In situ Transesterification/Reactive Extraction of Castor Bean Seeds Assisted by Flying Jet Plasma for Biodiesel Production |
Elsheikh, Yasir A.
(Department of Chemical and Petrochemical Engineering, University of Nizwa)
Abdul-Majeed, Wameath S. (Department of Chemical and Petrochemical Engineering, University of Nizwa) Nasir, Qazi (Department of Chemical and Petrochemical Engineering, University of Nizwa) Al-Rahbi, Balaqis (Department of Chemical and Petrochemical Engineering, University of Nizwa) Al-Subhi, Noor (Department of Chemical and Petrochemical Engineering, University of Nizwa) Mahmoud, Mohamed A. (Chemical Engineering Department, College of Engineering, Jazan University) AAl-Thani, Ghanim S. (Daris Centre for Scientific Research and Technological Development, University of Nizwa) |
1 | D. Leung and Y. Guo, Transesterification of neat and used frying oil: Optimization for biodiesel production, Fuel Process Technol., 87, 883-890 (2006). DOI |
2 | L. C. Meher, D. V. Sagar, and S. N. Naik, Technical aspects of biodiesel production by transesterification - A review, Renew. Sust. Energ. Rev., 10, 248-268 (2006). DOI |
3 | B. P. Thangaraj, R. Solomon, B. Muniyandi, S. Ranganathan, and L. Lin, Catalysis in biodiesel production-A review, Clean Energy, 3, 2-23 (2019). DOI |
4 | J. Li, C. Ma, S. Zhu, F. Yu, B. Dai, and D. Yang, A review of recent advances of dielectric barrier discharge plasma in catalysis, Nanomaterials, 9, 1-34 (2019). DOI |
5 | F. Kasim, A. P. Harvey, and R. Zakaria, Biodiesel production by in situ transesterification, Biofuels, 1, 355-365 (2014). DOI |
6 | M. J. Haas, K. M. Scott, T. A. Foglia, and W. N. Marmer, The general applicability of in situ transesterification for the production of fatty acid esters from a variety of feedstocks, JAOCS, 84, 963-970 (2007). DOI |
7 | P. Mehta, P. Barboun, D. B. Go, J. C. Hicks, and W. F. Schneider, Catalysis enabled by plasma activation of strong chemical bonds: A review, ACS Energy Lett., 4, 1115-1133 (2019). DOI |
8 | W. S. Abdul-Majeed, G. S. AAl-Thani, and J. N. Al-Sabahi, Application of flying jet plasma for production of biodiesel fuel from wasted vegetable oil, Plasma Chem. Plasma Process., 36, 1517-1531 (2016). DOI |
9 | Y. Zhang, M. A. Dube, D. D. McLean, and M. Kates, Biodiesel production from waste cooking oil: Economic assessment and sensitivity analysis, Bioresour. Technol., 90, 229-240 (2003). DOI |
10 | W. S. Abdul-Majeed, and K.O. Al-Riyami, Activation of peat soil carbon and production of carbon nanostructures using a flying jet cold plasma torch, Environ. Chem. Lett., 17, 1383-1390 (2019). DOI |
11 | U. Kogelschatz, Dielectric-barrier discharges: their history, discharge physics, and industrial applications, Plasma Chem. Plasma Process., 23, 1-46 (2003). DOI |
12 | R.S. Singhal and P. R. Kulkarni, Effect of puffing on oil characteristics of Amaranth (Rajgeera) seeds, JAOCS, 67, 952-954 (1990). DOI |
13 | P. Golay, F. Dionisi, B. Hug, and F. Giuffrida, Destaillats, Direct quantification of fatty acids in dairy powders with special emphasis on trans fatty acid content, Food Chem., 101, 1115-1120 (2006). DOI |
14 | W. S. Abdul-Majeed, Flying jet plasma: a logistic powerful catalyzing agent for chemical and biological processes, AOCS, 29, 18-20 (2018). |
15 | Y. A. Elsheikh, Z. Man, M. A. Bustam, F. H. Akhtar, S. Yusup, and A. muhammad, Preparation and characterization of citrulus colocynthis oil biodiesel: Optimization of alkali-catalyzed transesterification, Can. J. Chem. Eng., 92, 435-440 (2014). DOI |
16 | U. Rashid, F. Anwar, R. Yunus, and A. H. AL-Muhtaseb, Transesterification for biodiesel production using thespesiapopulnea seed oil: An optimization study, Int. J. Green Energy, 12, 479-484 (2015). DOI |
17 | S. M. Sadrameli, and M. Omarei, Preparation of biodiesel by transesterification of canola oil using solid base catalyst KOH/γ-Al2O3, Energy Technology: Carbon Dioxide Management and Other Technologies, 141-148 (2012). DOI |
18 | Y. Wang, S. Ou, P. Liu, and Z. Zhang, Preparation of biodiesel from waste cooking oil via two-step catalyzed process, Energy Convers. Manag., 48, 184-188 (2007). DOI |
19 | A. Bogaerts, and E. C. Neyts, Plasma technology: An emerging technology for energy storage, ACS Energy Lett., 3, 1013-1027 (2018). DOI |
20 | U. Pal, M. Kumar, M. Tyagi, B. Meena, H. Khatun, and A. Sharma, Discharge analysis and electrical modeling for the development of efficient dielectric barrier discharge, J. Phys. Conf. Ser., 208, 1-12 (2010). |
21 | E. C. Neyts, Plasma-surface interactions in plasma catalysis, Plasma Chem. Plasma Process, 36, 185-212 (2016). DOI |
22 | L. Naik, N. Radhika, K. Sravani, A. Hareesha, B. Mohanakumari, and K. Bhavanasindhu, Optimized parameters for production of biodiesel from fried oil, IARJSET, 2, 62-65 (2015). |
23 | B. R. Dhar, and K. Kirtania, Excess methanol recovery in biodiesel production process using a distillation column: A simulation study, Chem. Eng. Res. Bull., 13, 55-60 (2009). |
24 | I. S. Sulaiman, M. Basri, H. R. Masoumi, W. J. Chee, S. E. Ashari, and M. Ismail, Effects of temperature, time, and solvent ratio on the extraction of phenolic compounds and the anti-radical activity of Clinacanthusnutans Lindau leaves by response surface methodology, Chem. Cent. J., 54, 1-11 (2017). |