Thermal Decomposition of Kerogen in High-Carbon Domanic Rock of the Romashkino Oilfield in Sub- and Supercritical Water

Nasyrova, Z. R.; Kayukova, G. P.; Shunina, Elena N.; Islamova, G. G.; Batalin, G. A.; Морозова, Е. В.; Vakhin, Аlexey V.; Нургалиев, Д. К.

doi:10.1021/acs.energyfuels.1c04415

Cited by 13 publications

(5 citation statements)

References 60 publications

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“…The decreasing trend in X brn and the A factor with temperature indicated the cleavage of branched side chains of kerogen macromolecules, which could also be demonstrated by the increase in saturates and aromatic contents of generated oil and in gas yield. The results were consistent with Nasyrova’s study that the A factor and C factor of the spent kerogen decreased with reaction temperature from 320 to 420 °C. The value of the C factor varied differently from Hou’s pyrolysis results, in which the C factor of spent kerogen decreased from 300 to 400 °C but increased at 420 °C.…”

Section: Resultssupporting

confidence: 92%

Experimental Study on Hydrocarbon Generation Characteristics of Type II Kerogen from Low-Maturity Shale in Supercritical Water

Zhao,

Bawaa,

Xie

et al. 2023

Ind. Eng. Chem. Res.

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Supercritical water conversion of low-maturity shale is a promising method to produce oil and gas. Hydrocarbon generation from kerogen is influenced by inorganic minerals in shale. This study aims to clarify hydrocarbon generation characteristics of pure kerogen in supercritical water by removing inorganic minerals by acid-pickling. A series of experiments on hydrocarbon generation of kerogen in the temperature range of 300−700 °C were carried out in a batch reactor, and the produced oil and gas were quantitatively analyzed. The results showed that when the temperature increased, the oil yield had experienced a variation of first an increase and then a decrease with a peak value of 0.19 g/gTOC at 380 °C, while the gas yield continued to increase to 0.88 g/gTOC at 700 °C. By increasing the temperature from 300 to 500 °C, it would favor producing high quality oil with more light distillates (70% at 500 °C) and less asphaltene (5% at 500 °C). The main gas products were methane, hydrogen, and carbon dioxide as well as C 2+ hydrocarbons. The proportion of hydrogen increased with temperature (30% at 700 °C), while the proportion of methane peaked to 51% at 600 °C. Elevated temperatures in a supercritical water atmosphere increase ring-opening processes and the cleavage of branched side chains, boosting the maturation of the kerogen.

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Section: Resultssupporting

confidence: 92%

Experimental Study on Hydrocarbon Generation Characteristics of Type II Kerogen from Low-Maturity Shale in Supercritical Water

Zhao,

Bawaa,

Xie

et al. 2023

Ind. Eng. Chem. Res.

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“…All of the studied asphaltenes have the same SFR/VP ratio. This indicates that the catalytic action of carbonate rock does not affect the condensed naphthenoaromatic structures in which SFR and VP are localized, unlike high-temperature processes in which demetalization begins at temperatures above 300 • C [28]. Thus, the activity of natural carbonate rocks in the processes of low-temperature (25 • C) conversion of petroleum components was proven.…”

Section: Changes In the Composition Of High-molecular Oil Componentsmentioning

confidence: 93%

Catalytic Conversion of Oil in Model and Natural Reservoir Rocks

et al. 2023

Self Cite

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The catalytic activity of metal oxides in the processes of low- and high-temperature oxidation (LTO and HTO, respectively) of oil was studied on model systems consisting of oil-saturated quartz sand with additives of Al2O3, Cr2O3 and MgO using thermal analysis methods. The used additives were shown to shift the LTO and HTO processes to the low-temperature region. The catalytic activity of a natural reservoir carbonate rock without and with water was studied. This study established that at room temperature in dry carbonate rock, the oil components undergo dealkylation and polycondensation of aromatic fragments for a week. In the presence of water, the polycondensation processes are suppressed, and the cracking of resin and asphaltene occurs. The cracking reactions lead to a decrease in the content of heteroatoms in resins and asphaltenes.

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“…Kerogen is a complex mixture of organic compounds, consisting of a high-molecular structure with a large organic carbon content [26,27]. Under thermal stimulation, kerogen decomposes into various bituminous products, which further crack into different low-carbon products [28].…”

Section: Building Modelmentioning

confidence: 99%

Theoretical Analysis of the Effect of Electrical Heat In Situ Injection on the Kerogen Decomposition for the Development of Shale Oil Deposits

Montilla

Zhang

et al. 2023

Energies

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In situ heat injection is a suitable technique for extracting shale oil from reservoirs with high organic matter content but insufficient thermal maturation. To optimize the stimulation process and to avoid unnecessary energy consumption, understanding the thermal process and the effects of thermal parameters is crucial. This research employs a self-developed simulator to build a 2D numerical model of the in situ conversion process of kerogen with electric heaters. A benchmark model is first established to determine the effects of heat injection on crude oil production and kerogen decomposition. Subsequently, this study analyzes the evolution of shale oil within the reservoir, identifying the role of thermal and physical properties in crude oil production and kerogen decomposition during the stimulation treatment. A sensitivity analysis of the thermal properties of the reservoir is also carried out, which allows for defining the role of the thermal conductivity of the rock during the stimulation process. Finally, it is observed that, when using the injection at a constant power, the injection time to achieve a suitable large rate of decomposition is shorter than at a constant temperature—consequently, it has a higher economic advantage.

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Thermal Decomposition of Kerogen in High-Carbon Domanic Rock of the Romashkino Oilfield in Sub- and Supercritical Water

Cited by 13 publications

References 60 publications

Experimental Study on Hydrocarbon Generation Characteristics of Type II Kerogen from Low-Maturity Shale in Supercritical Water

Experimental Study on Hydrocarbon Generation Characteristics of Type II Kerogen from Low-Maturity Shale in Supercritical Water

Catalytic Conversion of Oil in Model and Natural Reservoir Rocks

Theoretical Analysis of the Effect of Electrical Heat In Situ Injection on the Kerogen Decomposition for the Development of Shale Oil Deposits

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