Full Length Research Paper
References
Aigbodion AI, Bakare IO (2005). Rubber seed oil quality assessment and authentication. Journal of the American Oil Chemists' Society 82(7):465-469. |
|
Aravind A, Joy ML, Nair KP (2015). Lubricant properties of biodegradable rubber tree seed (Hevea brasiliensis Muell. Arg) oil. Industrial Crops and Products 74:14-19. |
|
Atabani AE, Silitonga AS, Ong HC, Mahlia TMI, Masjuki HH, Badruddin IA, Fayaz H (2013). Non-edible vegetable oils: A critical evaluation of oil extraction, fatty acid compositions, biodiesel production, characteristics, engine performance and emissions production. Renewable and Sustainable Energy Reviews18:211-245. |
|
Bakare IO, Okieimen FE, Pavithran C, Abdul Khalil HPS, Brahmakumar M (2010). Mechanical ant thermal properties of sisal fiber-reinforced rubber seed oil-based polyurethane composites. Material Design 31:4274-4280. |
|
Barison A, Pereira da Silva CW, Campos FR, Simonelli F, Lenz CA, Ferreira AG (2010). A simple methodology for the determination of fatty acid composition in edible oils through 1H NMR spectroscopy. Magnetic Resonance in Chemistry 48:642-650. |
|
Bohre A (2013). Immobolization of radioactive waste in ceramic-based hosts: Radioactive waste immobolization. Hamburg: Anchor Academic Publishers. |
|
Ebewele RO, Iyayi AF, Hymore FK (2010). Considerations of the extraction process and potential technical applications of Nigerian rubber seed oil. International Journal of Physical Sciences 5(6):826-831. |
|
Eka HD, Tajul Aris Y, Wan Nadiah WA (2010). Potential use of Malaysia rubber (Hevea brasiliensis) seed as food, feed and biofuel. International Food Research Journal 17:527-534. |
|
Guillén MD, Cabo N (2002). Fourier transform infrared spectra data versus peroxide and anisidine values to determine oxidative stability of edible oils. Food Chemistry 77:503-510. |
|
Guillén MD, Ruiz A (2003a). 1H nuclear magnetic resonance as a fast tool for determining the composition of acyl chains in acylglycerol mixtures. European Journal of Lipid Science and Technology 105:502-507. |
|
Guillén MD, Ruiz A (2003b). Rapid simultaneous determination by proton NMR of unsaturation and composition of acyl groups in vegetable oils. European Journal of Lipid Science and Technology 105:688-696. |
|
Hosamani KM, Katagi KS (2008). Characterization and structure elucidation of 12-hydroxyoctadec-cis-9-enoic acid in Jatropha gossypifolia and Hevea brasiliensis seed oils: a rich source of hydroxy fatty acid. Chemistry and Physics of Lipids 152:9-12. |
|
Igeleke CL, Omorusi VI (2007). Review of post-harvest deterioration of rubber Seeds. Journal of Agriculture and Social Research 7(2):11-19. |
|
Ogbu IM, Ajiwe VIE (2016). FTIR studies of thermal stability of the oils and methyl esters from Afzelia africana and Hura crepitans seeds. Renewable Energy 96:203-208. |
|
Okiemen FE, Pavithran C, Bakare IO (2005). Epoxidation and hydroxlation of rubber seed oil: one-pot multi-step reactions. European Journal of Lipid Science and Technology 107:330-336. |
|
Onoji SE, Iyuke SE, Igbafe AI (2016). Hevea brasiliensis (Rubber seed) oil: Extraction, characterization, and kinetics of thermo-oxidative degradation using classical chemical methods. Energy Fuels 30(12):10555-10567. |
|
Onoji SE, Iyuke SE, Igbafe AI, Daramola MO (2017). Transesterification of rubber seed oil to biodiesel over a calcined waste rubber seed shell catalyst: Modeling and optimization of process variables. Energy Fuels 31(6):6109-6119. |
|
Onoji SE, Iyuke SE, Igbafe AI, Daramola MO (2019). Hevea brasiliensis (Rubber seed) oil: Modeling and optimization of extraction process parameters using response surface methodology and artificial neural network techniques. Biofuels 10(6):677-691. |
|
Onoji SE, Iyuke SE, Igbafe AI, Daramola MO (2020). Rubber seed (Hevea brasiliensis) oil biodiesel emission profiles and engine performance characteristics using a TD202 diesel test engine. Biofuels 1-8, doi: 10.1080/17597269.2020.1738679. |
|
Reshad AS, Tiwari P, Goud VV (2015). Extraction of oil from rubber seeds for biodiesel application: Optimization of parameters. Fuel 150:636-644. |
|
Roschat W, Siritanon T, Yoosuk B, Sudyoadsuk T, Promarak V (2017). Rubber seed oil as potential non-edible feedstock for biodiesel production using heterogeneous catalyst in Thailand. Renewable Energy 101:937-944. |
|
Sadowska J, Johansson B, Johannessen E, Friman R, Broniarz-Press L, Rosenholm JB (2008). Characterization of ozonated vegetable oils by spectroscopic and chromatographic methods. Chemistry and Physics of Lipids 151:85-91. |
|
Scano P, Rosa A, Marincola FC, Locci E, Melis MP, Dessi MA, Lai A (2008). 13C NMR, GC and HPLC characterization of lipid components of the salted and dried mullet (Mugil cephalus) roe "bottarga". Chemistry and Physics of Lipids 151:69-76. |
|
Sinclair RG, Mckay AF, Myers GS, Jones RN (1952). The infrared absorption spectra of unsaturated fatty acids and esters. Journal of the American Chemical Society 74:2578-2585. |
|
Skooge DA, Holler FJ, Crouch SR (2007). Principle of Instrumental Analysis (6th Ed.). Thomson Publishing, USA. |
|
Umar HY, Esekhade TU, Idoko SO, Ugwa IK (2010). Production analysis of budded rubber stumps in Rubber Research Institute of Nigeria (RRIN). Journal of Agricultural Science 1(2):109-113. |
|
Valente VSB, dos S. Vieira A, Teixeira RM (2016). Physicochemical characterization of commercial biodiesel/diesel blends and evaluation of unconventional spectroscopic vibrational techniques in the monitoring of their oxidation and hydrolysis during storage. Energy Fuels 30:8399-8409. |
|
Yang R, Su M, Zhang J, Jin F, Zhu C, Li M, Hao X (2011). Biodiesel production from rubber seed oil using poly (sodium acrylate) supporting NaOH as a water-resistant catalyst. Bioresource Technology 102:2665-2671. |
|
Yeung DKW, Lam SL, Griffith JF, Chan ABW, Chen Z, Tsang PH, Leung PC (2008). Analysis of bone marrow fatty acid composition using high-resolution proton NMR spectroscopy. Chemistry and Physics of Lipids 151:103-109. |
Copyright © 2024 Author(s) retain the copyright of this article.
This article is published under the terms of the Creative Commons Attribution License 4.0