FTIR, Raman, X-ray fluorescence spectroscopy and SEM analysis. CLD removal by this hybrid material was faster than that by VB12 or BagP1.5 alone. The CLD degradation products were characterised by mass spectrometry. |
| Databáze: | OpenAIRE |
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