NiO based catalysts obtained “in-situ” for heavy crude oil upgrading: effect of NiO precursor on the catalytic cracking products composition

Hosseinpour, 2018, The Synergistic effect between supercritical water and redox properties of iron oxide nanoparticles for in-situ catalytic upgrading heavy oil with formic acid. isotopic study, Appl Catal B, 230, 91, 10.1016/j.apcatb.2018.02.030 Biyouki, 2018, Pyrolysis and oxidation of asphaltene-born coke-like residue formed onto in situ prepared NiO nanoparticles toward advanced in situ combustion enhanced oil recovery processes, Energy Fuels, 32, 5033, 10.1021/acs.energyfuels.8b00638 Li, 2019, Advances on the transition-metal based catalysts for aquathermolysis upgrading of heavy crude oil, Fuel, 257, 1, 10.1016/j.fuel.2019.115779 Guo, 2018, Monodispersed nickel and cobalt nanoparticles in desulfurization of thiophene for in-situ upgrading of heavy crude oil, Fuel, 211, 697, 10.1016/j.fuel.2017.09.097 Chen, 2019, In situ preparation of well-dispersed CuO nanocatalysts in heavy oil for catalytic aquathermolysis, Pet Sci, 3, 439, 10.1007/s12182-019-0300-3 Al-Marshed, 2015, Effectiveness of different transition metal dispersed catalysts for in situ heavy oil upgrading, Ind Eng Chem Res, 54 43, 10645, 10.1021/acs.iecr.5b02953 Wang, 2019, Integrated process for partial oxidation of heavy oil and in-situ reduction of red mud, Appl Catal B, 258, 1, 10.1016/j.apcatb.2019.117944 Morelos‑Santos, 2020, Dispersed nickel-based catalyst for enhanced oil recovery (EOR) under limited hydrogen conditions, Top Catal, 63, 504, 10.1007/s11244-020-01227-w Al-Muntaser, 2020, Hydrothermal upgrading of heavy oil in the presence of water at sub-critical, near-critical and supercritical conditions, J Pet Sci Eng, 184, 10.1016/j.petrol.2019.106592 Rana, 2007, A review of recent advances on process technologies for upgrading of heavy oils and residua, Fuel, 86, 1216, 10.1016/j.fuel.2006.08.004 Hosseinpour, 2020, An optimization study on heavy oil upgrading in supercritical water through the response surface methodology (RSM), Fuel, 271, 10.1016/j.fuel.2020.117618 Avbenake, 2020, Saturates and aromatics characterization in heavy crude oil upgrading using Ni–Co/γ-Al2O3 catalysts, Pet Sci Technol, 38, 800, 10.1080/10916466.2020.1779743 Li, 2020, A review of in situ upgrading technology for heavy crude oil, Petroleum Sviridenko, 2020, Upgrading of heavy crude oil by thermal and catalytic cracking in the presence of NiCr/WC catalyst, J Taiwan Inst Chem Eng., 112, 97, 10.1016/j.jtice.2020.06.018 Omajali, 2017, In-situ catalytic upgrading of heavy oil using dispersed bio nanoparticles supported on gram-positive and gram-negative bacteria, Appl. Catal. B, 203, 807, 10.1016/j.apcatb.2016.10.074 Morozov, 2017, Catalytic properties of tungsten carbide powders in cracking heavy petroleum feedstock, Bull Tomsk Polytech Univ Geo Assets Eng, 328, 16 Guo, 2016, In-situ heavy and extra-heavy oil recovery: a review, Fuel, 185, 886, 10.1016/j.fuel.2016.08.047 Suwaid, 2020, In-situ catalytic upgrading of heavy oil using oil-soluble transition metal-based catalysts, Fuel, 281, 10.1016/j.fuel.2020.118753 Mukhamatdinov, 2019, Influence of Co-based catalyst on subfractional composition of heavy oil asphaltenes during aquathermolysis, J. Pet. Sci. Eng., 186 Sviridenko, 2016, Cracking of natural bitumen in the presence of nanosized powers Mo and CuO, Pet Coal, 58, 732 Khadzhiev, 2011, Nanoheterogeneous catalysis: a new sector of nanotechnologies in chemistry and petroleum chemistry (A review), Pet Chem., 51, 1, 10.1134/S0965544111010063 Knyazeva, 2019, Properties of nanosized cobalt-molybdenum sulfide catalyst formed in situ from sulfonium thiosalt, Pet Chem, 59, 504, 10.1134/S0965544119050049 Knyazeva, 2019, Effect of composition of cobalt-molybdenum-containing sulfonium thiosalts on the hydrogenation activity of nanosized catalysts in situ synthesized on their basis, Pet Chem, 59, 1285, 10.1134/S0965544119120065 Kang, 2019, A review on the Mo-precursors for catalytic hydroconversion of heavy oil, J Ind Eng Chem, 76, 1, 10.1016/j.jiec.2019.03.022 Sviridenko, 2020, General features of catalytic upgrading of karmalskoe heavy oil in the presence of amorphous aluminosilicates, Pet Chem, 60, 384, 10.1134/S0965544120030214 León, 2020, Reactivity of vacuum residues by thermogravimetric analysis and nuclear magnetic resonance spectroscopy, Energy Fuels, 34, 9231, 10.1021/acs.energyfuels.0c00200 Sadegh Mazloom, 2020, Application of nanoparticles for asphaltenes adsorption and oxidation: a critical review of challenges and recent progress, Fuel, 279, 10.1016/j.fuel.2020.117763 Wang, 2003, Asphaltene stability in crude oil and aromatic solvents the influence of oil composition energy, Fuels, 17, 1445, 10.1021/ef030030y Nassar, 2011, Metal oxide nanoparticles for asphaltene adsorption and oxidation, Energy Fuels, 25, 1017, 10.1021/ef101230g AlHumaidan, 2015, Changes in asphaltene structure during thermal cracking of residual oils: XRD study, Fuel, 150, 558, 10.1016/j.fuel.2015.02.076 Iovik, 2020, Thermal transformations of sulfur-containing components of oxidized vacuum gas oil, Pet Chem, 60, 341, 10.1134/S0965544120030081 Ancheyta, 2017 Sviridenko, 2019, Effect of conditions of cracking of heavy crude oils on a composition of products, AIP Conf Proc, 2167, 10.1063/1.5132227 Yeletsky, 2020, Heavy oil cracking in the presence of steam and nanodispersed catalysts based on different metals, Fuel Process Technol, 199, 10.1016/j.fuproc.2019.106239 Nguyen-Huy, 2016, Hierarchical macro–mesoporous Al2O3-supported NiK catalyst for steam catalytic cracking of vacuum residue, Fuel, 169, 1, 10.1016/j.fuel.2015.11.088 Stølen, 1994, Phase stability and structural properties of Ni7 ± ΔS6 and Ni9S8 heat capacity and thermodynamic properties of Ni7S6 at temperatures from 5 K to 970 K and of Ni9S8 from 5 K to 673 K, J Chem Thermodyn, 26, 10.1006/jcht.1994.1116 A.V. Vakhin, F.A. Aliev, I.I. Mukhamatdinov, S.A. Sitnov, A.V. Sharifullin, S.I. Kudryashov, I.S. Afanasiev, O.V. Petrashov, D.K. Nurgaliev, Catalytic aquathermolysis of boca de jaruco heavy oil with nickel-based oil-soluble catalyst. 8 (2020) 532, https://doi.org/10.3390/pr8050532 Medina, 2020, Thermo-oxidative decomposition behaviors of different sources of n-C7 asphaltenes under high-pressure conditions, Energy Fuels, 34, 8740, 10.1021/acs.energyfuels.0c01234 Al-muntaser, 2021, Hydrogen donating capacity of water in catalytic and non-catalytic aquathermolysis of extra-heavy oil: deuterium tracing study, Fuel, 283, 10.1016/j.fuel.2020.118957 Sun, 2015, Characterization of asphaltene isolated from low-temperature coal tar, Fuel Process Technol, 138, 413, 10.1016/j.fuproc.2015.05.008 Manasrah, 2020, Oxy-cracking technique for producing non-combustion products from residual feedstocks and cleaning up wastewater, Appl. Energy, 280, 10.1016/j.apenergy.2020.115890 Rakhmatullin, 2018, Application of high resolution NMR (1H and 13C) and FTIR spectroscopy for characterization of light and heavy crude oils, J Pet Sci Eng, 168, 256, 10.1016/j.petrol.2018.05.011 Aliev, 2021, In-situ heavy oil aquathermolysis in the presence of nanodispersed catalysts based on transition metals, Processes, 9, 127, 10.3390/pr9010127 Li, 2016, Catalytic aquathermolysis of super-heavy oil: cleavage of C-S bonds and separation of light organosulfurs, Fuel Process Technol, 153, 94, 10.1016/j.fuproc.2016.06.007