Abstract
There has been a strong interest worldwide in developing suitable technologies that can derive chemicals and materials from renewable biomass in a number of applications, including corrosion inhibitors. In spite of the efficacy of conventional inhibitors in corrosion control, current corrosion inhibitors exhibit toxicity and/or are non-biodegradable. Therefore, industry efforts are leading to the development of non-toxic and environmentally friendly “green” corrosion inhibitors from renewable resources. Extensive studies of different bio-based inhibitors show that a vast number of phytochemicals can be used as efficient corrosion inhibitors. This paper provides a comprehensive review of the corrosion inhibition properties of plant-derived chemicals classified under the parameters provided by botanical chemistry.
About the authors
Andrea Marciales received her BSc in chemical engineering from the Industrial University of Santander (UIS), Colombia. In 2011, Andrea joined the Colombian Petroleum Institute (ICP) as a consulting engineer for Ecopetrol. She later obtained her MSc in petroleum engineering from the University of Alberta in 2015, working on selection of solvent for unconventional recovery processes. In 2016, she worked as a research assistant at the University of Alberta, focusing on the development of green inhibitors and microbiologically influenced corrosion. In 2017, she joined InnoTech Alberta as a corrosion engineer.
Tesfaalem Haile obtained his PhD in civil and environmental engineering from the University of Western Ontario, London, Canada, in 2009. Tesfa has been working in R&D and corrosion consultancy since 2006. He leads several corrosion projects, including corrosion in oil sand thermal and mining operations, investigating MIC in Canadian onshore operations, and testing the efficiency of lignin as a corrosion inhibitor, among others. He is the principal investigator of the projects he manages.
Behzad Ahvazi completed his Bachelor of Science in Honours program at the Department of Chemistry and Biochemistry, and graduated with distinction at Concordia University in Montréal, Québec. His PhD program was completed in 1998 at McGill. Currently, he is working at InnoTech Alberta as a Principal Researcher for Biomass Conversion and Processing Technologies, aimed at developing high-end value-added applications from pulp and lignocellulosic materials such as cellulose nanocrystals and lignin. Dr. Ahvazi is also an adjunct professor in the Department of Mechanical Engineering, University of Alberta.
Tri-Dung Ngo obtained his PhD in mechanical engineering from Concordia University, Montreal, Canada, in 2007. He held a position as lecturer and researcher at Faculty of Chemical Engineering and thereafter Materials Engineering at HCM Polytechnic University from 1997 to 2002. He worked at National Research Council of Canada as a researcher from 2003 to 2014. Dr. Ngo joined InnoTech Alberta as a research scientist in 2014. His research focuses on biomass processing and development of novel, eco-friendly biomaterials. Dr. Ngo is also an adjunct professor at Department of Civil and Environmental Engineering, University of Alberta.
John Wolodko is currently the AI Strategic Chair in Bio and Industrial Materials, and an associate professor at the University of Alberta in Edmonton, Canada. His areas of research include the development and characterization of sustainable materials from agricultural and forestry feedstocks, life cycle assessment, and materials for the energy sector. Dr. Wolodko is a former Executive Director at AITF (formerly the Alberta Research Council), and has over 20 years R&D experience in advanced materials, manufacturing, testing, and engineering design.
Acknowledgments
The authors would like to thank Dr. Tamer Crosby for providing scientific review.
Funding: The authors would like to thank Alberta Innovates for funding the project.
Conflict of interest statement: The authors declare to have no conflicts of interest regarding this article.
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