Enhanced asphaltene degradation using piezocatalytic technology: A novel approach for sustainable oilfield operations

Muhammed Ibrahim, Wrea and Amiri, Omid and S. Ahmed, Sangar and Yasin Muhammed, Hunar and H. Mahmood, Peshawa and A. Qurbani, Karzan and A. Abdulrahman, Nabaz and A. Younis, Karim and Kh Omer, Peshang (2024) Enhanced asphaltene degradation using piezocatalytic technology: A novel approach for sustainable oilfield operations. Results in Engineering, 21. ISSN 2590-1230

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Abstract

Asphalt or oil spills containing asphaltene can contaminate soil, water bodies, and ecosystems. Natural balances are disrupted by this contamination. Asphaltene contaminates water sources such as rivers, lakes, and aquifers, making them unfit for human consumption. Aquatic habitats are damaged, and aquatic organisms cannot reproduce, grow, or maintain health. Air pollutants, including sulfur dioxide, nitrogen oxides, volatile organic compounds, and particulate matter, are released when asphaltene-containing materials are burned. Here, we have developed a new method for the degradation of asphaltene that is fast, clean, and cost-effective. The asphaltene was degraded using NixMnyO piezo catalyst in this study. By using NixMnyO under mechanical force, the result showed that asphaltene was degraded to the extent of 94.7 %. Piezo based on NixMnyO has shown promising reusability when compared to conventional catalysts. Despite being used for 11 runs, it maintained 94% of its activity for 11 consecutive cycles. As well as analyzing the kinetics and thermodynamics of piezo asphaltene degradation, a mechanism pathway was developed for piezo degradation of asphaltene. Radical scavenger experiments showed that superoxide radicals, holes, and hydroxyl radicals are involved in the degradation of asphaltene by NixMnyO piezo catalysts. However, hydroxyl radicals and holes are responsible for the majority of asphaltene degradation.

Item Type: Article
Uncontrolled Keywords: Piezo catalyst Degradation Asphaltene Kinetic Mechanism
Subjects: G Geography. Anthropology. Recreation > GE Environmental Sciences
Q Science > QD Chemistry
Engineering > Petroleum and mining engineering
Depositing User: ePrints deposit
Date Deposited: 22 Sep 2024 13:57
Last Modified: 22 Sep 2024 13:57
URI: http://eprints.tiu.edu.iq/id/eprint/1631

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