Enhanced pyrolysis and oxidation of asphaltenes adsorbed onto transition metal oxides nanoparticles towards advanced in-situ combustion EOR processes by nanotechnology

“…Hence, metakaolin surface contribution generates a synergetic effect in the R-A steam gasification in comparison with the results observed for functionalized clay. The main decomposition peak for R-A mixture is observed at 773 K, which is attributed to aromatics rings decomposition [13]. However, in the presence of the synthesized metakaolin-supported catalysts, this temperature can be reduced significantly, probably related to the chemical content (Al 2 O 3 and SiO 2 ) and the pore size distribution that could determine the interaction degree of the adsorbed species and the adsorbate.…”

“…Under inert atmosphere R-A is converted mainly to CO 2 , light hydrocarbons, and CH 4 with a less extent. Also, oxygen sources present on catalyst structure and R-A functional groups are probably used in CO 2 production during the thermal cracking by the reaction of free carbon radicals and the oxygen sources [13]. From Figure 9a,b it is observed that steam injection has hydrogen source contribute to a less condensation of light hydrocarbons by the cracking of LCH and saturation of free radicals [59], which means a higher yield in methane production under steam atmosphere.…”

“…Different gasses could be detected during the cracking of heavy oil compounds, predominately CO 2 , H 2 , CO, CH 4 , and O 2 in the steam gasification process [101]. The characteristic intensity of the adsorption bands at 2149, 2349, 3016 and 2750 cm −1 were analyzed respectively for CO, CO 2 , CH 4 , and other light hydrocarbons, respectively [13]. All experiments were performed in duplicate to confirm reproducibility.…”

Metal Oxide Nanoparticles Supported on Macro-Mesoporous Aluminosilicates for Catalytic Steam Gasification of Heavy Oil Fractions for On-Site Upgrading

“…Hence, metakaolin surface contribution generates a synergetic effect in the R-A steam gasification in comparison with the results observed for functionalized clay. The main decomposition peak for R-A mixture is observed at 773 K, which is attributed to aromatics rings decomposition [13]. However, in the presence of the synthesized metakaolin-supported catalysts, this temperature can be reduced significantly, probably related to the chemical content (Al 2 O 3 and SiO 2 ) and the pore size distribution that could determine the interaction degree of the adsorbed species and the adsorbate.…”

“…Under inert atmosphere R-A is converted mainly to CO 2 , light hydrocarbons, and CH 4 with a less extent. Also, oxygen sources present on catalyst structure and R-A functional groups are probably used in CO 2 production during the thermal cracking by the reaction of free carbon radicals and the oxygen sources [13]. From Figure 9a,b it is observed that steam injection has hydrogen source contribute to a less condensation of light hydrocarbons by the cracking of LCH and saturation of free radicals [59], which means a higher yield in methane production under steam atmosphere.…”

“…Different gasses could be detected during the cracking of heavy oil compounds, predominately CO 2 , H 2 , CO, CH 4 , and O 2 in the steam gasification process [101]. The characteristic intensity of the adsorption bands at 2149, 2349, 3016 and 2750 cm −1 were analyzed respectively for CO, CO 2 , CH 4 , and other light hydrocarbons, respectively [13]. All experiments were performed in duplicate to confirm reproducibility.…”

Metal Oxide Nanoparticles Supported on Macro-Mesoporous Aluminosilicates for Catalytic Steam Gasification of Heavy Oil Fractions for On-Site Upgrading

“…However, most of these techniques do not exceed 20 %-25 % oil recovery or 50 % for the steam-assisted gravity drainage (SAGD) process (Butler 1998;Nasr et al 2003;Hashemi et al 2013). Nanoparticle technology has emerged as an alternative with a great potential to improve the previously mentioned techniques and increase oil recovery (Hashemi et al 2014a, b, c;Galarraga and Pereira-Almao 2010;Hashemi et al 2012;Franco et al 2013aFranco et al , b, 2014Hosseinpour et al 2014). …”

“…Because of their small sizes, high surface area/volume ratios, and tunable chemical characteristics, nanoparticles have exceptional adsorptive and catalytic properties and can be employed for in situ adsorption and post-adsorption catalytic cracking of heavy hydrocarbons, such as asphaltenes (Nassar et al 2011a(Nassar et al , b, c, d, e, 2012a(Nassar et al , b, 2013bNassar 2010;Franco et al 2013c;Hosseinpour et al 2014;Hashemi et al 2014c). It has been demonstrated that with advanced research, nanoparticles can be used to sustain the heavy oil industry via the development of environmentally sound processes with cost-effective approaches.…”

Kinetics and mechanisms of the catalytic thermal cracking of asphaltenes adsorbed on supported nanoparticles

Nanoparticles for Heavy Oil In Situ Upgrading