Crude Oil Oxidation in an Air Injection Based Enhanced Oil Recovery Process: Chemical Reaction Mechanism and Catalysis

[1]  Wan-fen Pu,et al.  Thermo-oxidative characteristics and kinetics of light, heavy, and extra-heavy crude oils using accelerating rate calorimetry , 2022, Fuel.

[2]  M. Varfolomeev,et al.  Catalytic combustion of heavy crude oil by oil-dispersed copper-based catalysts: Effect of different organic ligands , 2022, Fuel.

[3]  A. Kovscek,et al.  Analysis and comparison of in-situ combustion chemical reaction models , 2021, Fuel.

[4]  J. Qajar,et al.  Synergistic effects of ultrasonic irradiation and α-Fe2O3 nanoparticles on the viscosity and thermal properties of an asphaltenic crude oil and their application to in-situ combustion EOR , 2021, Ultrasonics.

[5]  M. Varfolomeev,et al.  Oxidation of Heavy Oil Using Oil-Dispersed Transition Metal Acetylacetonate Catalysts for Enhanced Oil Recovery , 2021, Energy & Fuels.

[6]  M. Varfolomeev,et al.  Catalytic combustion of heavy oil using γ-Fe2O3 nanocatalyst in in-situ combustion process , 2021, Journal of Petroleum Science and Engineering.

[7]  M. Varfolomeev,et al.  Fundamental insight into pyrolysis and oxidation process of ferric (III) stearate , 2021, Journal of Analytical and Applied Pyrolysis.

[8]  R. Zhao,et al.  Catalytic effects of Al2O3 nano-particles on thermal cracking of heavy oil during in-situ combustion process , 2021 .

[9]  Wei Li,et al.  Properties, combustion behavior, and kinetic triplets of coke produced by low-temperature oxidation and pyrolysis: Implications for heavy oil in-situ combustion , 2021, Petroleum Science.

[10]  M. Varfolomeev,et al.  Effect of copper stearate as catalysts on the performance of in-situ combustion process for heavy oil recovery and upgrading , 2021 .

[11]  M. Varfolomeev,et al.  Oil-Dispersed α-Fe2O3 Nanoparticles as a Catalyst for Improving Heavy Oil Oxidation , 2021, Energy & Fuels.

[12]  Jing Huo,et al.  Evolution of mass losses and evolved gases of crude oil and its SARA components during low-temperature oxidation by isothermal TG–FTIR analyses , 2021, Journal of Thermal Analysis and Calorimetry.

[13]  L. Yakimova,et al.  Improving heavy oil oxidation performance by oil-dispersed CoFe2O4 nanoparticles in In-situ combustion process for enhanced oil recovery , 2021 .

[14]  M. Varfolomeev,et al.  Mechanistic and kinetic insight into catalytic oxidation process of heavy oil in in-situ combustion process using copper (Ⅱ) stearate as oil soluble catalyst , 2021 .

[15]  Wan-fen Pu,et al.  Low-temperature oxidation of heavy crude oil characterized by TG, DSC, GC-MS, and negative ion ESI FT-ICR MS , 2021 .

[16]  M. V. Kok,et al.  Effect of inlet pressure on crude oil combustion -laboratory approach- , 2020 .

[17]  J. Sheng,et al.  Experimental study on the oxidation behaviors of Wolfcamp light crude oil and its saturate, aromatic and resin fractions using accelerated rate calorimetry tests , 2020 .

[18]  Wan-fen Pu,et al.  Low-temperature combustion characteristics of heavy oils by a self-designed porous medium thermo-effect cell , 2020 .

[19]  Wan-fen Pu,et al.  Oxidation characteristics of heavy oil and its SARA fractions during combustion using TG-FTIR , 2020 .

[20]  R. G. Moore,et al.  High-pressure air injection laboratory-scale numerical models of oxidation experiments for Kirsanovskoye oil field , 2020 .

[21]  M. Varfolomeev,et al.  Interaction between aromatics and n-alkane for in-situ combustion process , 2020 .

[22]  A. Turta,et al.  THAI process: Determination of the quality of burning from gas composition taking into account the coke gasification and water-gas shift reactions , 2020 .

[23]  Wan-fen Pu,et al.  Low-temperature combustion behavior of crude oils in porous media under air flow condition for in-situ combustion (ISC) process , 2020 .

[24]  M. Khelkhal,et al.  Thermal Study on Stabilizing the Combustion Front via Bimetallic Mn@Cu Tallates during Heavy Oil Oxidation , 2020 .

[25]  M. Khelkhal,et al.  Kinetic Study on Heavy Oil Oxidation by Copper Tallates , 2019, Energy & Fuels.

[26]  Shufeng Pei,et al.  Flammability and Explosion Characteristics of Methane in Oxygen-Reduced Air and Its Application in Air Injection IOR Process , 2019, Energy & Fuels.

[27]  M. Varfolomeev,et al.  Combustion behavior of aromatics and their interaction with n-alkane in in-situ combustion enhanced oil recovery process: Thermochemistry , 2019, Journal of Industrial and Engineering Chemistry.

[28]  Teng-Fei Wang,et al.  Catalytic Effect of Cobalt Additive on the Low Temperature Oxidation Characteristics of Changqing Tight Oil and Its SARA Fractions , 2019, Energies.

[29]  M. Varfolomeev,et al.  Integrative Investigation of Low-Temperature Oxidation Characteristics and Mechanisms of Heavy Crude Oil , 2019, Industrial & Engineering Chemistry Research.

[30]  M. Khelkhal,et al.  Impact of Iron Tallate on the Kinetic Behavior of the Oxidation Process of Heavy Oils , 2019, Energy & Fuels.

[31]  M. Varfolomeev,et al.  Comparison of oxidation behavior of linear and branched alkanes , 2019, Fuel Processing Technology.

[32]  Z. Fan,et al.  Enhanced in situ combustion of heavy crude oil by nickel oxide nanoparticles , 2019, International Journal of Energy Research.

[33]  H. Choi,et al.  Synthesis and thermal analysis of hydrophobic iron oxide nanoparticles for improving in-situ combustion efficiency of heavy oils , 2019, Journal of Industrial and Engineering Chemistry.

[34]  Wan-fen Pu,et al.  Thermal Behavior and Kinetic Triplets of Heavy Crude Oil and Its SARA Fractions during Combustion by High-Pressure Differential Scanning Calorimetry , 2019, Energy & Fuels.

[35]  Wan-fen Pu,et al.  Comparative evaluation on the thermal behaviors and kinetics of combustion of heavy crude oil and its SARA fractions , 2019, Fuel.

[36]  Bing Wei,et al.  Integrative determination of the interactions between SARA fractions of an extra-heavy crude oil during combustion , 2018, Fuel.

[37]  M. Varfolomeev,et al.  EPR as a complementary tool for the analysis of low-temperature oxidation reactions of crude oils , 2018, Journal of Petroleum Science and Engineering.

[38]  M. Varfolomeev,et al.  Copper stearate as a catalyst for improving the oxidation performance of heavy oil in in-situ combustion process , 2018, Applied Catalysis A: General.

[39]  Weipeng Yang,et al.  Low temperature oxidation of crude oil: Reaction progress and catalytic mechanism of metallic salts , 2018, Fuel.

[40]  Jia Yao,et al.  Application of In-situ combustion for heavy oil production in China: A Review , 2018, Journal of Oil, Gas and Petrochemical Sciences.

[41]  Wan-fen Pu,et al.  Oxidation Behavior and Kinetics of Eight C20–C54 n-Alkanes by High Pressure Differential Scanning Calorimetry (HP-DSC) , 2018, Energy & Fuels.

[42]  Dong Liu,et al.  Influence of Conversion Conditions on Heavy-Oil Coking During in Situ Combustion Process , 2018 .

[43]  M. Varfolomeev,et al.  Oxidation Behavior and Kinetics of Light, Medium, and Heavy Crude Oils Characterized by Thermogravimetry Coupled with Fourier Transform Infrared Spectroscopy , 2018 .

[44]  E. V. Kopylova,et al.  Oxidation Behavior of Light Crude Oil and Its SARA Fractions Characterized by TG and DSC Techniques: Differences and Connections , 2017 .

[45]  J. Wood,et al.  Laboratory investigation of CAPRI catalytic THAI-add-on process for heavy oil production and in situ upgrading , 2017 .

[46]  Qiang Zhang,et al.  Chemical-structural properties of the coke produced by low temperature oxidation reactions during crude oil in-situ combustion , 2017 .

[47]  M. V. Kok,et al.  Thermal characterization of crude oils in the presence of limestone matrix by TGA-DTG-FTIR , 2017 .

[48]  M. Varfolomeev,et al.  Crude oil characterization using TGA-DTA, TGA-FTIR and TGA-MS techniques , 2017 .

[49]  Q. Song,et al.  Interaction between saturates, aromatics and resins during pyrolysis and oxidation of heavy oil , 2017 .

[50]  A. Kovscek,et al.  Analysis of the effects of copper nanoparticles on in-situ combustion of extra heavy-crude oil , 2017 .

[51]  J. Wood,et al.  In-situ catalytic upgrading of heavy oil using dispersed bionanoparticles supported on gram-positive and gram-negative bacteria , 2017 .

[52]  Zhangxin Chen,et al.  An Improved Kinetics Model for In-Situ Combustion of Pre-Steamed Oil Sands , 2017 .

[53]  Pengcheng Liu,et al.  Enhanced oil recovery by air-foam flooding system in tight oil reservoirs: Study on the profile-controlling mechanisms , 2017 .

[54]  M. V. Kok,et al.  Thermal decomposition of Tatarstan Ashal’cha heavy crude oil and its SARA fractions , 2016 .

[55]  J. Lloyd,et al.  Upgrading of heavy oil by dispersed biogenic magnetite catalysts , 2016 .

[56]  M. V. Kok,et al.  Thermal, kinetics, and oxidation mechanism studies of light crude oils in limestone and sandstone matrix using TG-DTG-DTA: Effect of heating rate and mesh size , 2016 .

[57]  James J. Sheng,et al.  Numerical modeling on air injection in a light oil reservoir: Recovery mechanism and scheme optimization , 2016 .

[58]  J. Wood,et al.  A comparative study of fixed-bed and dispersed catalytic upgrading of heavy crude oil using-CAPRI , 2015 .

[59]  Yibo Li,et al.  Thermal Characteristics and Combustion Kinetics Analysis of Heavy Crude Oil Catalyzed by Metallic Additives , 2015 .

[60]  Wan-fen Pu,et al.  Characterizing the Fuel Deposition Process of Crude Oil Oxidation in Air Injection , 2015 .

[61]  H. Bruining,et al.  Recovery of light oil by air injection at medium temperature: Experiments , 2015 .

[62]  G. Vitale,et al.  Preparation of NiMoS nanoparticles for hydrotreating , 2015 .

[63]  Zheng Chen,et al.  Catalytic Effect of Transition Metallic Additives on the Light Oil Low-Temperature Oxidation Reaction , 2015 .

[64]  Wan-fen Pu,et al.  Low-Temperature Oxidation and Characterization of Heavy Oil via Thermal Analysis , 2015 .

[65]  Fa-yang Jin,et al.  The Kinetic Analysis of Oxidized Oil During the High Pressure Air Injection by Thermal Kinetic Analysis , 2015 .

[66]  Nashaat N. Nassar,et al.  Comparing kinetics and mechanism of adsorption and thermo-oxidative decomposition of Athabasca asphaltenes onto TiO2, ZrO2, and CeO2 nanoparticles , 2014 .

[67]  Y. Mortazavi,et al.  Enhanced pyrolysis and oxidation of asphaltenes adsorbed onto transition metal oxides nanoparticles towards advanced in-situ combustion EOR processes by nanotechnology , 2014 .

[68]  Qiang Zhang,et al.  The oxidation of heavy oil: Thermogravimetric analysis and non-isothermal kinetics using the distributed activation energy model , 2014 .

[69]  I. Gates,et al.  Low-temperature oxidation of Lloydminster heavy oil: Kinetic study and product sequence estimation , 2014 .

[70]  Mustafa Versan Kok,et al.  DSC study on combustion and pyrolysis behaviors of Turkish crude oils , 2013 .

[71]  M. Ranjbar,et al.  Thermocatalytic in situ combustion: Influence of nanoparticles on crude oil pyrolysis and oxidation , 2013 .

[72]  Kiymet Gizem Gul,et al.  Combustion characteristics and kinetic analysis of Turkish crude oils and their SARA fractions by DSC , 2013, Journal of Thermal Analysis and Calorimetry.

[73]  German Luna,et al.  Kinetics of the catalytic thermo-oxidation of asphaltenes at isothermal conditions on different metal oxide nanoparticle surfaces , 2013 .

[74]  A. Kovscek,et al.  An experimental investigation of the in-situ combustion behavior of Karamay crude oil , 2013 .

[75]  Tayfun Babadagli,et al.  Enhancement of the efficiency of in situ combustion technique for heavy-oil recovery by application of nickel ions , 2013 .

[76]  M. Husein,et al.  Oxidation of asphaltenes adsorbed onto NiO nanoparticles , 2012 .

[77]  N. Nassar,et al.  Iron oxide nanoparticles for rapid adsorption and enhanced catalytic oxidation of thermally cracked asphaltenes , 2012 .

[78]  S. Ren,et al.  Low-Temperature Oxidation of Oil Components in an Air Injection Process for Improved Oil Recovery , 2011 .

[79]  Murat Cinar,et al.  Combustion Kinetics of Heavy Oils in Porous Media , 2011 .

[80]  M. V. Kok Characterization of medium and heavy crude oils using thermal analysis techniques , 2011 .

[81]  N. Nassar,et al.  Metal Oxide Nanoparticles for Asphaltene Adsorption and Oxidation , 2011 .

[82]  R. Hughes,et al.  Comparison of conventional and catalytic in-situ combustion processes for oil recovery , 2009 .

[83]  N. Mahinpey,et al.  IN SITU COMBUSTION IN ENHANCED OIL RECOVERY (EOR): A REVIEW , 2007 .

[84]  M. Greaves,et al.  In Situ Upgrading of Athabasca Tar Sand Bitumen Using Thai , 2006 .

[85]  A. T. Turta,et al.  Current Status of the Commercial In Situ Combustion (ISC) Projects and New Approaches to Apply ISC , 2005 .

[86]  M. V. Kok,et al.  Characterization and Kinetics of Light Crude Oil Combustion in the Presence of Metallic Salts , 2004 .

[87]  R. G. Moore,et al.  Investigation of the Oxidation Behaviour of Hydrocarbon and Crude Oil Samples Utilizing DSC Thermal Techniques , 2004 .

[88]  R. G. Moore,et al.  The Research of Oxidation and Ignition Behaviour of Saturated Hydrocarbon Sample With Crude Oils Using TG/DTG and DTA Thermal Analysis Techniques , 2002 .

[89]  Malcolm Greaves,et al.  THAI-New Air Injection Technology for Heavy Oil Recovery and In Situ Upgrading , 2001 .

[90]  R. Hughes,et al.  Oxidation Reactions of a Light Crude Oil and Its SARA Fractions in Consolidated Cores , 2001 .

[91]  R. G. Moore,et al.  Ramped Temperature Oxidation Analysis of Athabasca Oil Sands Bitumen , 1999 .

[92]  R. Rathbone,et al.  Oxidation kinetics of north sea light crude oils at reservoir temperature , 1999 .

[93]  B. Verkoczy,et al.  Oxidation Of Heavy Oils And Their Sara Fractions - Its Role In Modelling In-Situ Combustion , 1997 .

[94]  James G. Speight,et al.  Oxidation of petroleum fractions , 1973 .