RSM course of optimization of biodiesel manufacturing from rapeseed oil and waste corn oil within the presence of inexperienced and novel catalyst
[ad_1]
Thanh, L. T., Okitsu, Okay., Van Boi, L. & Maeda, Y. Catalytic applied sciences for biodiesel gas manufacturing and utilization of glycerol. A assessment. Catalysts 2, 191–222 (2012).
Glisic, S. B., Pajnik, J. M. & Orlović, A. M. Course of and techno-economic evaluation of inexperienced diesel manufacturing from waste vegetable oil and the comparability with ester sort biodiesel manufacturing. Appl. Power 170, 176–185 (2016).
Bobadilla Corral, M., LostadoLorza, R., EscribanoGarcía, R., Somovilla Gómez, F. & Vergara González, E. P. An enchancment in biodiesel manufacturing fromwaste cooking oil by making use of thought multi-response floor methodology utilizing desirability capabilities. Energies 10, 130–137 (2017).
Martins, F., Felgueiras, C., Smitkova, M. & Caetano, N. Evaluation of fossil gas vitality consumption and environmental impacts in European international locations. Energies 12(6), 964 (2019).
Narula, Okay. World vitality system and sustainable vitality safety. Maritime Dimen Maintain. Power Secur. 68, 23–49 (2019).
Abas, N., Kalair, A. & Khan, N. Overview of fossil fuels and future vitality applied sciences. Futures 39, 31–49 (2015).
Tan, Y. H. et al. Biodiesel manufacturing from used cooking oil utilizing inexperienced strong catalyst derived from calcined fusion waste hen and fish bones. Renew. Power 139, 696–706 (2019).
Tang, X. & Niu, S. Preparation of carbon-based strong acid with massive floor space to catalyze esterification for biodiesel manufacturing. J. Ind. Eng. Chem. 69, 187–195 (2019).
Norjannah, B., Chyuan Ong, H., Masjuki, H. H., Juan, J. C. & Chong, W. T. Enzymatic transesterification for biodiesel manufacturing from used cooking oil, a assessment. RSC Adv. 6, 60034–60055 (2016).
Fukuda, H., Kondo, A. & Noda, H. Biodiesel gas manufacturing by transesterification of oils. J. Biosci. Bioenergy 92, 405–416 (2001).
Verma, P. & Sharma, M. Comparative evaluation of impact of methanol and ethanol on Karanja biodiesel manufacturing and its optimization. Gas 180, 164–174 (2016).
Ong, H. et al. Manufacturing and comparative gas properties of biodiesel from non-edible oils: Jatropha curcas, Sterculiafoetida and Ceibapentandra. Power Convers. Manag. 73, 245–255 (2013).
Konur, O. Palm oil-based biodiesel fuels: A assessment of the analysis. Biodivers. Gas Primarily based Edible Nonedible 2021 (in press).
Gayglou, S. E., Tafakori, V., Zahed, M. A., Khamoushi, A.: Two promoters of biodiesel and biomass manufacturing induced by completely different concentrations of myo-inositol in Chlorella vulgaris. Biomass Convers. Biorefinery 2021 (in press).
Singh, D. et al. A assessment on feedstocks, manufacturing processes, and yield for various generations of biodiesel. Gas 262, 116553–116565 (2020).
Hasni, Okay., Ilham, Z., Dharma, S. & Varman, M. Optimization of biodiesel manufacturing from Bruceajavanica seeds oil as novel non-edible feedstock utilizing response floor methodology. Power Convers. Manag. 149, 392–400 (2017).
Souza, M. C. G., de Oliveira, M. F., Vieira, A. T., de Faria, A. M. & Batista, A. C. F. Methylic and ethylic biodiesel manufacturing from crambe oil (Crambeabyssinica): New points for yield and oxidative stability. Renew. Power 163, 368–374 (2021).
Ma, F. & Hanna, M. A. Biodiesel manufacturing: A assessment. Bioresour. Technol. 70, 1–15 (1999).
Lapinskiene, A., Martinkus, P. & Rebzdaite, V. Eco-toxicological research of diesel and biodiesel fuels in aerated soil. Environ. Pollut. 142, 432–437 (2006).
Knothe, G., Gerpen, J. V. & Krahl, J. The biodiesel handbook. AOCS 34, 1–3 (2005).
Mumtaz, M. W., Adnan, A., Mukhtar, H., Rashid, U. & Danish, M. Biodiesel manufacturing via chemical and biochemical transesterification. Clear Power Maintain. Dev. 15, 465–485 (2017).
Baskar, G., Kalavathy, G., Aiswarya, R. & Selvakumari, I. A. Advances in bio-oil extraction from non-edible oil seeds and algal biomass. Adv. Eco-Fuels Maintain. Environ. 7, 187–210 (2019).
Nasreen, S. et al. Overview of catalytic transesterification strategies for biodiesel manufacturing. Biofuel State Dev. 6, 1–28 (2018).
Norjannah, B., Chyuan Ong, H., Masjuki, H. H., Juan, J. C. & Chong, W. T. Enzymatic transesterification for biodiesel manufacturing: a complete assessment. RSC Adv. 6, 60034–60055 (2016).
Angulo, B., Fraile, J. M., Gil, L. & Herrerías, C. I. Comparability of chemical and enzymatic strategies for the transesterification of waste fish oil fatty ethyl esters with completely different alcohols. ACS Omega 5, 1479–1487 (2020).
Wang, X. et al. Fatty acid methyl ester synthesis via transesterification of palm oil with methanol in microchannels: circulate sample and response kinetics. Power Fuels 34, 3628–3639 (2020).
Yusuff, A. S. & Bello, Okay. A. Synthesis of fatty acid methyl ester by way of transesterification of waste frying oil by a zinc-modified pumice catalyst: Taguchi strategy to parametric optimization. React. Kinet. Mech. Cat. 128, 739–761 (2019).
Maleki, H. et al. Transesterification of canola oil and methanol by lithium impregnated CaO–La2O3 blended oxide for biodiesel synthesis. J. Ind. Eng. Chem. 47, 399–404 (2017).
Shareh, F. B., Kazemeini, M., Asadi, M. & Fattahi, M. Metallic promoted mordenite catalyst for methanol conversion into mild olefins. Petrol. Sci. Tech. 32, 1349–1356 (2014).
Amirthavalli, V. & Warrier, A. R. Fabrication and optimization of nanocatalyst for biodiesel manufacturing: An outline. AIP Conf. Proc. 2115, 030609–030612 (2019).
Pedram, M. Z., Kazemeini, M., Fattahi, M. & Amjadian, A. A physicochemical analysis of modified HZSM-5 catalyst utilized for manufacturing of dimethyl ether from methanol. Pet. Sci. Tech. 32, 904–911 (2014).
Kamyab, H. et al. Optimum lipid manufacturing utilizing agro-industrial wastewater handled microalgae as biofuel substrate. Clear Technol. Environ. Coverage 18, 2513–2523 (2016).
Kamyab, H. et al. Isolation and screening of microalgae from agro-industrial wastewater (POME) for biomass and biodiesel sources. Desalin. Water Deal with. 57, 29118–29125 (2016).
Parichehreh, R., Gheshlaghi, R., Mahdavi, M. A. & Kamyab, H. Investigating the results of 11 key physicochemical components on development and lipid accumulation of Chlorella sp. as a feedstock for biodiesel manufacturing. J. Biotechnol. 340, 64–74 (2021).
Vicente, G., Martınez, M. & Aracil, J. Built-in biodiesel manufacturing: A comparability of various homogeneous catalysts programs. Biores. Technol. 92, 297–305 (2004).
Boey, P.-L., Maniam, G. P. & Hamid, S. A. Efficiency of calcium oxide as a heterogeneous catalyst in biodiesel manufacturing: A assessment. Chem. Eng. J. 168, 15–22 (2011).
Singh, B., Gulde, A., Rawat, I. & Bux, F. In direction of a sustainable strategy for improvement of biodiesel from plant and microalgae. Renew Maintain. Power Rev. 29, 216–245 (2014).
Takagaki, A. et al. Esterification of upper fatty acids by a novel sturdy strong acid. Catal. Immediately 116, 157–161 (2006).
Konwar, L. J., Boro, J. & Deka, D. Overview on newest developments in biodiesel manufacturing utilizing carbon-based catalysts. Renew Maintain. Power Rev. 29, 546–564 (2014).
Tariq, M., Ali, S. & Khalid, N. Exercise of homogeneous and heterogeneous catalysts, spectroscopic and chromatographic characterization of biodiesel: a assessment. Renew. Maintain. Power Rev 16, 6303–6316 (2012).
Gotch, A. J., Reeder, A. J. & McCormick, A. Examine of heterogeneous base catalysts for biodiesel manufacturing. J. Undgrad. Chem. Res 8, 22–26 (2009).
Chouhan, A. P. S. & Sarma, A. Okay. Trendy heterogeneous catalysts for biodiesel manufacturing: A complete assessment. Renew. Maintain. Power Rev. 15, 4378–4399 (2011).
Leung, D. Y. C., Wu, X. & Leung, M. Okay. H. A assessment on biodiesel manufacturing utilizing catalyzed transesterification. Appl. Power 87, 1083–1095 (2010).
Zabeti, M., Daud, W. A. W. & Aroua, M. Okay. Exercise of strong catalysts for biodiesel manufacturing: a assessment. Gas Course of. Technol. 90, 770–777 (2009).
Macario, A. & Giordano, G. Catalytic conversion of renewable sources for biodiesel manufacturing: A comparability between biocatalysts and inorganic catalysts. Catal. Lett. 143, 159–168 (2013).
Sani, Y. M., Daud, W. A. W. & Aziz, A. R. A. Exercise of strong acid catalyst for biodiesel manufacturing: a vital assessment. Appl. Catal. A Gen. 470, 140–161 (2014).
Lam, M. Okay., Lee, Okay. T. & Mohamed, A. R. Homogeneous, heterogeneous and enzymatic catalysis for transesterification of excessive free fatty acid oil (waste cooking oil) to biodiesel: a assessment. Biotechnol. Adv. 28, 500–518 (2010).
Shu, Q. et al. Synthesis of biodiesel from cottonseed oil and methanol utilizing a carbon-based strong acid catalyst. Gas Course of. Technol. 90, 1002–1008 (2009).
Smith, S. M. et al. Transesterification of soybean oil utilizing bovine bone waste as new catalyst. Bioresour. Technol. 143, 686–690 (2013).
Luque, R. et al. Carbonaceous residues from biomass gasification as catalysts for biodiesel manufacturing. J. Nat. Gasoline Chem. 21, 246–250 (2012).
Sanjay, B. Heterogeneous catalyst derived pure sources for biodiesel manufacturing: A assessment. Res. J. Chem. Sci. 3, 95–101 (2013).
Veisi, H., Tamoradi, T., Rashtiani, A., Hemmati, S. & Karmakar, B. Palladium nanoparticles anchored polydopamine-coated graphene oxide/Fe3O4 nanoparticles (GO/Fe3O4@PDA/Pd) as a novel recyclable heterogeneous catalyst within the facile cyanation of haloarenes utilizing K4[Fe(CN)6] as cyanide supply. J. Ind. Eng. Chem. 90, 379–388 (2020).
Tamoradi, T. et al. MgO doped magnetic graphene spinoff as a reliable heterogeneous catalyst producing biofuels by way of transesterification: Course of optimization via Response Floor Methodology (RSM). J. Environ. Chem. Eng. 9, 106009–106020 (2021).
Rao, L. et al. Lotus seedpods biochar embellished molybdenum disulfide for moveable, versatile, out of doors and cheap sensing of hyperin. Chemosphere 301, 134595 (2022).
Torkian, N. et al. Synthesis and characterization of Ag-ion-exchanged zeolite/TiO2 nanocomposites for antibacterial purposes and photocatalytic degradation of antibiotics. Environ. Res. 207, 112157 (2022).
Cheraghi, A., Davar, F., Homayoonfal, M. & Hojjati-Najafabadi, A. Impact of lemon juice on microstructure, part adjustments, and magnetic efficiency of CoFe2O4 nanoparticles and their use on launch of anti-cancer medication. Ceram. Int. 47, 20210–20219 (2021).
HojjatiNajafabadi, A., Ghasemi, A., Mozaffarinia, R. Synthesis and analysis of microstructural and magnetic properties of Cr3+ substitution barium hexaferrite nanoparticles (BaFe10.5−x Al1.5Cr x O19). J. Cluster Sci. 27, 965–978 (2016).
Hojjati-Najafabadi, A., Davar, F., Enteshari, Z., Hosseini-Koupaei, M. Antibacterial and photocatalytic behaviour of inexperienced synthesis of Zn0. 95Ag0.05O nanoparticles utilizing natural drugs extract. Ceram. Int. 31617–31624 (2021).
Hojjati-Najafabadi, A., Mansoorianfar, M., Liang, T., Shahin, Okay. & Karimi-Maleh, H. A assessment on magnetic sensors for monitoring of hazardous pollution in water sources. Sci. Complete Environ. 824, 153844 (2022).
Karimi-Maleh, H. et al. Latest advances in carbon nanomaterials-based electrochemical sensors for meals azo dyes detection. Meals Chem. Toxicol. 164, 112961 (2022).
Karaman, C., Karaman, O., Present, P. L., Karimi-Maleh, H. & Zare, N. Congo purple dye elimination from aqueous setting by cationic surfactant modified-biomass derived carbon: Equilibrium, kinetic, and thermodynamic modeling, and forecasting by way of synthetic neural community strategy. Chemosphere 290, 133346 (2022).
Karimi-Maleh, H. et al. Cyanazine herbicide monitoring as a hazardous substance by a DNA nanostructure biosensor. J Hazardous Mater. 423, 127058 (2022).
Karimi-Maleh, H., Karaman, C., Karaman, O., Karimi, F., Vasseghian, Y., Fu, L., Baghayeri, M., Rouhi, J., Kumar, P. S., Present, P. L., Rajendran, S., Sanati, A. L., Mirabi, A. Nanochemistry strategy for the fabrication of Fe and N co-decorated biomass-derived activated carbon frameworks: a promising oxygen discount response electrocatalyst in impartial media. J. Nanostruct. Chem. in press (2022).
Ghalkhani, M. et al. Latest advances in Ponceau dyes monitoring as meals colorant substances by electrochemical sensors and developed procedures for his or her elimination from actual samples. Meals Chem. Toxicol. 161, 112830 (2022).
Karimi-Maleh, H. et al. A inexperienced and delicate guanine-based DNA biosensor for idarubicin anticancer monitoring in organic samples: A easy and quick technique for management of well being high quality in chemotherapy process confirmed by docking investigation. Chemosphere 291, 132928 (2022).
Moloudizargari, M., Mikaili, P., Aghajanshakeri, S., Asghari, M. H. & Shayegh, J. Pharmacological and therapeutic results of Peganumharmala and its fundamental alkaloids. Pharmacogn. Rev. 7, 199–212 (2013).
Wang, Okay.-B., Li, D.-H., Bao, Y. & Cao, F. Structurally numerous alkaloids from the seeds of Peganumharmala. J. Nat. Prod. 80, 551–559 (2017).
Miao, X., Zhang, X., Yuan, Y., Zhang, Y. & Gao, J. The toxicity evaluation of extract of Peganumharmala L. seeds in Caenorhabditis elegans. BMC Complement. Med. Ther. 20, 256–267 (2020).
Singh, V., Belova, L., Singh, B. & Sharma, Y. C. Biodiesel manufacturing utilizing a novel heterogeneous catalyst, magnesium zirconate (Mg2Zr5O12): Course of optimization via response floor methodology (RSM). Power Convers. Manag. 174, 198–207 (2018).
Tan, Y. H., Abdullah, M. O., Hipolito, C. N. & Zauzi, N. S. A. Utility of RSM and Taguchi strategies for optimizing the transesterification of waste cooking oil catalyzed by strong ostrich and chicken-eggshell derived CaO. Renew. Power 114, 437–447 (2017).
Arumugam, A., Thulasidharan, D. & Jegadeesan, G. B. Course of optimization of biodiesel manufacturing from Heveabrasiliensis oil utilizing lipase immobilized on spherical silica aerogel. Renew. Power 116, 755–761 (2018).
Mansoorianfar, M., Shahin, Okay., Hojjati-Najafabadi, A. & Pei, R. MXene–laden bacteriophage: A brand new antibacterial candidate to manage bacterial contamination in water. Chemosphere 290, 133383 (2022).
HojjatiNajafabadi, A., Mozaffarinia, R., Rahimi, H., ShojaRazavi, R. & Paimozd, E. Mechanical property analysis of corrosion safety sol–gel nanocomposite coatings. Surf. Eng. 29, 249–254 (2013).
Tamoradi, T., Kiasat, A. R., Veisi, H., Nobakht, V. & Karmakar, B. Transesterification of rapeseed oil and waste corn oil towards the manufacturing of biodiesel over a fundamental excessive floor space magnetic nanocatalyst: utility of the response floor methodology in course of optimization. New. J. Chem. 45, 21116–21124 (2021).
Jang, M. G., Kim, D. Okay., Park, S. C., Lee, J. S. & Kim, S. W. Biodiesel manufacturing from crude canola oil by two-step enzymatic processes. Renew Energ 42, 99–104 (2012).
Kim, H. J. et al. Transesterification of vegetable oil to biodiesel utilizing heterogeneous base catalyst. Catal. Immediately 93, 315–320 (2004).
Nelson, L. A., Foglia, A. & Marmer, W. N. Lipase-catalyzed manufacturing of biodiesel. J. Am. Oil Chem. Sot. 73, 1191–1195 (1996).
Antunes, W. M., Veloso, C. O. & Henriques, C. A. Transesterification of soybean oil with methanol catalyzed by fundamental solids. Catal. Immediately 133, 548–554 (2008).
Mittelbach, M. Lipase catalyzed alcoholysis of sunflower oil. J. Am. Oil Chem. Sot. 67, 1688170 (1990).
Abigor, R. et al. Lipase-catalysed manufacturing of biodiesel gas from some Nigerian lauric oils. Biochem. Sot. Trans. 28, 979–981 (2000).
[ad_2]
Source_link
