SOCAR Proceedings

SOCAR Proceedings

Published by "OilGasScientificResearchProject" Institute of State Oil Company of Azerbaijan Republic (SOCAR).

SOCAR Proceedings is published from 1930 and is intended for oil and gas industry specialists, post-graduate (students) and scientific workers.

Journal is indexed in Web of Science (Emerging Sources Citation Index), SCOPUS and Russian Scientific Citation Index, and abstracted in EI’s Compendex, Petroleum Abstracts (Tulsa), Inspec, Chemical Abstracts database.

R. A. Gasumov1, E. R. Gasumov2,3, V. M. Veliyev3, V. A. Gasumov4

1North Caucasus Federal University, Stavropol, Russia; 2Azerbaijan State University of Oil and Industry, Baku, Azerbaijan; 3Azerbaijan Technical University, Baku, Azerbaijan; 4Azerbaijan Engineering University, Baku, Azerbaijan

Technical and economic aspects of monitoring CO2 distribution in geological structure using gravımetric methods


The article addresses the reduction of carbon dioxide (CO2) emissions by placing them in geological structures. The technical and economic aspects of monitoring the distribution of carbon dioxide in geological structures, including technical, economic and environmental issues related to long-term storage of CO2 in geological formations, are studied. The need to ensure the reliability of carbon dioxide disposal and control their condition in the layers of the underground storage is considered. The main aspects of monitoring the distribution of carbon dioxide in the geological structure by gravimetric methods, including by the volume of the structural trap during its disposal, are studied. The article studies the features of the distribution of carbon dioxide in the reservoir with the initial saturation of the reservoir with low-density reservoir fluid and the possibility of activating gas-dynamic risks. The issue of the distribution and rate of distribution of carbon dioxide by the volume of the natural trap is considered. It is substantiated that gravity prospecting monitoring allows tracking the current state of the geological structure into which CO is injected and timely strengthening control over the tightness of old wells during the distribution of carbon dioxide in the area of their location. The possibility of using gravimetric monitoring of the distribution of carbon dioxide in the geological structure is substantiated and the possibility of constructing indicator maps and graphs characterizing the distribution of fluid in the trap is considered.

Keywords: technical and economic aspects; deposit; carbon dioxide (CO2); gravity exploration; reservoir; structural trap; CO2 placement; geological structure.

Date submitted: 09.09.2025     Date accepted: 23.02.2026

The article addresses the reduction of carbon dioxide (CO2) emissions by placing them in geological structures. The technical and economic aspects of monitoring the distribution of carbon dioxide in geological structures, including technical, economic and environmental issues related to long-term storage of CO2 in geological formations, are studied. The need to ensure the reliability of carbon dioxide disposal and control their condition in the layers of the underground storage is considered. The main aspects of monitoring the distribution of carbon dioxide in the geological structure by gravimetric methods, including by the volume of the structural trap during its disposal, are studied. The article studies the features of the distribution of carbon dioxide in the reservoir with the initial saturation of the reservoir with low-density reservoir fluid and the possibility of activating gas-dynamic risks. The issue of the distribution and rate of distribution of carbon dioxide by the volume of the natural trap is considered. It is substantiated that gravity prospecting monitoring allows tracking the current state of the geological structure into which CO is injected and timely strengthening control over the tightness of old wells during the distribution of carbon dioxide in the area of their location. The possibility of using gravimetric monitoring of the distribution of carbon dioxide in the geological structure is substantiated and the possibility of constructing indicator maps and graphs characterizing the distribution of fluid in the trap is considered.

Keywords: technical and economic aspects; deposit; carbon dioxide (CO2); gravity exploration; reservoir; structural trap; CO2 placement; geological structure.

Date submitted: 09.09.2025     Date accepted: 23.02.2026

References

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  7. Azarov, S. S., Prishivalko, N. I. (2002). Results of repeated gravimetric observations of an exploited gas deposit. Exploration Geophysics, 39, 97-101.
  8. Lozhevsky, M. I., Mikhailov, I. N., Rosenberg, V. N., Chertovskikh, K. A. (2002). Gravimetric control in the development of hydrocarbon fields and operation of underground gas storage facilities. Exploration and Protection of Subsoil, 2, 23-26.
  9. Lozhevsky, M. I., Mikhailov, I. N., Chertovskikh, K. A. (2002). Possibilities of gravity exploration in the search for and study of underground structures. Exploration and Protection of Subsoil, 2, 38-41.
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  11. Soromotin, A. V., Lekomtsev, A. V., Ilyushin, P. Yu. (2022). Analysis of the features of the application of CO₂ HUFTN-PUFF technology. Bulletin of the Tomsk Polytechnic University. Engineering of Georesources, 333(12), 178-189.
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  18. Dmitrievsky, A. N., Khan, S. A., Dorokhin, V. G. (2023). Geological repository of carbon dioxide. Theory, history and methodology. Moscow: Publishing House «FLINTA».
  19. Mikhailovsky, A. A. (2022). Formation gas losses at UGS in aquifers. Georesources, 24(3), 182-186.
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  24. Yetirmishli, G. J., Kazimova, S. E., Gadirov, Z. S. (2025). Investigation of the deep structure of the earth's crust of Azerbaijan and the Caspian region using the method of seismic tomography. SOCAR Proceedings, 3, 16-30.
  25. Drobyshev, M. N., Koneshov, V. N., Abramov, D. V., Malysheva, D. A. (2021). Improving the Accuracy of Gravimetric Observations Using Seismic Information. Geophysical Research, 22(3), 26-34.
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  27. Molev, V. P. (2019). Methodology and technology of ground-based gravimetric surveys. Vladivostok: Far Eastern Federal University.
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  30. Gasumov, E. R., Gasumov, R. А. (2025). Impact of injection of industrial liquid waste on hydrodynamic conditions of receiving horizon. Bulletin of the Tomsk Polytechnic University Geo Assets Engineering, 335(5), 37-48.
  31. Gasumov, E. R., Gasumov, R. А. (2024). Estimation of the hydrodynamic perfection of the well-reservoir system at the stage of opening a productive reservoir. Geology and Geophysics of Russian South, 14(4), 152-165.
  32. Gasumov, R. A., Gasumov, E. R., Valiev, V. M., Musaeva, F. (2024). Geological and technical-economic issues of designing underground gas storage facilities in reservoir formations. Geology and Geophysics of Russian South, 14(4), 152-165.
  33. Koneshov, V. N., Abramov, D. V., Drobyshev, N. V., Malysheva, D. A. (2023). Assessment of the influence of humidity on long-term high-precision measurements with the CG5 Autograv gravimeter. Geophysical Research, 24(2), 87-94.
  34. Gasumov, E., Veliyev, V., Gasumov, R., Suleymanov, G. (2024). Technical and economic aspects of reducing carbon dioxide emissions into the atmosphere. Reliability: Theory & Applications, 6(81), 2(19), 930-937.
  35. Los, A. S., Korolkov, V. K. (2023). Conditions for carbon dioxide disposal in an aquifer with further geophysical control. In: Proceedings «Innovative technologies in the oil and gas industry. Problems of sustainable development of territories».
  36. Belyaev, A. S., Rozenberg, V. N. (2016). The influence of measurement methodology on the results of high-precision gravimetric survey. Exploration Geophysics, 93, 129-133.
  37. Gasumov, R. A., Gasumov, E. R., Veliev, V. M., et al. (2022). Development of a three- dimensional geological model of the upper control horizons and near-surface sediments for investigation of the system of monitoring the tightness of the underground storage. Bulletin of the Tomsk Polytechnic University. Geo Аssets Engineering, 333(6), 86–95.
  38. Drobyshev, M. N., Koneshov, V. N. (2013). Estimation of the ultimate accuracy of the CG-5 Autograv Gravimeter. Seismic Instruments, 49(2), 39-43.
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DOI: 10.5510/OGP20260201190

E-mail: r.gasumov@yandex.ru


A. R. Deryaev1, Ch. Geldyeva1, D. S. Saduakassov2

1SRI of Natural Gas of the State Concern «Turkmengas», Ashgabat, Turkmenistan; 2Yessenov Caspian University of Technologies and Engineering, Aktau, Kazakhstan

Development of foam drilling fluids for drilling and well killing under conditions of abnormally low formation pressure


The paper presents the results of a comprehensive experimental study aimed at the development and justification of the efficiency of formulations of thermally stable foam solutions for drilling and temporary well killing under conditions of abnormally low formation pressures (ALFP). The purpose of the study is the development, laboratory testing, and validation of the functional efficiency of multicomponent foaming fluids optimized to solve two key tasks: minimizing overbalance pressure on the formation during drilling and creating a long-term blocking barrier during well killing. Experimental results showed that the influence of the type and concentration of surfactants, polymer additives (CMC-HV, ChemPAC-LV), a structure-forming agent (bentonite), and stabilizers (liquid glass, NaCl) on key functional properties was investigated, including density (0.50–0.88 g/cm³), foam expansion ratio (3.0–4.0), thermal stability (up to 130 °C), and long-term structural stability (up to 7 days). The scientific novelty of the study lies in the identification of a synergistic effect resulting from the use of local components - monoethanolamine (MEA) derived from waste products of the Maryazot production association and the surfactant Guwlydere - in combination with bentonite, which made it possible to achieve a minimum density of 0.50 g/cm³ and maximum stability of up to 7 days. These parameters are critically important for application under ALFP conditions. The developed formulations were successfully implemented at the Yashyldepe, Yolguyi, and Garashsyzlygyn 10-yyllygy fields, demonstrating a reduction in lost circulation mitigation costs by 30–50 % and an increase in well production rates.

Keywords: foam solution; drilling, well killing; lost circulation; well completion.

Date submitted: 16.10.2025     Date accepted: 17.02.2026

The paper presents the results of a comprehensive experimental study aimed at the development and justification of the efficiency of formulations of thermally stable foam solutions for drilling and temporary well killing under conditions of abnormally low formation pressures (ALFP). The purpose of the study is the development, laboratory testing, and validation of the functional efficiency of multicomponent foaming fluids optimized to solve two key tasks: minimizing overbalance pressure on the formation during drilling and creating a long-term blocking barrier during well killing. Experimental results showed that the influence of the type and concentration of surfactants, polymer additives (CMC-HV, ChemPAC-LV), a structure-forming agent (bentonite), and stabilizers (liquid glass, NaCl) on key functional properties was investigated, including density (0.50–0.88 g/cm³), foam expansion ratio (3.0–4.0), thermal stability (up to 130 °C), and long-term structural stability (up to 7 days). The scientific novelty of the study lies in the identification of a synergistic effect resulting from the use of local components - monoethanolamine (MEA) derived from waste products of the Maryazot production association and the surfactant Guwlydere - in combination with bentonite, which made it possible to achieve a minimum density of 0.50 g/cm³ and maximum stability of up to 7 days. These parameters are critically important for application under ALFP conditions. The developed formulations were successfully implemented at the Yashyldepe, Yolguyi, and Garashsyzlygyn 10-yyllygy fields, demonstrating a reduction in lost circulation mitigation costs by 30–50 % and an increase in well production rates.

Keywords: foam solution; drilling, well killing; lost circulation; well completion.

Date submitted: 16.10.2025     Date accepted: 17.02.2026

References

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  8. Dvoynikov, M. V., Minaev, Y. D. (2025). Mathematical model of non-pressurized flow for calculating killing of gas wells with abnormally low reservoir pressures. International Journal of Engineering, 38(7), 1677-1684.
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DOI: 10.5510/OGP20260201191

E-mail: annagulyderyayew@gmail.com


K. A. Bashmur1, A. V. Zagulyaev1, M. V. Nebylitsyn2

1Siberian Federal University, Krasnoyarsk, Russia; 2Schneider Electric, Fairfield, OH, United States of America

A hybrid bionic strategy to enhance the static characteristics of roller-cone bit bearings using CFD simulations


The service life of roller-cone drill bits is largely determined by the condition of their bearing units, which account for a significant share of drilling failures. Reducing friction and increasing load-carrying capacity in bearing assemblies are essential for improving rock-breaking efficiency and extending tool life. One promising approach is the use of a bionic surface texture, which stabilizes the lubricant film and redistributes pressure within the contact zone. In this work, a combined bionic surface texturing strategy is proposed for the thrust bearing of a roller-cone bit, integrating a phyllotactic-inspired distribution pattern with ellipsoidal micro-dimples in both symmetric and asymmetric configurations. A CFD model of the thrust bearing was developed using numerical simulations in ANSYS Fluent. Smooth and textured surfaces were compared. Analysis of pressure distribution and shear stress demonstrated that the combined texture increases the load-carrying capacity of the lubricant film by up to 9% and the phyllotactic pattern reduces the friction coefficient by more than two times compared to a smooth surface. Additionally, a comparison between the phyllotactic pattern and a linear arrangement of micro-dimples showed a 14% reduction in friction coefficient with a slight decrease in load-carrying capacity. The obtained results confirm the effectiveness of the bionic approach in the design of roller-cone bit bearings and can be applied to develop wear-resistant and energy-efficient structures that contribute to increasing the maintenance interval of drilling tools. 

Keywords: roller-cone bit; bearing; bionic surface texturing; phyllotactic; ellipsoidal dimples; CFD.

Date submitted: 24.11.2025     Date accepted: 09.02.2026

The service life of roller-cone drill bits is largely determined by the condition of their bearing units, which account for a significant share of drilling failures. Reducing friction and increasing load-carrying capacity in bearing assemblies are essential for improving rock-breaking efficiency and extending tool life. One promising approach is the use of a bionic surface texture, which stabilizes the lubricant film and redistributes pressure within the contact zone. In this work, a combined bionic surface texturing strategy is proposed for the thrust bearing of a roller-cone bit, integrating a phyllotactic-inspired distribution pattern with ellipsoidal micro-dimples in both symmetric and asymmetric configurations. A CFD model of the thrust bearing was developed using numerical simulations in ANSYS Fluent. Smooth and textured surfaces were compared. Analysis of pressure distribution and shear stress demonstrated that the combined texture increases the load-carrying capacity of the lubricant film by up to 9% and the phyllotactic pattern reduces the friction coefficient by more than two times compared to a smooth surface. Additionally, a comparison between the phyllotactic pattern and a linear arrangement of micro-dimples showed a 14% reduction in friction coefficient with a slight decrease in load-carrying capacity. The obtained results confirm the effectiveness of the bionic approach in the design of roller-cone bit bearings and can be applied to develop wear-resistant and energy-efficient structures that contribute to increasing the maintenance interval of drilling tools. 

Keywords: roller-cone bit; bearing; bionic surface texturing; phyllotactic; ellipsoidal dimples; CFD.

Date submitted: 24.11.2025     Date accepted: 09.02.2026

References

  1. Abbas, R. K. (2018). A review on the wear of oil drill bits (conventional and the state of the art approaches for wear reduction and quantification). Engineering Failure Analysis, 90, 554–584.
  2. Dai, X., Chen, P., Huang, T. (2024). Investigation on the rock failure characteristics and reliability of hybrid drill bits combing shaped PDC cutters and roller-cone elements. Geoenergy Science and Engineering, 239, 212976.
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DOI: 10.5510/OGP20260201192

E-mail: kbashmur@sfu-kras.ru


B. Т. Ratov1, V. A. Mechnik2, N. A. Bondarenko2, A. B. Kalzhanova3, V. A. Chishkala4, Z. T. Matayeva1, V. L. Khomenko5

1Kazakh National Research Technical University named after K. I. Satpayev, Almaty, Kazakhstan; 2V. Bakul Institute for Superhard Materials of the National Academy of Sciences of Ukraine, Kyiv, Ukraine; 3Caspian State University of Technology and Engineering named after Sh. Yesenov, Aktau, Kazakhstan; 4V. N. Karazin Kharkiv National University, Kharkiv, Ukraine; 5Dnipro University of Technology, Dnipro, Ukraine

Effect of dispersion strengthening on the performance of Cdiamond–(WC–CO) composite drilling tools


The study examines the effect of ZrO2 micropowder additive (at 3 and 6 wt%) on the mechanical performance and wear behavior of 25Cdiamond–(70.5WC–4.5Co) composites fabricated by spark plasma sintering (SPS), as well as the performance of impregnated drill bits based on these composites during exploration drilling in Kazakhstan. It was found that introducing 3 wt% ZrO2 into the 25Cdiamond–(70.5WC–4.5Co) composite reduces the wear rate by weight WR from 9.124±0.544 ⋅ 10–5 to 4.116±0.382 ⋅ 10–5 g/m, by volume WV from 9.237±0.645 ⋅ 10–12 to 4.220±0.424 ⋅ 10–12 m³/s, and the specific wear rate WS from 7.142±0.512 ⋅ 10–13 to 4.022±0.254 ⋅ 10–13 m³/(N ⋅ m). The twofold increase in wear resistance observed in the 25Cdiamond–(67.68WC–4.32Co)–3ZrO2 composite compared to the base 25Cdiamond–(70.5WC–4.5Co) is attributed to grain refinement of WC, improved fracture toughness, and the transformation of the metastable tetragonal phase t-ZrO2 into the thermodynamically stable monoclinic m-ZrO2 phase. Even lower wear values were recorded for the 25Cdiamond–(64.86WC–4.14Co)–6ZrO2 composite: WR = 2.107±0.204 ⋅ 10–5 g/m, WV = 2.102±0.162 ⋅ 10–12 m³/s, and WS = 1.724±0.118 ⋅ 10–13 m³/(N ⋅ m), which is approximately 4.3 times lower than those of the base sample. The superior wear resistance of the 6% ZrO2 composite is linked to a higher content of the monoclinic m-ZrO2 phase, resulting from a more complete transformation of t-ZrO2. Field tests showed that the drilling footage achieved by the impregnated core bit based on the 25Cdiamond–(64.86WC–4.14Co)–6ZrO2 composite was four times greater than that of the standard core bit based on the 25Cdiamond–(70.5WC–4.5Co) mixture during exploration drilling by «KazakhmysBarlau» LLP.

Keywords: diamond core drill bit; composite; tungsten carbide; cobalt; zirconium dioxide; wear resistance; spark plasma sintering.

Date submitted: 25.08.2025     Date accepted: 12.12.2025

The study examines the effect of ZrO2 micropowder additive (at 3 and 6 wt%) on the mechanical performance and wear behavior of 25Cdiamond–(70.5WC–4.5Co) composites fabricated by spark plasma sintering (SPS), as well as the performance of impregnated drill bits based on these composites during exploration drilling in Kazakhstan. It was found that introducing 3 wt% ZrO2 into the 25Cdiamond–(70.5WC–4.5Co) composite reduces the wear rate by weight WR from 9.124±0.544 ⋅ 10–5 to 4.116±0.382 ⋅ 10–5 g/m, by volume WV from 9.237±0.645 ⋅ 10–12 to 4.220±0.424 ⋅ 10–12 m³/s, and the specific wear rate WS from 7.142±0.512 ⋅ 10–13 to 4.022±0.254 ⋅ 10–13 m³/(N ⋅ m). The twofold increase in wear resistance observed in the 25Cdiamond–(67.68WC–4.32Co)–3ZrO2 composite compared to the base 25Cdiamond–(70.5WC–4.5Co) is attributed to grain refinement of WC, improved fracture toughness, and the transformation of the metastable tetragonal phase t-ZrO2 into the thermodynamically stable monoclinic m-ZrO2 phase. Even lower wear values were recorded for the 25Cdiamond–(64.86WC–4.14Co)–6ZrO2 composite: WR = 2.107±0.204 ⋅ 10–5 g/m, WV = 2.102±0.162 ⋅ 10–12 m³/s, and WS = 1.724±0.118 ⋅ 10–13 m³/(N ⋅ m), which is approximately 4.3 times lower than those of the base sample. The superior wear resistance of the 6% ZrO2 composite is linked to a higher content of the monoclinic m-ZrO2 phase, resulting from a more complete transformation of t-ZrO2. Field tests showed that the drilling footage achieved by the impregnated core bit based on the 25Cdiamond–(64.86WC–4.14Co)–6ZrO2 composite was four times greater than that of the standard core bit based on the 25Cdiamond–(70.5WC–4.5Co) mixture during exploration drilling by «KazakhmysBarlau» LLP.

Keywords: diamond core drill bit; composite; tungsten carbide; cobalt; zirconium dioxide; wear resistance; spark plasma sintering.

Date submitted: 25.08.2025     Date accepted: 12.12.2025

References

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DOI: 10.5510/OGP20260201193

E-mail: inteldriller@gmail.com


R. R. Ilyazov, A. Kh. Shakhverdiev

Sergo Ordzhonikidze Russian State University for Geological Prospecting (MGRI), Moscow, Russia

Real-time determination of fluid contacts during horizontal well drilling using mud gas logging


The article analyzes real-time detection of gas-oil (GOC) and oil-water (OWC) contacts during horizontal drilling in clastic reservoirs. Timely localization ensures high-quality geosteering, keeping the wellbore within the pay zone and preventing undesirable fluid intersections. Relying solely on conventional logging-while-drilling (LWD) is often insufficient. Limitations arise from electrical macroanisotropy distorting resistivity data, the clay electrical double layer masking responses, and tool «blind zones» causing delayed observations, which poses a critical risk in horizontal drilling. To address this, advanced mud gas logging is proposed. Instead of indirect electrophysical features, this method captures actual reservoir fluid dynamics. By using chromatographic analysis of C1–C5 fractions and calculating Wetness, Balance, and Pixler ratios, characteristic fluid signatures and transition zones are identified. Crucially, reliable interpretation requires mathematical normalization of gas data. Without it, operational artifacts from rate of penetration (ROP) and mud flow rate fluctuations create false anomalies or obscure actual boundaries. An Eastern Siberian field case study demonstrates that normalized mud gas logging achieved real-time GOC localization with sub-meter accuracy in a low-contrast reservoir. Validated by pulsed neutron logging (PNL),
this method proves to be an effective geosteering and risk management tool.

Keywords: mud gas logging; horizontal wells; gas-oil contact (GOC); oil-water contact (OWC); geosteering; mud logging; gas chromatography; gas data normalization.

Date submitted: 18.05.2026     Date accepted: 11.06.2026

The article analyzes real-time detection of gas-oil (GOC) and oil-water (OWC) contacts during horizontal drilling in clastic reservoirs. Timely localization ensures high-quality geosteering, keeping the wellbore within the pay zone and preventing undesirable fluid intersections. Relying solely on conventional logging-while-drilling (LWD) is often insufficient. Limitations arise from electrical macroanisotropy distorting resistivity data, the clay electrical double layer masking responses, and tool «blind zones» causing delayed observations, which poses a critical risk in horizontal drilling. To address this, advanced mud gas logging is proposed. Instead of indirect electrophysical features, this method captures actual reservoir fluid dynamics. By using chromatographic analysis of C1–C5 fractions and calculating Wetness, Balance, and Pixler ratios, characteristic fluid signatures and transition zones are identified. Crucially, reliable interpretation requires mathematical normalization of gas data. Without it, operational artifacts from rate of penetration (ROP) and mud flow rate fluctuations create false anomalies or obscure actual boundaries. An Eastern Siberian field case study demonstrates that normalized mud gas logging achieved real-time GOC localization with sub-meter accuracy in a low-contrast reservoir. Validated by pulsed neutron logging (PNL),
this method proves to be an effective geosteering and risk management tool.

Keywords: mud gas logging; horizontal wells; gas-oil contact (GOC); oil-water contact (OWC); geosteering; mud logging; gas chromatography; gas data normalization.

Date submitted: 18.05.2026     Date accepted: 11.06.2026

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DOI: 10.5510/OGP20260201194

E-mail: shahverdievah@mgri.ru


M. V. Kuzmina1, Sh. Z. Ismayilov2, R. R. Stepanova3, I. F. Galiullina3, I. G. Fattakhov1, A. A. Pimenov1, T. I. Iusifov4

1TatNIPIneft – PJSC TATNEFT, Almetyevsk, Russia; 2Azerbaijan Oil and Industry University, Baku, Azerbaijan; 3Ufa State Petroleum Technical University, Ufa, Russia; 4RN-BashNIPIneft LLC (Rosneft Oil Company), Ufa, Russia

Justification of the effectiveness of the technology of low-mineralized flooding factory in the conditions of fractured carbonate reservoirs of the oil and gas condensate field


One of the promising EOR technologies is a relatively recent technique of injecting low-salinity water into carbonate reservoirs. There are some Russian and foreign papers studying the effect of changing the injected water properties on the rate of production and reservoir recovery. Most of the studies analyze the effect of water composition on terrigenous reservoirs, while there are few studies concerning carbonate reservoirs. Therefore, development of carbonate reservoirs and their waterflooding, in particular, is of great interest. The paper discusses production target III of an oil and gas condensate field, composed of the Bobrikovian carbonate rocks. This heterogeneous, tight, fractured reservoir is currently developed under depletion drive. Reservoir stimulation is not provided by design, which indicates deficiency of field development strategy, preventing exploitation of full potential of this reservoir. To obtain an objective, a problematic zones in production target III has been analyzed. This analysis considered cumulative production against a thickness map between OWC and the upper carbonate reservoir. An extensive analysis of water sources was carried out for future use of this water as a reservoir-repressuring agent, as well as compatibility of the injected water, reservoir rock, and underlying groundwater was analyzed with regard to predicted chemical reactions. Laboratory testing of core samples was performed using a gas permeameter-porosimeter. For estimating efficient parameters of a reservoir pressure maintenance system is well interference study. Understanding well interference in carbonate reservoirs is complicated by natural fracturing, so, Express Pressure Tool data has been interpreted to analyze well interference. 

Keywords: water flooding; injected water; salt content; reservoir rock; underlying groundwater compatibility.

Date submitted: 01.04.2025     Date accepted: 21.01.2026

One of the promising EOR technologies is a relatively recent technique of injecting low-salinity water into carbonate reservoirs. There are some Russian and foreign papers studying the effect of changing the injected water properties on the rate of production and reservoir recovery. Most of the studies analyze the effect of water composition on terrigenous reservoirs, while there are few studies concerning carbonate reservoirs. Therefore, development of carbonate reservoirs and their waterflooding, in particular, is of great interest. The paper discusses production target III of an oil and gas condensate field, composed of the Bobrikovian carbonate rocks. This heterogeneous, tight, fractured reservoir is currently developed under depletion drive. Reservoir stimulation is not provided by design, which indicates deficiency of field development strategy, preventing exploitation of full potential of this reservoir. To obtain an objective, a problematic zones in production target III has been analyzed. This analysis considered cumulative production against a thickness map between OWC and the upper carbonate reservoir. An extensive analysis of water sources was carried out for future use of this water as a reservoir-repressuring agent, as well as compatibility of the injected water, reservoir rock, and underlying groundwater was analyzed with regard to predicted chemical reactions. Laboratory testing of core samples was performed using a gas permeameter-porosimeter. For estimating efficient parameters of a reservoir pressure maintenance system is well interference study. Understanding well interference in carbonate reservoirs is complicated by natural fracturing, so, Express Pressure Tool data has been interpreted to analyze well interference. 

Keywords: water flooding; injected water; salt content; reservoir rock; underlying groundwater compatibility.

Date submitted: 01.04.2025     Date accepted: 21.01.2026

References

  1. Biserov, A. O. (2022). Overview of low-salinity flooding and its development. Enigma, 44, 124-127.
  2. Burdenyuk, O. O., Kozhevnikov, A. V. (2016). Review of the efficiency of using low-salinity flooding of terrigenous reservoirs. Nauchnyj Forum. Sibir, 2(4), 11.
  3. Aghdam, S. Kh., Kazemi, A., Ahmadi, M. (2023). Studying the effect of various surfactants on the possibility and intensity of fine migration during low-salinity water flooding in clay-rich sandstones. Results in Engineering, 18, 101149.
  4. Keller, Yu. A., Uskov, A. A., Krivoguz, A. N. (2020). Application of SVKTT technology to assess the efficiency of flooding with low-mineralized water of the carbonate formation of the Kharyaginskoye field. Oil Industry, 7, 109-113.
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  7. Podzorova, M. S., Aminov, K. Yu. (2020). Flooding of rocks of the Bazhenov formation with low-mineralized water. In: Proceedings of the National Scientific and Practical Conference «Oil and Gas: Technologies and Innovations», Tyumen Industrial University, Tyumen, November 19–20.
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  11. Selimov, A. D., Tananyhin, D. S. (2021, May). Rationale for the use of low-salinity flooding at a late stage of oil field development. In: Proceedings of the International Scientific and Practical Conference «Current issues of scientific knowledge. New technologies of fuel and energy complex». Tyumen: Tyumen Industrial University.
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DOI: 10.5510/OGP20260201195

E-mail: i-fattakhov@rambler.ru


Rihab A. Deabl, Mohammed S. Al-Jawad

College of Engineering, University of Baghdad, Iraq

Application of machine learning technique in water, chemical, and thermal flooding: review paper


This article aims to provide literature for the development of new technologies in enhanced oil recovery (EOR), with a focus on reservoir modelling using machine learning (ML). The inaccuracy and inefficiency of traditional physics-based numerical simulations necessitate the development of faster and more intelligent tools. This review serves as a comprehensive resource on applied ML approaches for reservoir modelling. This research classifies the previous artificial intelligence (AI) research in EOR into three methods: water flooding (WF), chemical enhanced oil recovery (CEOR), and thermal flooding. The comprehensive classification is based on the algorithm used, dataset, purpose, inputs, results, and evaluation for each method in each paper. A novel method for simulating dynamic fluid distributions in WF, the Conditional Deep Convolutional Generative Adversarial Network (CDC-GAN) significantly lowers computational costs while handling complex nonlinear relationships. Particle Swarm Optimization (PSO) combined with Bayesian Random Forest (BRF) provides reliable proxy modelling and optimization, also the Echo State Network (ESN) improves prediction accuracy, however it requires high-quality historical data. While Adaptive Neuro-Fuzzy Inference Systems (ANFIS) efficiently handle uncertainties, Least Square Support Vector Machines (LSSVM) and Artificial Neural Networks (ANNs) demonstrate predictive capabilities for nonlinear relationships in the CEOR. This review emphasizes the role of Reinforcement Learning (RL) in thermal, along with the incorporation of Principal Component Analysis (PCA) and clustering techniques for improved data interpretation. Consequently, this study presents a comprehensive analysis of AI techniques in Enhanced Oil Recovery (EOR) from 2009 to 2024, offering researchers and technical experts insights for future investigations.

Keywords: Bayesian random forest; particle swarm optimisation; least square support vector machine; ANNs; reinforcement learning.

Date submitted: 16.07.2025     Date accepted: 05.02.2026

This article aims to provide literature for the development of new technologies in enhanced oil recovery (EOR), with a focus on reservoir modelling using machine learning (ML). The inaccuracy and inefficiency of traditional physics-based numerical simulations necessitate the development of faster and more intelligent tools. This review serves as a comprehensive resource on applied ML approaches for reservoir modelling. This research classifies the previous artificial intelligence (AI) research in EOR into three methods: water flooding (WF), chemical enhanced oil recovery (CEOR), and thermal flooding. The comprehensive classification is based on the algorithm used, dataset, purpose, inputs, results, and evaluation for each method in each paper. A novel method for simulating dynamic fluid distributions in WF, the Conditional Deep Convolutional Generative Adversarial Network (CDC-GAN) significantly lowers computational costs while handling complex nonlinear relationships. Particle Swarm Optimization (PSO) combined with Bayesian Random Forest (BRF) provides reliable proxy modelling and optimization, also the Echo State Network (ESN) improves prediction accuracy, however it requires high-quality historical data. While Adaptive Neuro-Fuzzy Inference Systems (ANFIS) efficiently handle uncertainties, Least Square Support Vector Machines (LSSVM) and Artificial Neural Networks (ANNs) demonstrate predictive capabilities for nonlinear relationships in the CEOR. This review emphasizes the role of Reinforcement Learning (RL) in thermal, along with the incorporation of Principal Component Analysis (PCA) and clustering techniques for improved data interpretation. Consequently, this study presents a comprehensive analysis of AI techniques in Enhanced Oil Recovery (EOR) from 2009 to 2024, offering researchers and technical experts insights for future investigations.

Keywords: Bayesian random forest; particle swarm optimisation; least square support vector machine; ANNs; reinforcement learning.

Date submitted: 16.07.2025     Date accepted: 05.02.2026

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  70. Guevara, J. L., Patel, R. G., Trivedi, J. J. (2018, December). Optimization of steam injection for heavy oil reservoirs using reinforcement learning. SPE-193769-MS. In: The SPE International Heavy Oil Conference and Exhibition, Kuwait City, Kuwait.
  71. Morvan, M., Degré, G., Leng, J., et al. (2009, April). New viscoelastic fluid for chemical EOR. SPE-121675-MS. In: The SPE International Symposium on Oilfield Chemistry, The Woodlands, Texas.
  72. Ersahin, A., Ertekin, T. (2020). Artificial neural network modelling of cyclic steam injection process in naturally fractured reservoirs. SPE Reservoir Evaluation & Engineering, 23(03), 0979-0991. 
  73. Amirian, E., Leung, J. Y., Zanon, S., Dzurman, P. (2015). Integrated cluster analysis and artificial neural network
    modelling for steam-assisted gravity drainage performance prediction in heterogeneous reservoirs. Expert Systems with Applications, 42(2), 723-740.
  74. Ansari, A., Heras, M., Nones, J., et al. (2020). Predicting the performance of steam assisted gravity drainage (SAGD) method utilizing artificial neural network (ANN). Petroleum, 6(4), 368-374.
  75. Sarapardeh, A., Kiasari, H. H., Alizadeh, N., et al. (2013). Application of fast-SAGD in naturally fractured heavy oil reservoirs: A case study. SPE-164418-MS. In: Proceedings of the SPE Middle East Oil and Gas Show and Conference. Society of Petroleum Engineers.
  76. Mohammadi, K., Ameli, F. (2019). Toward mechanistic understanding of Fast SAGD process in naturally fractured heavy oil reservoirs: Application of response surface methodology and genetic algorithm. Fuel, 253, 840-856.
  77. Merdeka, M. G., Ridha, S., Negash, B. M., Ilyas, S. U. (2022). Reservoir performance prediction in steam huff and puff injection using proxy modelling. Applied Sciences, 12(6), 3169.
  78. Zhang, N., Wei, M., Bai, B., et al. (2022). Pattern recognition for steam flooding field applications based on hierarchical clustering and principal component analysis. ACS Omega, 7(22), 18804-18815.
  79. Sarma, P., Lawrence, K., Zhao, Y., et al. (2018, December). Implementation and assessment of production optimization in a steamflood using machine-learning assisted modelling. SPE-193680-MS. In: The SPE International Heavy Oil Conference and Exhibition, Kuwait City, Kuwait.
  80. Sibaweihi, N., Patel, R. G., Guevara, J. L., et al. (2019, April). Real-time steam allocation workflow using machine
    learning for digital heavy oil reservoirs. SPE-195312-MS. In: The SPE Western Regional Meeting, San Jose, California, USA.
  81. Sun, F., Yao, Y., Chen, M., et al. (2017). Performance analysis of superheated steam injection for heavy oil recovery
    and modelling of wellbore heat efficiency. Energy, 125, 795-804.
  82. Yu, Y., Liu, S., Liu, Y., et al. (2021). Data-driven proxy model for forecasting of cumulative oil production during the steam-assisted gravity drainage process. ACS Omega, 6(17), 11497-11509.
  83. Li, Y., Liu, H., Jiao, P., et al. (2023). Machine‐learning‐assisted identification of steam channeling after cyclic steam stimulation in heavy‐oil reservoirs. Geofluids, 2023, 1-13.
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DOI: 10.5510/OGP20260201196

E-mail: rehab.abbas2208@coeng.uobaghdad.edu.iq


Kh. M. Gamzaev

Azerbaijan State Oil and Industry University, Baku, Azerbaijan

A numerical method for restoring pressure distribution in the gas regime of reservoir development based on the model of turbulent filtration


The process of developing a rectangular gas reservoir in the gas regime is considered. A one-dimensional model of is proposed to describe this process. The pressure distribution in the reservoir at the initial moment of time, the pressure and volume flow rate of gas in the production gallery of wells are considered to be set. However, data on the pressure and flow of gas at the outer boundary of the reservoir are assumed to be unknown. Within the framework of the proposed model, the task is to determine the pressure distribution in the reservoir only based on the information specified in the operational gallery. This problem belongs to the class of boundary inverse problems. First, a discrete analogue of the problem is constructed using the method of difference approximation. To numerically solve the resulting system of difference equations, a special computational algorithm is proposed based on the use of representation for solving a system of linear algebraic equations with a tridiagonal matrix. As a result, an explicit formula was obtained for determining the pressure value at the outlet boundary of the reservoir and a recurrent formula for determining the pressure distribution in the reservoir at each time layer. To ensure the stability of the solution of the inverse problem, the method of natural regularization is used. Numerical experiments for a model gas reservoir were carried out based on the proposed computational algorithm.

Keywords: gas regime of reservoir development; rectilinearly parallel gas flow; boundary inverse problem; self-regularization method; difference approximation method.

Date submitted: 10.12.2025     Date accepted: 02.04.2026

The process of developing a rectangular gas reservoir in the gas regime is considered. A one-dimensional model of is proposed to describe this process. The pressure distribution in the reservoir at the initial moment of time, the pressure and volume flow rate of gas in the production gallery of wells are considered to be set. However, data on the pressure and flow of gas at the outer boundary of the reservoir are assumed to be unknown. Within the framework of the proposed model, the task is to determine the pressure distribution in the reservoir only based on the information specified in the operational gallery. This problem belongs to the class of boundary inverse problems. First, a discrete analogue of the problem is constructed using the method of difference approximation. To numerically solve the resulting system of difference equations, a special computational algorithm is proposed based on the use of representation for solving a system of linear algebraic equations with a tridiagonal matrix. As a result, an explicit formula was obtained for determining the pressure value at the outlet boundary of the reservoir and a recurrent formula for determining the pressure distribution in the reservoir at each time layer. To ensure the stability of the solution of the inverse problem, the method of natural regularization is used. Numerical experiments for a model gas reservoir were carried out based on the proposed computational algorithm.

Keywords: gas regime of reservoir development; rectilinearly parallel gas flow; boundary inverse problem; self-regularization method; difference approximation method.

Date submitted: 10.12.2025     Date accepted: 02.04.2026

References

  1. Aliev, Z. S., Basniev, K. S., Kuznetsov, O. L., Mirzadjanzade, A. Kh. (2003). Fundamentals of gas production technology. Moscow: Nedra.
  2. Basniev, K. S., Dmitriev, N. M., Rozenberg, G. D. (2005). Oil and gas hydromechanics. Moscow-Izhevsk: ICS.
  3. Suleimanov, B. A. (2022). Theory and practice of enhanced oil recovery. Moscow-Izhevsk: ICS.
  4. Vishnyakov, V. V., Suleimanov, B. A., Salmanov, A. V., Zeynalov, E. B. (2019). Primer on enhanced oil recovery. Gulf Professional Publishing.
  5. Dzhalalov, G. I. (2025). Hydrodynamic modeling as the main tool for the management of a complex hydrocarbon reservoir. a review. SOCAR Proceedings, SI1, 1-11.
  6. Suleimanov, B. A., Abbasov, H. F., Aliyev, R. Y., et al. (2025). Selection of proxy modelling methods for streamline simulation to waterflooding management process in oil reservoirs. SOCAR Proceedings 2, 55-60.
  7. Aziz, K., Settari, A. (1979). Petroleum reservoir simulation. New York: Applied Science Publishers.
  8. Alifanov, O. M. (2011). Inverse heat transfer problems. Berlin: Springer.
  9. Samarskii, A. A., Vabishchevich, P. N. (2008). Numerical methods for solving inverse problems of mathematical physics. Berlin: De Gruyter.
  10. Kozhanov, A. I. (2016). Inverse problems for determining boundary regimes for some equations of Sobolev type. Bulletin of the South Ural State University Ser. Mathematical Modelling, Programming & Computer Softwar, 9(2), 37–45.
  11. Kostin, A. B, Prilepko, A. I. (1996). On some problems of restoration of a boundary condition for a parabolic equation. Differential Equations, 32(1), 113–122.
  12. Prilepko, A. I., Orlovsky, D. G., Vasin, I. A. (2000). Methods for solving inverse problems in mathematical physics. New York: Marcel Dekker.
  13. Hasanov, A. H., Romanov, V. G. (2021). Introduction to inverse problems for differential equations. Berlin: Springer.
  14. Denisov, A. M. (2021). Approximate solution of inverse problems for the heat equation with a singular perturbation. Computational Mathematics and Mathematical Physics, 61(12), 2004–2014.
  15. Gamzaev, Kh. M. (2025). Numerical identification of hydrodynamic parameters of a reservoir under elastic-water-drive development mode. Bulletin of the South Ural State University. Ser. Mathematical Modelling, Programming & Computer Software, 18(4), 56–65.
  16. Gamzaev, Kh. M. (2024). Identification of the boundary regime in the process of water- oil displacement from the reservoir. St. Petersburg State Polytechnical University Journal. Physics and Mathematics, 17(4), 57–67.
  17. Gamzaev, Kh. M., Nadirov, U. M. (2025). Numerical identification of boundary condition in the elastic regime model of a two-dimensional single-well reservoir. Applied Mathematics and Computation,24(4), 608-618.
  18. Tabarintseva, E. V. (2018). On the estimate of accuracy of the auxiliary boundary conditions method for solving a boundary value inverse problem for a nonlinear equation. Numerical Analysis and Applications, 11(3), 236–255.
  19. Sidikova, A. I. (2019). A study of an inverse boundary value problem for the heat conduction equation. Numerical Analysis and Applications, 12, 70–86.
  20. Yaparova, N. M. (2014). Numerical methods for solving a boundary value inverse heat conduction problem. Inverse Problems in Science and Engineering, 22(5), 832-847.
  21. Dmitriev, V. I., Stolyarov, L. V. (2017). Numerical method for the inverse boundary-value problem of the heat equation. Computational Mathematics and Modeling, 28(2), 141–147.
  22. Abdullayev, V. J., Gamzaev, Kh. M. (2024). A method for computing the pressure distribution in the elastic mode of single-well formation development. SOCAR Proceedings 2, 80-84.
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DOI: 10.5510/OGP20260201197

E-mail: xan.h@rambler.ru


A. A. Aliyev1, G. I. Jalalov2, E. N. Mamalov2

1BP Azerbaijan, Baku, Azerbaijan; 2The Azerbaijan National Academy of Sciences, Baku, Azerbaijan

Hydrodynamic modeling of water–gas injection effects in permeability-heterogeneous reservoirs


In oil fields operated under depletion drive, improving oil recovery remains a critical challenge, requiring methods that can modify the physicochemical properties of the reservoir system, improve displacement efficiency, and provide additional pressure support. This study evaluates water-gas mixture (WGM) injection, supported by digital reservoir monitoring and numerical modeling, as an integrated approach for increasing the recovery of remaining oil reserves from heterogeneous reservoirs. A series of laboratory experiments was conducted using a linear reservoir model to compare the displacement efficiency of conventional waterflooding, WGM injection, and polyacrylamide (PAM) injection. The experiments show that WGM injection, particularly when applied from the early stage of development and compared with PAM-based mobility-control displacement, enables the target recovery factor to be achieved considerably faster. This improves the time-dependent oil recovery factor, shortens the overall development period, and reduces the required volume of the displacement agent. To validate the experimental conclusions under field-scale conditions, a hydrodynamic reservoir simulation study was performed for a selected block of the Gum Deniz oil field in Azerbaijan, which is characterized by complex geology, layered heterogeneity, and variable displacement behavior. The simulation workflow was implemented using the Landmark Nexus (Nexus-Black-Oil) software package and calibrated against historical production and pressure trends. The combined laboratory and numerical modeling results confirm that WGM injection can provide stronger pressure maintenance, improved sweep efficiency, and higher recovery potential than conventional waterflooding and PAM injection, making it a promising enhanced oil recovery strategy for mature depletion-drive reservoirs.

Keywords: enhanced oil recovery; water–gas mixture injection; sweep efficiency; oil displacement; heterogeneous reservoirs; history matching; polyacrylamide; PAM; EOR.

Date submitted: 14.02.2026     Date accepted: 30.04.2026

In oil fields operated under depletion drive, improving oil recovery remains a critical challenge, requiring methods that can modify the physicochemical properties of the reservoir system, improve displacement efficiency, and provide additional pressure support. This study evaluates water-gas mixture (WGM) injection, supported by digital reservoir monitoring and numerical modeling, as an integrated approach for increasing the recovery of remaining oil reserves from heterogeneous reservoirs. A series of laboratory experiments was conducted using a linear reservoir model to compare the displacement efficiency of conventional waterflooding, WGM injection, and polyacrylamide (PAM) injection. The experiments show that WGM injection, particularly when applied from the early stage of development and compared with PAM-based mobility-control displacement, enables the target recovery factor to be achieved considerably faster. This improves the time-dependent oil recovery factor, shortens the overall development period, and reduces the required volume of the displacement agent. To validate the experimental conclusions under field-scale conditions, a hydrodynamic reservoir simulation study was performed for a selected block of the Gum Deniz oil field in Azerbaijan, which is characterized by complex geology, layered heterogeneity, and variable displacement behavior. The simulation workflow was implemented using the Landmark Nexus (Nexus-Black-Oil) software package and calibrated against historical production and pressure trends. The combined laboratory and numerical modeling results confirm that WGM injection can provide stronger pressure maintenance, improved sweep efficiency, and higher recovery potential than conventional waterflooding and PAM injection, making it a promising enhanced oil recovery strategy for mature depletion-drive reservoirs.

Keywords: enhanced oil recovery; water–gas mixture injection; sweep efficiency; oil displacement; heterogeneous reservoirs; history matching; polyacrylamide; PAM; EOR.

Date submitted: 14.02.2026     Date accepted: 30.04.2026

References

  1. Abdullaev, V. D., Ibrahimov, Kh. M., Kyazimov, F. K., Shafiyev, T. Kh. (2016). Experimental studies on gas drive and gas-and-water oil displacement. SOCAR Proceedings, 1, 51-57.
  2. Corey, A. T. (1954). The interrelation between gas and oil relative permeabilities. Producers Monthly, 19(1), 38–41.
  3. Green, D. W., Willhite, G. P. (1998). Enhanced oil recovery. SPE Textbook Series, Vol. 6. Society of Petroleum Engineers.
  4. Gumrah, F., Aliyev, A., Guliyeva, J., Ozavci, O. (2012). Determining reservoir characteristics and drive mechanisms for an oil reservoir. SOCAR Proceedings, 4, 22–31.
  5. Gumrah, F., Aliyev, A., Ozavci, O. (2015). Evaluation of drive mechanisms on offshore oil reservoirs by analytical methods. Proceedings of ANAS. The Sciences of Earth, 3, 15–24.
  6. Irani, M. M., Telkov, V. P. (2021). Study of modern options for using combinations of gas and traditional flooding (water-gas impact and its alternative). SOCAR Proceedings, 2, 248–256.
  7. Kazimov, Sh. P. (2022). Enhanced oil recovery in water-flooded and hard-to-recover reservoirs. SOCAR Proceedings, 1, 89–93.
  8. Mamalov, E. N., Gorshkova, E. V. (2025). Intensification of oil production using a combined method of influencing formations. Baku: Ocaq.
  9. Mamalov, E. N., Jalalov, G. I., Gorshkova, E. V., Hadiyeva, A. S. (2022). Intensification of oil production using WGM. SOCAR Proceedings, 2, 78–83.
  10. Suleimanov, B. A., Abbasov, H. F. (2022). Enhanced oil recovery mechanism with nanofluid injection. SOCAR Proceedings, 3, 28–37.
  11. Suleimanov, B. A., Abbasov, H. F., Ismayilov, R. H. (2023). Enhanced oil recovery with nanofluid injection. Petroleum Science and Technology, 41(18), 1734–1751.
  12. Suleimanov, B. A., Veliyev, E. F. (2016). Softened water application for enhanced oil recovery. SOCAR Proceedings, 2, 24-28.
  13. Telkov, V. P., Mostadjeran, M. G. (2018). Evaluation of criteria for the application of polymer flooding for the displacement of heavy, highly viscous Iranian oils. Oil Gas Exposure, 4(64), 52-55.
  14. Gasimli, A. M., Jamalov, I. M., Aliyev, N. Sh., Kazimov, F. K. (2008). On increasing oil recovery from reservoir layers with different permeabilities. Azerbaijan Oil Industry, 3, 36–39.
  15. Jalalov, G. I., Aliyev, A. A. (2024). Study of unsteady state flow in a deformable formation under two-phase flow condition. SOCAR Proceedings, 2, 4–11. 
  16. Oliver, D. S., Chen, Y. (2011). Recent progress on reservoir history matching: a review. Computational Geosciences, 15(1), 185–221.
  17. Efros, D. A., (1963). A study of the filtration of heterogeneous systems. Moscow: Gostoptekhizdat.
  18. Lake, L. W. (1989). Enhanced oil recovery. New Jersey: Prentice Hall, Englewood Cliffs.
  19. Mamalov, E. N., Gorshkova, E. V. (2020). One opportunity to increase oil recovery in a layered heterogeneous reservoir. Azerbaijan Oil Industry, 3, 20–26.
  20. Manrique, E. J., Thomas, C. P., Ravikiran, R. (2010). EOR: current status and opportunities. SPE Reservoir Evaluation & Engineering, 13(06), 946–956.
  21. Sheng, J. J. (2015). A comprehensive review of alkaline–surfactant–polymer flooding. SPE Reservoir Evaluation & Engineering, 18(03), 357–372.
  22. Jalalov, G. I., Ibragimov, T. M., Aliyev, A. A., Gorshkova, E. V. (2018). Modeling and research of filtration processes in deep-seated oil and gas fields. Baku: Elm ve Tehsil.
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DOI: 10.5510/OGP20260201198

E-mail: evgeniy_mamalov@rambler.ru


Yamama Al-Oudah1, Omar Al-Fatlawi1,2,3

1College of Engineering, University of Baghdad, Baghdad, Iraq; 2College of Engineering, Al-Naji University, Baghdad, Iraq; 3WASM: Energy and Chemical Engineering, Curtin University, WA, Australia

Hydraulic fracturing in tight oil reservoirs: a synthesis of current practices, challenges, and future trajectories


Multistage hydraulic fracturing (MHF) is the primary method for developing extremely tight oil reservoirs (TORs) with nanopores. Currently, this technology is considered the only economically viable way to develop these resources. However, MHF suffers from geomechanical limitations, including formation heterogeneity and limited pumping capacity at surface facilities. This paper reviews the current state of MHF in tight oil reservoirs, connecting geomechanical concepts to field applications and highlighting key challenges and future trends, including sustainability and digital transformation. The industry has evolved from simple planar fracturing operations to complex stimulated reservoir systems (SRS). Modern design is based on geological characteristics; in-situ stresses and natural fractures guide engineering decisions, such as the use of hydraulic fracturing fluids. However, this sector faces ongoing challenges, including overlap of parent and child wells, low recovery factors (less than 10%), and loss of conductivity, caused by gaps in the scaling of complex physical processes across time and space. Addressing these challenges is facilitated by digitalization. By harnessing data analytics, ML and real-time DAS/DTS, operators transition from a «design and pump» paradigm to a «sense and respond» approach. This empowers them to optimize real-time hydrocarbon sweep and bridge key sustainability gaps. In conclusion, this review illustrates how optimized water management, efficient operational scaling and sustainable design in MHF directly contributes to SDGs 6, 8, 9 and 12, promoting responsible global resource stewardship.

Keywords: tight oil reservoirs; hydraulic fracturing; stimulated reservoir system; fracturing fluids; energy efficiency; sustainable energy; clean energy technology.

Date submitted: 13.08.2025     Date accepted: 28.04.2026

Multistage hydraulic fracturing (MHF) is the primary method for developing extremely tight oil reservoirs (TORs) with nanopores. Currently, this technology is considered the only economically viable way to develop these resources. However, MHF suffers from geomechanical limitations, including formation heterogeneity and limited pumping capacity at surface facilities. This paper reviews the current state of MHF in tight oil reservoirs, connecting geomechanical concepts to field applications and highlighting key challenges and future trends, including sustainability and digital transformation. The industry has evolved from simple planar fracturing operations to complex stimulated reservoir systems (SRS). Modern design is based on geological characteristics; in-situ stresses and natural fractures guide engineering decisions, such as the use of hydraulic fracturing fluids. However, this sector faces ongoing challenges, including overlap of parent and child wells, low recovery factors (less than 10%), and loss of conductivity, caused by gaps in the scaling of complex physical processes across time and space. Addressing these challenges is facilitated by digitalization. By harnessing data analytics, ML and real-time DAS/DTS, operators transition from a «design and pump» paradigm to a «sense and respond» approach. This empowers them to optimize real-time hydrocarbon sweep and bridge key sustainability gaps. In conclusion, this review illustrates how optimized water management, efficient operational scaling and sustainable design in MHF directly contributes to SDGs 6, 8, 9 and 12, promoting responsible global resource stewardship.

Keywords: tight oil reservoirs; hydraulic fracturing; stimulated reservoir system; fracturing fluids; energy efficiency; sustainable energy; clean energy technology.

Date submitted: 13.08.2025     Date accepted: 28.04.2026

References

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DOI: 10.5510/OGP20260201199

E-mail: omar.al-fatlawi@alnaji-uni.edu.iq


M. A. Huseynov, R. R. Mammadov

«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan

Observation-driven AI framework for integrated geological–hydrodynamic reservoir modelling


This study presents an observation-driven approach for integrated geological and hydrodynamic reservoir modelling using multi-source data. Reservoir systems are complex due to heterogeneous structures, nonlinear flow behaviour, and limited direct access to subsurface information. These factors make accurate modelling a challenging task in reservoir engineering. Conventional modelling approaches usually follow a sequential workflow from geological interpretation to numerical simulation. This often increases computational cost and introduces uncertainty in model construction. To address these limitations, the study explores the use of artificial intelligence methods together with physics-informed and hybrid modelling concepts. In the proposed framework, geological, petrophysical, and production data are combined in a unified processing scheme. A simple encoder–decoder structure is used to extract latent features that describe reservoir behaviour. A bridge mechanism is introduced to connect these features with physically meaningful reservoir properties such as connectivity, flow capacity, and pressure response. The method does not replace traditional reservoir simulation but aims to support it by improving data integration and reducing computational effort. A synthetic validation study shows that the proposed approach can reproduce main reservoir behaviour trends with reasonable accuracy. Overall, the results suggest that data-driven methods, when guided by physical understanding, can be a useful complement to classical reservoir modelling workflows.

Keywords: reservoir modelling; artificial intelligence; data integration; physics-informed methods; hybrid modelling; surrogate models.

Date submitted: 12.03.2026     Date accepted: 09.06.2026

This study presents an observation-driven approach for integrated geological and hydrodynamic reservoir modelling using multi-source data. Reservoir systems are complex due to heterogeneous structures, nonlinear flow behaviour, and limited direct access to subsurface information. These factors make accurate modelling a challenging task in reservoir engineering. Conventional modelling approaches usually follow a sequential workflow from geological interpretation to numerical simulation. This often increases computational cost and introduces uncertainty in model construction. To address these limitations, the study explores the use of artificial intelligence methods together with physics-informed and hybrid modelling concepts. In the proposed framework, geological, petrophysical, and production data are combined in a unified processing scheme. A simple encoder–decoder structure is used to extract latent features that describe reservoir behaviour. A bridge mechanism is introduced to connect these features with physically meaningful reservoir properties such as connectivity, flow capacity, and pressure response. The method does not replace traditional reservoir simulation but aims to support it by improving data integration and reducing computational effort. A synthetic validation study shows that the proposed approach can reproduce main reservoir behaviour trends with reasonable accuracy. Overall, the results suggest that data-driven methods, when guided by physical understanding, can be a useful complement to classical reservoir modelling workflows.

Keywords: reservoir modelling; artificial intelligence; data integration; physics-informed methods; hybrid modelling; surrogate models.

Date submitted: 12.03.2026     Date accepted: 09.06.2026

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  7. Karniadakis, G. E., Kevrekidis, I. G., Lu, L., et al. (2021). Physics-informed machine learning. Nature Reviews Physics, 3, 422–440.
  8. Chan, S., Elsheikh, A. (2017). Parametric generation of geological models using generative adversarial networks. Computational Geosciences, 21, 1201–1214.
  9. Chen, Y., Oliver, D.S. (2013). Ensemble-based reservoir history matching. Journal of Petroleum Science and Engineering, 109, 123–137.
  10. Nurgaliev, R. Z., Fattakhov, I. G., Khusnutdinova, R. R., et al. (2023). A method for assessing the effectiveness of water isolation works based on the development of a hydrodynamic model. SOCAR Proceedings, 1, 94–99.
  11. Aliyev, N. Sh. (2024). Waterflood reservoir modelling for Chirag oilfield. SOCAR Proceedings, 1, 40–47.
  12. Liu, Y., Durlofsky, L. (2020). Machine learning-based surrogate modeling for reservoir simulation. Computational Geosciences, 24, 1245–1263.
  13. Laloy, E., Jacques, D. (2019). Deep learning for inverse problems in hydrogeology. Water Resources Research, 55, 1–18.
  14. Pyrcz, M. J., Deutsch, C. V. (2014). Geostatistical reservoir modeling. Oxford University Press.
  15. Durlofsky, L. J., Chen, Y. (2013). Recent developments in surrogate modeling for subsurface flow simulation. Journal of Computational Physics, 248, 1–18.
  16. Mosser, L., Dubrule, O., Blunt, M. (2017). Reconstruction of three-dimensional porous media using generative adversarial neural networks. Physical Review E, 96(4), 043309.
  17. Fataliyev, V. M., Hamidov, N. N. (2017). Effective «vaporizer» for recovering retrograde hydrocarbon condensate from a gas-condensate reservoir. Journal of Petrochemical Science & Engineering, 2(6), 1–7.
  18. Fataliyev, V. M., Hamidov, N. N., Aliyev, K. F. (2025). Advances in understanding and controlling liquid loading in gas-condensate production well. SOCAR Proceedings, 2, 65–103.
  19. Tartakovsky, A. M., Marrero, C. O. (2020). Learning parameters of subsurface flow models using physics-informed neural
    networks. Journal of Computational Physics, 418, 109629.
  20. Zhang, Y., Pan, Z., Wang, X., Yang, D. (2020). Machine learning-based reservoir production forecasting: A review. Petroleum Exploration and Development, 47(5), 1043–1059.
  21. Zhao, T., Li, J., Li, Z. (2022). Deep learning-assisted reservoir modeling: A review. Energy & AI, 7, 100128.
  22. Sun, A. Y., Scanlon, B. R. (2019). Combining physics-based modeling and machine learning for groundwater simulation. Water Resources Research, 55(1), 1–19.
  23. Huseynova, N. I., Safarov, N. M., Safarova, G. N. (2023). Hydrodynamic simulation of the current state of liquid filtration under water emulsion impact on oil layer. SOCAR Proceedings, SI1, 87–95.
  24. Goodfellow, I., Bengio, Y., Courville, A. (2016). Deep learning. MIT Press.
  25. Karniadakis G.E. (2021). Physics-informed machine learning and hybrid modeling frameworks. Nature Reviews Physics, 3, 422–440.
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DOI: 10.5510/OGP20260201200

E-mail: mehdi.huseynov@socar.az


M. A. Jamalbayov1, Z. T. Mustafayeva2, N. A. Valiyev2

1Baku Engineering University, The Ministry of Science and Education of Azerbaijan, Baku, Azerbaijan; 2SOCAR, Baku, Azerbaijan

Technological efficiency and productivity analysis in sucker-rod pumping wells


Rod pumping systems represent a fundamental component of artificial lift technologies, particularly in the development and exploitation of mature oil fields. Despite their widespread use, the quantitative evaluation of their operational efficiency remains a challenging task, largely due to the nonlinear dynamics of well behavior and the inherent limitations of conventional diagnostic methods. This study presents a comprehensive and structured methodology for evaluating the efficiency of sucker-rod pumping wells by integrating field measurements with advanced computer-based simulation techniques. The proposed framework is based on directly measurable operational parameters in order to formulate a practically applicable concept for evaluating the efficiency of pump operation. Within this framework, efficiency is conceptualized as a function of reservoir productivity, pump fillage factor, production rate, stroke speed, the geometric characteristics of the pump, and other indicators that collectively characterize the well–reservoir system. The proposed methodology is demonstrated under various geo-technological conditions using a computer simulator of the pump–well–reservoir system developed on the basis of the authors’ Discrete-Imitation Modeling Concept. It provides a robust analytical basis for evaluating the efficiency of production using sucker-rod pumps and supports the development of informed strategies for production enhancement. The notions of the Pump Productivity Index and the Technological Efficiency Coefficient are introduced, and analytical expressions for efficiency evaluation are presented. Using the simulator, a methodology for the investigation and optimization of the sucker-rod pump
well–reservoir system is demonstrated.Validation using data from a real field well confirms the methodological soundness and practical relevance of the approach, demonstrating its potential as an effective decision-support tool for petroleum engineers engaged in the optimization of sucker-rod pump systems.

Keywords: sucker-rod pump; efficiency conception; technological efficiency; pump performance indicator; production data analysis; optimization. 

Date submitted: 18.05.2026     Date accepted: 16.06.2026

Rod pumping systems represent a fundamental component of artificial lift technologies, particularly in the development and exploitation of mature oil fields. Despite their widespread use, the quantitative evaluation of their operational efficiency remains a challenging task, largely due to the nonlinear dynamics of well behavior and the inherent limitations of conventional diagnostic methods. This study presents a comprehensive and structured methodology for evaluating the efficiency of sucker-rod pumping wells by integrating field measurements with advanced computer-based simulation techniques. The proposed framework is based on directly measurable operational parameters in order to formulate a practically applicable concept for evaluating the efficiency of pump operation. Within this framework, efficiency is conceptualized as a function of reservoir productivity, pump fillage factor, production rate, stroke speed, the geometric characteristics of the pump, and other indicators that collectively characterize the well–reservoir system. The proposed methodology is demonstrated under various geo-technological conditions using a computer simulator of the pump–well–reservoir system developed on the basis of the authors’ Discrete-Imitation Modeling Concept. It provides a robust analytical basis for evaluating the efficiency of production using sucker-rod pumps and supports the development of informed strategies for production enhancement. The notions of the Pump Productivity Index and the Technological Efficiency Coefficient are introduced, and analytical expressions for efficiency evaluation are presented. Using the simulator, a methodology for the investigation and optimization of the sucker-rod pump
well–reservoir system is demonstrated.Validation using data from a real field well confirms the methodological soundness and practical relevance of the approach, demonstrating its potential as an effective decision-support tool for petroleum engineers engaged in the optimization of sucker-rod pump systems.

Keywords: sucker-rod pump; efficiency conception; technological efficiency; pump performance indicator; production data analysis; optimization. 

Date submitted: 18.05.2026     Date accepted: 16.06.2026

References

  1. Brown, K. E. (1980). The technology of artificial lift methods. Tulsa, Oklahoma: PennWell Publishing.
  2. American Petroleum Institute. (2011). API Recommended Practice 11L: Design calculations for sucker rod pumping systems. Washington, DC: American Petroleum Institute.
  3. Takács, G. (2009). Sucker-rod pumping handbook: production engineering fundamentals and long-stroke rod pumping. Burlington, MA: Gulf Professional Publishing.
  4. Fakher, S., Khlaifat, A., Hossain, M. E., et al. (2021). A comprehensive review of sucker rod pumps’ components, diagnostics, mathematical models, and common failures and mitigations. Journal of Petroleum Exploration and Production Technology, 11, 3815–3839.
  5. Gibbs, S. G., Neely, A. B. (1993). The beam pumping handbook. Tulsa, Oklahoma: PennWell Publishing.
  6. Jamalbayov, M. A., Valiyev, N. A., Ibrahimov, Kh. M., et al. (2024). Energy and efficiency optimization in sucker-rod pumping using discrete-ımitation modeling concept: application to well operations in the Bibi-Eibat field of Azerbaijan. SOCAR Proceedings, SI1, 95-101.
  7. Jamalbayov, M. A., Valiyev, N. A. (2024). The discrete-imitation modeling concept of the «sucker-rod pump-wellreservoir» system and the optimization of the pumping process. Petroleum Research, 9(4), 686-694.
  8. Economides, M. J., Hill, A. D., Ehlig-Economides, C., Zhu, D. (2012). Petroleum production systems. Upper Saddle River, NJ: Pearson.
  9. Kazymov, B. Z. (2018). Influence of the relaxation deformation of rocks on the characteristics of nonisothermal filtration of live crude in the stratum. Journal of Engineering Physics and Thermophysics, 91(6), 1539-1542.
  10. Gibbs, S. G. (1963). Predicting the behavior of sucker-rod pumping systems. SPE Journal of Petroleum Technology, 15(07), 769–778.
  11. Romero, O. J., Almeida, P. (2014). Numerical simulation of the sucker-rod pumping system. Ingeniería e Investigación, 34(3), 4–11.
    M. A. Jamalbayov et al. / SOCAR Proceedings No.2 (2026) 116-127 
  12. Al Badi, S., Al Abri, A. T., Al Faraji, O., et al. (2025). Optimizing sucker rod pump selection for mature oilfields: a case study on pump size and clearance. SPE-228920-MS. In: ADIPEC, Abu Dhabi, United Arab Emirates, November.
  13. Ngoc Lam Tran, Hamidreza Karami, Opeyemi Bello, Catalin Teodoriu. (2022). Tailoring digital approaches for monitoring and predictive diagnosis for sucker rod pumping systems. SPE-209762-MS. In: SPE Artificial Lift Conference and Exhibition - Americas, Galveston, Texas, USA, August.
  14. Hamidishad N., Barbosa, R. S., Allahyarzadeh-Bidgoli, A. Yanagihara, J. I. (2025). Digital twin frameworks for oil and gas processing plants. Processes, 13(11), 3488.
  15. Lin B., Zhu, H., Jin, Y., et al. (2024). Modeling approach and case studies of digital twin in oil and gas engineering. Petroleum Science Bulletin, 9(2), 282-296.
  16. Rebello, C., Jäschkea, J., Nogueira, I. B. R. (2023). Digital twin framework for optimal and autonomous decision-making in the oil and gas industry. https://arxiv.org/abs/2311.12755
  17. Meza, E. B. M., Borges de Souza, D. G., Copetti, A., et al. (2024). Tools, technologies and frameworks for digital twins in the oil and gas industry. Sensors, 24(19), 6457.
  18. Ma, S., Flanigan, K. A., Bergés, M. (2024). State-of-the-art review: the use of digital twins to support ai-guided predictive maintenance. https://arxiv.org/html/2406.13117v1
  19. Kochtik, D., Langbauer, C. (2018). Volumetric efficiency evaluation of sucker-rod-pumping applications performed on a pump testing facility. SPE-192454-MS. In: SPE Middle East Artificial Lift Conference and Exhibition, Manama, Bahrain, November.
  20. Nind, T. E. W. (1964). Principles of oil well production. New York: McGraw-Hill.
  21. Aliev, F. A., Aliyev, N. A, Hajiyeva, N. S., Mahmudov, N. I. (2021). Some mathematical problems and their solutions for the oscillating systems with liquid dampers: A review. Applied and Computational Mathematics, 20(3), 339-365.
  22. Aliev, F. A., Aliyev, N. A, Rasulzade, A. F., Hajiyeva, N. S. (2023). Solution of the optimal program trajectory and control of the discretized equation of motion of sucker-rod pumping unit in a Newtonian fluid. TWMS Journal of Applied and Engineering Mathematics, 13(4), 1369-1382.
  23. Aliev, F. A., Aliyev, N. A., Hajiyeva, N. S., et al. (2021). Solution of an oscillatory system with fractional derivative including to equations of motion and to nonlocal boundary conditions, SOCAR Proceedings, 4, 115-121.
  24. Jamalbayov, М. A., Valiyev, N. A., Mahamat Zene, M. T. (2021). Imitation modelling of pump–well–reservoir systems equipped with submersible rod-free pumps. Automation, Telemechanization and Communication in Oil Industry, 2(571), 49-54.
  25. Yi, P., Chunming, X., Jianjun, Z., et al. (2019). Innovative deep autoencoder and machine learning algorithms applied in production metering for sucker-rod pumping wells. In: Proceedings of the 7th Unconventional Resources Technology Conference, July 22–24.
  26. Thabet, S., Zidan, H., Elhadidy, A., et al. (2024). Machine learning models to predict production rate of sucker rod pump wells. SPE-218857-MS. In: SPE Western Regional Meeting, Palo Alto, California, USA, April.
  27. Jamalbayov, M. A., Valiyev, N. A. (2024). The discrete-ımitational modeling of the pump-well-reservior system with a ıntermittent sucker-rod pumping. SPE-221528-MS. In: SPE Middle East Artificial Lift Conference and Exhibition, Manama, Bahrain.
  28. Aliev, F. A., Dzhamalbekov, M. A., Veliev, N. A., et al. (2019). Computer simulation of crude oil extraction using a sucker rod pumping unit in the oil well–reservoir system. International Applied Mechanics, 55, 332–341.
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DOI: 10.5510/OGP20260201201

E-mail: jamalbayovm@gmail.com


V. M. Abbasov1, A. A. Kangarli1, D. B. Aghamaliyeva1,2, R. H. Valiyev3, Z. Z. Aghamaliyev1,2, N. Sh. Rzayeva1, E. K. Hasanov1, U. V. Abbasova2

1Academician Y. H. Mammadaliyev Institute of Petrochemical Processes of the Ministry of Science and Education of the Republic of Azerbaijan, Baku, Azerbaijan; 2Azerbaijan State Oil and Industry University, Baku, Azerbaijan; 3SOCAR, Baku, Azerbaijan

Preparation of oleic acid–based corrosion inhibitor reagents for application in various aggressive environments of the oil and gas industry


In the present study, the protective efficacy of conservation fluids formulated from bisimidazoline derivatives synthesized via the reaction of oleic acid with polyethylenepolyamine and triethylenetetramine in a 2:1 molar ratio was systematically investigated under various corrosive conditions, including hydrochamber exposure, seawater immersion, and in a 0.001% sulfuric acid solution. The resulting formulations were prepared at 5 and 10 % concentrations in a T-30 oil distillate matrix and applied for temporary corrosion protection of metallic surfaces. Experimental results showed that the T-30 oil distillate alone, in the absence of any corrosion inhibitor, exhibited minimal protective capability, providing surface protection for only 9–34 days. In contrast, formulations incorporating bisimidazoline derivatives particularly those containing 10% concentrations of polyethylenepolyamine- and triethylenetetramine-based compounds achieved continuous protective performance exceeding 300–400 days across all tested environments. The relative extension of the protection period was estimated to be approximately 10- to 23-fold. Furthermore, imidazolines synthesized using polyethylenepolyamine exhibited superior corrosion inhibition performance compared to those derived from triethylenetetramine, which can be attributed to their higher density of functional groups and enhanced coordination capability with metal surfaces. Consequently, these imidazoline-based formulations represent effective and practical candidates for temporary corrosion protection in atmospheric and aqueous environments. 

Keywords: atmospheric corrosion; conservation fluids; bisimidazoline; polyethylenepolyamine; triethylenetetramine; conservation time; inhibitor effectiveness.

Date submitted: 15.07.2025     Date accepted: 22.12.2025

In the present study, the protective efficacy of conservation fluids formulated from bisimidazoline derivatives synthesized via the reaction of oleic acid with polyethylenepolyamine and triethylenetetramine in a 2:1 molar ratio was systematically investigated under various corrosive conditions, including hydrochamber exposure, seawater immersion, and in a 0.001% sulfuric acid solution. The resulting formulations were prepared at 5 and 10 % concentrations in a T-30 oil distillate matrix and applied for temporary corrosion protection of metallic surfaces. Experimental results showed that the T-30 oil distillate alone, in the absence of any corrosion inhibitor, exhibited minimal protective capability, providing surface protection for only 9–34 days. In contrast, formulations incorporating bisimidazoline derivatives particularly those containing 10% concentrations of polyethylenepolyamine- and triethylenetetramine-based compounds achieved continuous protective performance exceeding 300–400 days across all tested environments. The relative extension of the protection period was estimated to be approximately 10- to 23-fold. Furthermore, imidazolines synthesized using polyethylenepolyamine exhibited superior corrosion inhibition performance compared to those derived from triethylenetetramine, which can be attributed to their higher density of functional groups and enhanced coordination capability with metal surfaces. Consequently, these imidazoline-based formulations represent effective and practical candidates for temporary corrosion protection in atmospheric and aqueous environments. 

Keywords: atmospheric corrosion; conservation fluids; bisimidazoline; polyethylenepolyamine; triethylenetetramine; conservation time; inhibitor effectiveness.

Date submitted: 15.07.2025     Date accepted: 22.12.2025

References

  1. Abbasov, V. M. (2023). Corrosion. 2nd ed. Baku: Elm.
  2. Abbasov, V. M., Mamedbeyli, E. G., Agamalieva, D. B., et al. (2018). Synthesis of imidazoline derivatives based on synthetic petroleum acids and their effect on microbiological corrosion. Theory and Practice of Corrosion Protection, 1, 17–23.
  3. Syed, S. (2006). Atmospheric corrosion of materials. Emirates Journal for Engineering Research, 11 (1), 1–24.
  4. Abbasov, V. M., Aliyeva, L. I., Efendiyeva, L. M., et al. (2016). Influence of imidazoline derivatives of synthetic oil acids on kinetics of process of CO2-steel corrosion. Processes of Petrochemistry and Oil Refining, 17(1), 3–8.
  5. Abbasov, V. M., Agamaliyeva, D. B., Mursalov, N. I., et al. (2015). Investigation imidazoline derivatives obtained from synthetic petroleum acids as corrosion inhibitor. Journal of Advances in Chemistry, 11(1), 3372–3381.
  6. Verma, Ch., Ebenso, E. E., Quraishi, M. A., Hussain, Ch. M. (2021). Recent developments in sustainable corrosion inhibitors: design, performance and industrial scale applications. Materials Advances, 2, 3806-3850.
  7. Valiyev, F. Q., Shabanova, Z. A., Sultanov, E. F., et al. (2019). Corrosion inhibitor for heavy brines. Caspian Corrosion Control, 1, 11-16.
  8. Ismailov, O. D., Shabanova, Z. A., Sultanov, E. F., Veliev, F. G.. (2019). Development and protective properties of a bactericidal inhibitor against hydrogen sulfide and microbiological corrosion of steel based on nitrogen-containing compounds. SOCAR Proceedings, 3, 29-33.
  9. Shwetha, K. M., Praveen, B. M., Devendra, B. K. (2024). A review on corrosion inhibitors: Types, mechanisms, electrochemical analysis, corrosion rate and efficiency of corrosion inhibitors on mild steel in an acidic environment. Results in Surfaces and Interfaces, 16, 100258.
  10. Aydinsoy, E. A., Aghamaliyev, Z. Z., Aghamaliyeva, D. B., Abbasov, V. B. (2024). A systematic review of corrosion inhibitors in marine environments: insights from the last 5 years. Processes of Petrochemistry and Oil Refining, 25(3), 793–843.
  11. Abbasov, V. M., Valiyev, R. H., Aydinsoy, E. A., et al. (2025). Environmental impact and analytical characterization of water samples from the Caspian sea. SOCAR Proceedings, SI1, 1–8.
  12. Groysman, A. (2017). Corrosion problems and solutions in oil, gas, refining, and petrochemical industry. Koroze a Ochrana Materiálu, 61(3), 100–117.
  13. Finsgar, M., Jackson, J. (2014). Application of corrosion inhibitors for steels in acidic media for the oil and gas industry. Corrosion Science, 86, 17–41.
  14. Prabha, S. S., Rathish, R. J., Dorothy, R., et al. (2014). Corrosion problems in the petroleum industry and their solution. European Chemical Bulletin, 3(3), 300–307.
  15. Zhang, H., Ling, Y., Zhu, Y., et al. (2021). The effect of immersion corrosion time on electrochemical corrosion behavior and the corrosion mechanism of EH47 ship steel in seawater. Metals, 11(8), 1–15.
  16. Al-Amiery, A., Roslam, W. N., Al-Azzawi, W. Kh. (2024). Sustainable corrosion Inhibitors: A key step towards environmentally responsible corrosion control. Ain Shams Engineering Journal, 15(5), 102672.
  17. Abbasov, V. M., Agazade, Y. C., Abdullayev, E. Sh, Hasanov, E. K. (2013). Study of conservation fluid created from the composition of nitro compounds with salts an d amides of natural petroleum acids. Azerbaijan Journal of Chemistry, 3, 16–20.
  18. Abbasova, U. B. (2022). Synthesis of amides of natural petroleum acids with ethylenediamine and alkylamines and research as a component to conservation liquıds. Processes of Petrochemistry and Oil Refining, 23(3), 517–523.
  19. Aghazada, Y. J., Abbasov, V. M., Nasirov, F. A., et al. (2017). Characteristic of conservative lubricants obtained on the basis of oxidated liquid rubber and amidoamines. Chemical Problems, 4, 397-404.
  20. Aghazada, Y. J. (2017). The research of miscellaneous conservative lubricants as anti-corrosion agents. Processes of Petrochemistry and Oil Refining, 18(4), 367-373.
  21. Rzayeva, N. S. (2016). Results of the tests of nitrated sunflower oil as a component of conservation liquid. Processes of Petrochemistry and Oil Refining, 17(1), 15-18.
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DOI: 10.5510/OGP20260201202

E-mail: aydanmehieva@gmail.com


T. V. Khismetov1, G. M. Efendiyev2, S. V. Abbasova3, R. A. Saipiev1, O. G. Kirisenko2, N. Traikovich4, O. N. Zhuravlev5

1OLC «STC GEOTECHNOKIN», Moscow, Russia; 2Institute of Oil and Gas of the Ministry of Science and Education of the Republic of Azerbaijan, Baku, Azerbaijan; 3Azerbaijan State University of Oil and Industry, Baku, Azerbaijan; 4«Geotechnokin D.O.O.», Novi Sad, Serbia; 5OLC «WORMHOLES Implementation», Moscow, Russia

Comprehensive assessment of the impact of mechanical impurities on the reliability indicators of downhole pumping equipment in oil production


The article investigates the causes of failures of downhole pumping equipment (DPE) used in mechanized oil production, as well as methods for analyzing and forecasting its reliability. Despite continuous improvements in pump design and materials, a significant proportion of failures is associated with the effects of abrasive particles, corrosion, and cavitation. An analysis of domestic and foreign studies aimed at identifying patterns of failure mechanisms and increasing the mean time between repairs (MTBR) of pumps has been carried out. It has been determined that the key factor affecting the reduction in efficiency and durability of the equipment is the presence of mechanical impurities, as well as their concentration, shape, and grain-size distribution. Based on data from oil fields in Kazakhstan, Russia, and Azerbaijan, fuzzy clustering of operating conditions was performed, which allowed the identification of four groups of objects with different combinations of factors. Threedimensional dependencies were constructed, and the results of the analysis formed the basis for fuzzy logic rules «if..., then...». The application of fuzzy cluster analysis confirmed the effectiveness of this method in solving diagnostic and optimization problems in oilfield equipment operation. Based on the results of the analysis, a new-generation filter element was developed, demonstrating significantly higher efficiency compared to leading global analogues and successfully implemented at one of the fields in Serbia. The results obtained can be used to improve the reliability of downhole pumps, reduce failure frequency, and form a knowledge base for managerial decision-making in oil production.

Keywords: oil production; downhole pumping equipment; failure; mean time between repairs; mechanical impurities; uncertainty; fuzzy cluster analysis; reliability; filter element.

Date submitted: 21.01.2026     Date accepted: 18.03.2026

The article investigates the causes of failures of downhole pumping equipment (DPE) used in mechanized oil production, as well as methods for analyzing and forecasting its reliability. Despite continuous improvements in pump design and materials, a significant proportion of failures is associated with the effects of abrasive particles, corrosion, and cavitation. An analysis of domestic and foreign studies aimed at identifying patterns of failure mechanisms and increasing the mean time between repairs (MTBR) of pumps has been carried out. It has been determined that the key factor affecting the reduction in efficiency and durability of the equipment is the presence of mechanical impurities, as well as their concentration, shape, and grain-size distribution. Based on data from oil fields in Kazakhstan, Russia, and Azerbaijan, fuzzy clustering of operating conditions was performed, which allowed the identification of four groups of objects with different combinations of factors. Threedimensional dependencies were constructed, and the results of the analysis formed the basis for fuzzy logic rules «if..., then...». The application of fuzzy cluster analysis confirmed the effectiveness of this method in solving diagnostic and optimization problems in oilfield equipment operation. Based on the results of the analysis, a new-generation filter element was developed, demonstrating significantly higher efficiency compared to leading global analogues and successfully implemented at one of the fields in Serbia. The results obtained can be used to improve the reliability of downhole pumps, reduce failure frequency, and form a knowledge base for managerial decision-making in oil production.

Keywords: oil production; downhole pumping equipment; failure; mean time between repairs; mechanical impurities; uncertainty; fuzzy cluster analysis; reliability; filter element.

Date submitted: 21.01.2026     Date accepted: 18.03.2026

References

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  19. Shakhverdiyev, A. Kh., Panov, Yu. P. (2024). Selecting the optimal option for a hydrocarbon field development project taking into account the risk of reserve deviation. Bulletin of the Russian Academy of Natural Sciences, 24(3), 3-14.
  20. Efendiyev, G. M., Karazhanova, M. K., Zhetekova, L. B., Abbasova, S. V. (2022). Influence of oil composition and properties on quality based on fuzzy clustering. ANAS Transactions. Earth Sciences, 1, 90–98.
  21. Bezdek, J. C. (1981). Pattern recognition with fuzzy objective function algorithms. New York: Plenum Press.
  22. Usov, I. A., Latifov, Ya. A., Khismetov, T. V., et al. (2025). Field experience of using sand screens with reverse-phase permeability. Oil and Gas Vertical, Special Issue, 64–68.
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DOI: 10.5510/OGP20260201203

E-mail: galib_2000@yahoo.com


A. G. Huseynov1, F. S. Huseynli1, Sh. A. Asadov1, N. M. Mirzezade2

1Azerbaijan Technical University, Baku, Azerbaijan; 2Azerbaijan National Aerospace Agency, Baku, Azerbaijan

Effect of deformation on precession details at critical heating


The research work is devoted to a comprehensive analysis of thermal stresses and deformations arising on the working surface of prestressed components operating under critical temperature regimes. During service, these components are subjected to a combination of high temperatures, mechanical pressure, and frictional effects, which lead to complex thermo-mechanical interactions and non-uniform heat distribution across the contact surface. Such conditions significantly influence the stress–strain state, potentially causing structural instability, loss of functionality, or premature failure. To investigate these phenomena, mathematical models based on Fourier series expansions and governing differential equations of heat conduction and elasticity were developed. These models enable the determination of temperature fields, as well as the calculation of thermal stresses and displacements within both zero-order and first-order approximations. The analytical approach provides insight into the distribution patterns of stresses and allows the identification of critical zones where maximum thermal loading occurs. The practical significance of the study lies in the application of the obtained analytical results to engineering design. Based on the developed models, constructive and technological solutions are proposed to minimize the risk of critical stresses and excessive deformations on the working surface of prestressed parts. In addition, optimization of normal and contact stresses is carried out by defining permissible parameter ranges, taking into account the thermophysical and mechanical properties of the material, as well as surface quality indicators such as roughness and hardness. These findings contribute to improving the reliability, durability, and operational efficiency of prestressed components under severe thermal conditions.

Keywords: surface; deformation; precession part; critical heating; mathematical model.

Date submitted: 17.04.2026     Date accepted: 04.05.2026

The research work is devoted to a comprehensive analysis of thermal stresses and deformations arising on the working surface of prestressed components operating under critical temperature regimes. During service, these components are subjected to a combination of high temperatures, mechanical pressure, and frictional effects, which lead to complex thermo-mechanical interactions and non-uniform heat distribution across the contact surface. Such conditions significantly influence the stress–strain state, potentially causing structural instability, loss of functionality, or premature failure. To investigate these phenomena, mathematical models based on Fourier series expansions and governing differential equations of heat conduction and elasticity were developed. These models enable the determination of temperature fields, as well as the calculation of thermal stresses and displacements within both zero-order and first-order approximations. The analytical approach provides insight into the distribution patterns of stresses and allows the identification of critical zones where maximum thermal loading occurs. The practical significance of the study lies in the application of the obtained analytical results to engineering design. Based on the developed models, constructive and technological solutions are proposed to minimize the risk of critical stresses and excessive deformations on the working surface of prestressed parts. In addition, optimization of normal and contact stresses is carried out by defining permissible parameter ranges, taking into account the thermophysical and mechanical properties of the material, as well as surface quality indicators such as roughness and hardness. These findings contribute to improving the reliability, durability, and operational efficiency of prestressed components under severe thermal conditions.

Keywords: surface; deformation; precession part; critical heating; mathematical model.

Date submitted: 17.04.2026     Date accepted: 04.05.2026

References

  1. Huseynov, A. G., Huseynli, F. S., Huseynzade, M. B. (2026). Analytical calculation of contact pressure under thermoelastic deformation conditions in sucker rod pumps. SOCAR Proceedings, 1, 99-108.
  2. Abbasov, V., Amirov, F., Karimov, A. (2025). Wear properties of camshaft cams and improvement of their wear resistance. Reliability: Theory & Applications, 20(SI7(83)), 297–303.
  3. Bashirov, R. J., Rasulov, F. R. (2022). Formation of high strength and corrosion resistance composition cover on the surface of casting. Kazakhstan: Eurasian Journal of Physics and Functional Materials, 6(4), 285-297.
  4. Gilaev, G. G., Khabibullin, M. Ya., Bakhtizin, R. N. (2023). Improvement of methods for combat with sand in production wells. SOCAR Proceedings, 1, 87–93.
  5. Guliev, H. F., Seyfullaeva, Kh., I. (2022). Optimal control problem with coefficients for the equation of vibrations of a thin plate with discontinuous solution. Proceedings of the Institute of Mathematics and Mechanics of Azerbaijan. Academy of Sciences, 48(2), 238–248.
  6. Huseynov, A., Huseynli, F., Safarov, M. (2025). Reliability prediction of precision parts of fuel pumps with enhanced surface hardness achieved through laser technology. Tribologia – Finnish Journal of Tribology, 42(1–2), 64–71.
  7. Huseynov, A. G., Nazarov, I. A, Huseynli, F. S., Safarov, M. (2025, May). Determinatıon of deformation and machining allowance of precision parts hardened by laser method. Reliability: Theory & Applications, 7 (83), 20, 379–385.
  8. Huseynov, A., Nazarov, I., Huseynli, F., Safarov, M. (2025). Challenges of property inheritance during the technological processing of fuel pump precision parts. Tribologia - Finnish Journal of Tribology, 42(1–2), 72–79.
  9. Jamalbayov, M. A., Valiyev, N. A., Ibrahimov, Kh. M., et al. (2024). Energy and efficiency optimization in sucker-rod pumping using discrete-imitation modeling concept: Application to well operations in the Bibi-Heybat field of Azerbaijan.SOCAR Proceedings, SI1, 95–101.
  10. Karimov, A. F. (2024, May). Improvement of the design and production of camshafts. In book: «Innovative equipment and technologies in mechanical engineering» Vol. 17. St. Petersburg: Research Center MS.
  11. Mohanty, R. R., Girina, O. A., Fonstein, N. M. (2011). Effect of heating rate on the austenite formation in low-carbon high-strength steels annealed in the intercritical region. Metallurgical and Materials Transactions A, 42, 3680–3690.
  12. Bashirov, R. J., Veysov, R. A., Astanova, E. R., et al. (2025). Restoration technologies for precision diesel injector components using vacuum chromotitanizing and grinding. SOCAR Proceedings, 3, 164-169.
  13. Rasulov, F. R. (2020). Mathematical model of crystallization and cooling process of coated casting. In: The 7th International Conference on Control and Optimization With İndustrial Applications, Baku, 26–28 August.
  14. Sun, X., Li, Y. (2019). Comparison of hot deformation behaviour and microstructural evolution between PM and IM alloys. Materials & Design, 165, 107582. 
  15. Tang, G., Zhang, J. (2024). Temperature–strain prediction driven by deformation induced heating in SCM440 steel. Heliyon, 10(4), e26322.
  16. Abdullayev, V. M. (2018). Numerical solution to optimal control problems with multipoint and integral conditions. Proceedings of the Institute of Mathematics and Mechanics of Azerbaijan. Academy of Sciences, 44(2), 171–186.
  17. Wang, X. (2022). Effect of residual deformation energy and critical heating rate on cubic texture and grain growth behavior of severely deformed aluminum foil. Materials, 15(4), 1395.
  18. Wu, M., Liu, W., Xiao, D., et al. (2023). Influence of thermal exposure on the microstructure and mechanical behaviors of an Al–Cu–Li alloy. Materials & Design, 241, 111767.
  19. Yan, H., Wang, W., Zhang, S., Ma, S. (2022). Microstructure and thermal deformation behavior of hot pressing sintered Zr–6Al–0.1B alloy. Materials, 15(5), 1816.
  20. Zhao, J., Wang, J., Li, J. (2024). The effects of super-fast heating rate and holding time on the microstructure and properties of DP Fe-0.16C-1.4Mn sheet steel. Materials, 17(20), 4982.
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DOI: 10.5510/OGP20260201204

E-mail: shamkhal.asadov@mail.ru


Fereshteh Koushki1, Mona Naghdehforoushha2

1Islamic Azad University, Qazvin, Iran; 2Islamic Azad University, Takestan, Iran

Metaheuristic-assisted DL and ML approaches integrated with DEA models to predict the performance of petroleum refineries


Performance evaluation of oil exploitation centers is crucial in both economic and environmental aspects. Data Envelopment Analysis (DEA), as a powerful mathematical optimization model, is commonly used to measure the efficiency of multi-input/output decision making units (DMUs). However, computational limitations in solving large-scale evaluation problems have motivated this research to combine DEA models with artificial intelligence (AI) techniques for estimating the efficiency scores of oil refineries. Machine learning (ML) and deep learning (DL) methods can be employed to address the challenges associated with large-scale mathematical optimization models. Additionally, metaheuristic methods can be utilized to improve hyperparameters of ML and DL algorithms. In this study, metaheuristic-assisted DL and ML approaches were integrated with mathematical linear programming to estimate the performance of oil refineries. First, the efficiency scores of oil refineries calculated by DEA model were used as training and testing datasets for the DL and ML models - Long Short-Term Memory (LSTM) and Multi-Layer Perceptron (MLP)-. Then, the metaheuristic algorithms - Grid Search and Particle Swarm Optimization (PSO) - were used to optimize the hyperparameters of the LSTM and MLP models. The results indicated that tuning the hyperparameters of the MLP and LSTM algorithms significantly reduced prediction errors. Additionally, LSTM-based algorithms had higher prediction accuracy compared to MLP-based algorithms. Furthermore, the LSTM-PSO approach predicted the efficiency scores with the highest accuracy value of 96%.

Keywords: oil refinery; performance evaluation; Data Envelopment Analysis (DEA); Machine Learning (ML); Deep learning (DL); Metaheuristics.

Date submitted: 28.08.2025     Date accepted: 26.01.2026

Performance evaluation of oil exploitation centers is crucial in both economic and environmental aspects. Data Envelopment Analysis (DEA), as a powerful mathematical optimization model, is commonly used to measure the efficiency of multi-input/output decision making units (DMUs). However, computational limitations in solving large-scale evaluation problems have motivated this research to combine DEA models with artificial intelligence (AI) techniques for estimating the efficiency scores of oil refineries. Machine learning (ML) and deep learning (DL) methods can be employed to address the challenges associated with large-scale mathematical optimization models. Additionally, metaheuristic methods can be utilized to improve hyperparameters of ML and DL algorithms. In this study, metaheuristic-assisted DL and ML approaches were integrated with mathematical linear programming to estimate the performance of oil refineries. First, the efficiency scores of oil refineries calculated by DEA model were used as training and testing datasets for the DL and ML models - Long Short-Term Memory (LSTM) and Multi-Layer Perceptron (MLP)-. Then, the metaheuristic algorithms - Grid Search and Particle Swarm Optimization (PSO) - were used to optimize the hyperparameters of the LSTM and MLP models. The results indicated that tuning the hyperparameters of the MLP and LSTM algorithms significantly reduced prediction errors. Additionally, LSTM-based algorithms had higher prediction accuracy compared to MLP-based algorithms. Furthermore, the LSTM-PSO approach predicted the efficiency scores with the highest accuracy value of 96%.

Keywords: oil refinery; performance evaluation; Data Envelopment Analysis (DEA); Machine Learning (ML); Deep learning (DL); Metaheuristics.

Date submitted: 28.08.2025     Date accepted: 26.01.2026

References

  1. Charnes, A., Cooper, W. W., Rhodes, E. (1978). Measuring the efficiency of decision-making units. European Journal of Operational Research, 2, 429–444.
  2. Bahrami, A., Rakhshaninejad, M., Ghousi, R., Atashi, A. (2025). Enhancing machine learning performance in cardiac surgery ICU: Hyperparameter optimization with metaheuristic algorithm. PLoS One, 20(2), e0311250.
  3. Li, H., Dong, K., Sun, R., et al. (2017). Sustainability assessment of refining enterprises using a DEA-based model. Sustainability, 9(4), 620.
  4. Tavana, M., Khalili-Damghani, K., Santos Arteaga, F. J., Hosseini, A. (2019). A fuzzy multi-objective multi-period network DEA model for efficiency measurement in oil refineries. Computers & Industrial Engineering, 135, 143-155.
  5. Mohammed Atris, A. (2020). Assessment of oil refinery performance: Application of data envelopment analysis-discriminant analysis. Resources Policy, 65, 101543.
  6. Sánchez Robles, B., Herrador-Alcaide, T., Montserrat, H-S. (2022). Efficiency of European oil companies: an empirical analysis. Energy Efficiency, 15, 63.
  7. Oliveira, M. S. D., Lizot, M., Siqueira, H., et al. (2023). Efficiency analysis of oil refineries using DEA window analysis, cluster analysis, and malmquist productivity index. Sustainability, 15(18), 13611.
  8. Ngeti, K. B. D. J. R., Mafukidze, B. S. (2024). DEA analysis of national oil companies. Open Access Library Journal, 11(12).
  9. Hasanvand, M., Taleghani, M., Fathi-Vajargah, B. (2025). Evaluating performance of national oil and gas production facilities: A fuzzy network approach to manage undesirable outputs. International Journal of Applied Operational Research, 13(1), 17-38.
  10. Zhu, N., Zhu, Ch., Emrouznejad, A. (2021). A combined machine learning algorithms and DEA method for measuring and predicting the efficiency of Chinese manufacturing listed companies. Journal of Management Science and Engineering, 6(4), 435-448.
  11. Kaur, G., Rajni, Sivia, J. S. (2024). Integrating data envelopment analysis and machine learning approaches for energy optimization, decreased carbon footprints, and wheat yield prediction across North-Western India. Journal of Soil Science and Plant Nutrition, 24, 1424–1447.
  12. Koushki, F., Naghdehforoushha, M. (2025). AI-Powered selection and classification of resilient suppliers: a hybrid approach using fuzzy DEA and ML techniques and its application in the textile industry. Advances in Industrial Engineering, 59(2), 307-319.
  13. Koushki, F., Naghdehforoushha, M. (2025). Integrating a novel fuzzy network DEA method with machine learning algorithms to predict the performance of production systems. Asia-Pacific Journal of Operational Research. https://doi. org/10.1142/S0217595925500320.
  14. Koushki, F., Naghdehforoushha, M. (2025). Predicting the sustainability of supply chains by integrating a novel network DEA model with ML techniques. Journal of Industrial and Management Optimization, 21(8), 5326-5347. 
  15. Al Bataineh, A., Kaur D., Jalali, S. M. J. (2022). Multi-layer perceptron training optimization using nature inspired computing. IEEE Access, 10, 36963-36977.
  16. Bahtiyar, H., Soydaner, D., Yüksel, E. (2022). Application of multilayer perceptron with data augmentation in nuclear physics. Applied Soft Computing, 128, 109470.
  17. Ghojogh, B., Ghodsi, A. (2023). Recurrent neural networks and long short-term memory networks: Tutorial and survey. https://arxiv.org/abs/2304.11461
  18. Liashchynskyi, P., Liashchynskyi, P. (2019). Grid search, random search, genetic algorithm: a big comparison for NAS. https://arxiv.org/abs/1912.06059
  19. Houssein, E. H., Gad, A. G., Hussain, K., Suganthan, P. N. (2021). Major advances in particle swarm optimization: Theory, analysis, and application. Swarm and Evolutionary Computation, 63, 100868.
  20. Gad, A. G. (2022). Particle swarm optimization algorithm and its applications: A systematic review. Archives of Computational Methods in Engineering, 29, 2531–2561.
  21. Li, L., Jamieson, K., Rostamizadeh, A., et al. (2021). A system for massively parallel hyperparameter tuning. Communications of the ACM, 64(12), 72–81.
  22. Agrawal, S., Chakraborty, A. (2021). A comparative study of particle swarm optimization and its variants for hyperparameter tuning in deep learning. Procedia Computer Science, 192, 1722–1731.
  23. Singh, A., Singh, S. (2021). Recent advances in metaheuristic algorithms for hyperparameter tuning: A review. Swarm and Evolutionary Computation, 62, 100840.
  24. Rashedi, E., Nezamabadi-pour, H., Saryazdi, S. (2020). A comprehensive review on metaheuristic algorithms for hyperparameter optimization. Applied Soft Computing, 91, 106260.
  25. Gupta, A., Khandelwal, S. (2022). Comparative study of metaheuristic optimization techniques in deep learning: Challenges and future directions. Journal of Computational Science, 59, 101537.
  26. Shiomi, H., Takahashi, M., Tanaka, T. (2025). Hybrid PSO-deep learning model for hyperparameter optimization in time series forecasting. Expert Systems with Applications, 225, 120218.
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DOI: 10.5510/OGP20260201205

E-mail: f_koushki13@iau.ac.ir


Zh. G. Nursultanova

«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan

Estimation of the impact of macroeconomic variables in the short-term and long-term on the volume of goods exports of Kazakhstan and Azerbaıjan


The author presents a study dedicated to a quantitative assessment of the influence of key macroeconomic factors on the dynamics of commodity export volumes in the Republic of Kazakhstan and the Republic of Azerbaijan. The article examines the problem of the high dependence of export earnings on commodity prices and external macroeconomic conditions, a topical issue for the national economy. The study aims to identify long-term and short-term relationships between commodity exports, total international reserves, the base rate, residents' income from foreign sources, and Brent crude oil prices. The article consistently presents methodological approaches to time series analysis, including stationarity testing, cointegration testing, evaluation of error correction models, and the construction of autoregressive moving average models of various orders. To analyze short-term reactions, an impulse response function is used to identify the nature of the reaction of commodity exports to macroeconomic shocks. The author finds that Brent crude oil prices are the most significant factor exerting a persistent influence on commodity exports in the long and short term for both countries. Total international reserves and the base rate exhibit a moderate impact, while the impact of residents' income from foreign sources is characterized by a short-term and statistically weak effect. The article concludes that commodity exports are highly sensitive to external shocks and confirms the feasibility of considering macroeconomic factors when formulating trade and currency policies. The results can be used to forecast export performance and assess the economy's resilience to fluctuations in the external environment.

Keywords: oil price; exports; total international reserves; income from foreign sources; interest rate; autoregressive integrated moving average; vector autoregression model; autoregressive distributed lag model.

Date submitted: 30.11.2025     Date accepted: 01.04.2026

The author presents a study dedicated to a quantitative assessment of the influence of key macroeconomic factors on the dynamics of commodity export volumes in the Republic of Kazakhstan and the Republic of Azerbaijan. The article examines the problem of the high dependence of export earnings on commodity prices and external macroeconomic conditions, a topical issue for the national economy. The study aims to identify long-term and short-term relationships between commodity exports, total international reserves, the base rate, residents' income from foreign sources, and Brent crude oil prices. The article consistently presents methodological approaches to time series analysis, including stationarity testing, cointegration testing, evaluation of error correction models, and the construction of autoregressive moving average models of various orders. To analyze short-term reactions, an impulse response function is used to identify the nature of the reaction of commodity exports to macroeconomic shocks. The author finds that Brent crude oil prices are the most significant factor exerting a persistent influence on commodity exports in the long and short term for both countries. Total international reserves and the base rate exhibit a moderate impact, while the impact of residents' income from foreign sources is characterized by a short-term and statistically weak effect. The article concludes that commodity exports are highly sensitive to external shocks and confirms the feasibility of considering macroeconomic factors when formulating trade and currency policies. The results can be used to forecast export performance and assess the economy's resilience to fluctuations in the external environment.

Keywords: oil price; exports; total international reserves; income from foreign sources; interest rate; autoregressive integrated moving average; vector autoregression model; autoregressive distributed lag model.

Date submitted: 30.11.2025     Date accepted: 01.04.2026

References

  1. Newbold, P. (1983). ARIMA model building and the time series analysis approach to forecasting. Journal of Forecasting, 2(1), 23-35.
  2. Fattah, J., Ezzine, L., Aman, Z., et al. (2018). Forecasting of demand using ARIMA model. International Journal of Engineering Business Management, 10.
  3. Makridakis, S., Hibon, M. (1997). ARMA models and the Box–Jenkins methodology. Journal of Forecasting, 16(3), 147-163.
  4. Abad, P., Benito, S., López, C. (2014). A comprehensive review of value at risk methodologies. The Spanish Review of Financial Economics, 12(1), 15-32.
  5. Sims, C. A. (1980). Macroeconomics and reality. Econometrica, 48(1), 1-48. 
  6. Jamalzade, G., Saldanlı, A., Jamalzade, E. (2024). Factors afeecting the total foreign exchange reserve adequacy of the central bank: Turkey and Azerbaijan. Agora International Journal of Economical Sciences, 18(1), 82-97.
  7. Arize, A. C., Malindretos, J. (2012). Foreign exchange reserves in Asia and its impact on import demand. International Journal of Economics and Finance, 4(3), 21-32.
  8. Allegret, J. P., Allegret, A. (2018). The role of international reserves holding in buffering external shocks. Applied Economics, 50(29), 3128-3147.
  9. Maslennikov, V. V., Korovin, D. I., Afanasyeva, O. N. (2019, December). Refinancing rate as an impact on global economic development. In: External Challenges and Risks for Russia in the Context of the World Community’s Transition to Polycentrism: Economics, Finance and Business (ICEFB 2019). Atlantis Press.
  10. Yuliadi, I., Sari, N. P., Setiawati, S. A. P., Ismail, S. H. (2024). The effect of exchange rate, inflation, interest rate and import on exports in ASEAN countries. Jurnal Ekonomi & Studi Pembangunan, 25(1), 78-86.
  11. Sudarusman. E., Prasetyo, T. U., Suparmono, S., Partina, A. (2021). Influence of exchange rate, world income, interest rates, and investments in Indonesian exports. The Journal of Asian Finance, Economics and Business, 8(6), 621-628.
  12. Mammadov, M. A., Yadigarov, T. A., Safarova, G. N., et al. (2024). An economic and mathematical modeling for risk assessment of innovative activities an enterprise in oil and gas industry. SOCAR Proceedings, 4, 139-146.
  13. Safarova, G. N. (2025). Assessment of synergistic effects in oil and gas industry enterprises through the application of economic and mathematical methods. SOCAR Proceedings, 3, 137-147.
  14. Mukhtarov, S., Aliyev, S., Zeynalov, J. (2020). The effects of oil prices on macroeconomic variables: Evidence from Azerbaijan. International Journal of Energy Economics and Policy, 10(1), 72-80.
  15. Zulfigarov, F., Neuenkirch, M. (2020). The impact of oil price changes on selected macroeconomic indicators in Azerbaijan. Economic Systems, 44(4), 100814.
  16. Moldabekova, G., Raimbekov, Z., Tleppaev, A. M., et al. (2022). The impact of oil prices on the macroeconomic indicators of Kazakhstan and the consequences for the formation of social policy. International Journal of Energy Economics and Policy, 12(4), 447-454.
  17. Czech, K., Niftiyev, I. (2021). The impact of oil price shocks on oil-dependent countries’ currencies: The case of Azerbaijan and Kazakhstan. Journal of Risk and Financial Management, 14(9), 431.
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  21. Al-Maamary, H. M., Kazem, H. A., Chaichan, M. T. (2017). The impact of oil price fluctuations on common renewable energies in GCC countries. Renewable and Sustainable Energy Reviews, 75, 989-1007.
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  23. Jwair, A. M., Zoghlami, F., Al-Khazaleh, S. M. (2024). Using the ARDL approach, measure the impact of global oil price fluctuations on foreign reserves. Cuadernos de Economía, 47(133), 153-165.
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DOI: 10.5510/OGP20260201206

E-mail: Nursultanova.Zhaniya@gmail.com


U. S. Nwigwe, O. D. Ikwechegh, C. S. Ezeanyaeji

Alex Ekwueme Federal University Ndufu-Alike, Ikwo, Ebonyi State, Nigeria

Novel eco-friendly extract for corrosion protection of materials in 1 M H₂SO₄ environment during transportation and storage of oil sector


In this study, the corrosion inhibition effect of Dioscorea dumentorum leaf extract on mild steel was evaluated in a 1 M H₂SO₄ solution at various concentrations, using weight loss measurements and Tafel polarization techniques. This study represents an effort to curb metallic corrosion in the transportation and storage sectors of the oil industry. The highest inhibition efficiency recorded was 90.8% in 3 g of inhibitor concentration with a corrosion rate of 0.0140 mpy and weight loss of 0.2567 g, respectively. Also, the inhibition efficiency increased with higher concentrations of the Dioscorea dumentorum leaf extract. The presence of phytochemical constituents such as saponins, phenols, steroids, and flavonoids in the extract was found to be responsible for the effective inhibition, as these compounds adsorbed onto the metal surface. The adsorption of the inhibitor on the mild steel surface followed both Langmuir and Temkin adsorption isotherms, as plots for both isotherms showed good regression that were all near unity (≅1), respectively, for samples with 0.5 to 3 g/0.25 L extract concentrations, while the computed Gibbs free energy of the adsorption process (ΔG0ads) for both isotherm models showed values less than -20 kJ mol−1. This suggests that adsorption of the extract onto the metal surfaces was by physisorption. The results confirm that the leaf extract acts as a corrosion inhibitor by enhancing surface protection on the metal.

Keywords: polarization curves; mild steel coupons; sulfuric solution; physisorption; Dioscorea dumentorum; corrosion inhibition.

Date submitted: 30.08.2025     Date accepted: 30.04.2026

In this study, the corrosion inhibition effect of Dioscorea dumentorum leaf extract on mild steel was evaluated in a 1 M H₂SO₄ solution at various concentrations, using weight loss measurements and Tafel polarization techniques. This study represents an effort to curb metallic corrosion in the transportation and storage sectors of the oil industry. The highest inhibition efficiency recorded was 90.8% in 3 g of inhibitor concentration with a corrosion rate of 0.0140 mpy and weight loss of 0.2567 g, respectively. Also, the inhibition efficiency increased with higher concentrations of the Dioscorea dumentorum leaf extract. The presence of phytochemical constituents such as saponins, phenols, steroids, and flavonoids in the extract was found to be responsible for the effective inhibition, as these compounds adsorbed onto the metal surface. The adsorption of the inhibitor on the mild steel surface followed both Langmuir and Temkin adsorption isotherms, as plots for both isotherms showed good regression that were all near unity (≅1), respectively, for samples with 0.5 to 3 g/0.25 L extract concentrations, while the computed Gibbs free energy of the adsorption process (ΔG0ads) for both isotherm models showed values less than -20 kJ mol−1. This suggests that adsorption of the extract onto the metal surfaces was by physisorption. The results confirm that the leaf extract acts as a corrosion inhibitor by enhancing surface protection on the metal.

Keywords: polarization curves; mild steel coupons; sulfuric solution; physisorption; Dioscorea dumentorum; corrosion inhibition.

Date submitted: 30.08.2025     Date accepted: 30.04.2026

References

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DOI: 10.5510/OGP20260201207

E-mail: nwigweuzoma@gmail.com


M. A. Ismayilov1, M. Z. Rahimov2, A. M. Aliyev1, S. H. Abbasov1

1Azerbaijan State Oil and Industry University, Baku, Azerbaijan; 2Warwick Manufacturing Group, University of Warwick, Coventry, UK

Data-driven assessments of Caspian Sea offshore wind energy: ERA5 – Weibull analysis


This study presents the first comprehensive, basin-wide assessment of offshore wind energy potential in the Caspian Sea based on a unified and reproducible analytical framework. We process 85 years (1940–2024) of hourly ERA5 reanalysis at 0.25° resolution for 653 grid points, assigning each to the EEZ of Azerbaijan, Iran, Kazakhstan, Russia, or Turkmenistan. A two-stage 90th-percentile filter selects the windiest decile per EEZ; two-parameter Weibull distributions provide hub-height (100 m) wind-power density (WPD) statistics. High-potential zones cover ≈36,10 km2 – 10 % of the sea yet about 70–85 % of its usable wind. Median 100 m wind speeds peak in Turkmenistan (7.52 m s⁻¹), however, the highest wind power density is found in Azerbaijan (613.48 W m⁻²), followed by Russia (560.62 W m⁻²), Kazakhstan (555.90 W m⁻²), and Turkmenistan (477.62 W m⁻²), while dropping significantly in Iran (168.50 W m⁻²). Shallow depths, existing oil-and-gas logistics and proximity to load centers make ≥1 GW pilot projects viable in the northern shelf before 2030. A 15 GW build-out by 2040 could displace ≈40 TWh of gas-fired generation and avoid ≈25 Mt CO₂ annually. The reproducible Python pipeline forms an updatable evidence base that can be refined with LiDAR campaigns and mesoscale down-scaling to underpin bankable offshore-wind development.

Keywords: Caspian Sea; offshore wind resource; ERA5 reanalysis; Weibull distribution; wind-power density; renewable energy; data-driven analysis.

Date submitted: 12.08.2025     Date accepted: 03.11.2025

This study presents the first comprehensive, basin-wide assessment of offshore wind energy potential in the Caspian Sea based on a unified and reproducible analytical framework. We process 85 years (1940–2024) of hourly ERA5 reanalysis at 0.25° resolution for 653 grid points, assigning each to the EEZ of Azerbaijan, Iran, Kazakhstan, Russia, or Turkmenistan. A two-stage 90th-percentile filter selects the windiest decile per EEZ; two-parameter Weibull distributions provide hub-height (100 m) wind-power density (WPD) statistics. High-potential zones cover ≈36,10 km2 – 10 % of the sea yet about 70–85 % of its usable wind. Median 100 m wind speeds peak in Turkmenistan (7.52 m s⁻¹), however, the highest wind power density is found in Azerbaijan (613.48 W m⁻²), followed by Russia (560.62 W m⁻²), Kazakhstan (555.90 W m⁻²), and Turkmenistan (477.62 W m⁻²), while dropping significantly in Iran (168.50 W m⁻²). Shallow depths, existing oil-and-gas logistics and proximity to load centers make ≥1 GW pilot projects viable in the northern shelf before 2030. A 15 GW build-out by 2040 could displace ≈40 TWh of gas-fired generation and avoid ≈25 Mt CO₂ annually. The reproducible Python pipeline forms an updatable evidence base that can be refined with LiDAR campaigns and mesoscale down-scaling to underpin bankable offshore-wind development.

Keywords: Caspian Sea; offshore wind resource; ERA5 reanalysis; Weibull distribution; wind-power density; renewable energy; data-driven analysis.

Date submitted: 12.08.2025     Date accepted: 03.11.2025

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DOI: 10.5510/OGP20260201208

E-mail: mahmud.ismayilov.az@asoiu.edu.az


S. Z. Ismayilova1, R. H. Ismayilov1, S. Z. Hamidov2, M. T. Huseynova1, L. Sh. Guliyeva1, V. J. Abdullayev3, F. F. Valiyev3, Onur Şahin4, Chi-How Peng5

1Institute of Chemistry, The Ministry of Science and Education of the Republic of Azerbaijan, Baku, Azerbaijan; 2Azerbaijan Technological University, Ganja, Azerbaijan; 3«OilGasScientificResearchProject» Institute, SOCAR, Baku, Azerbaijan; 4Department of Occupational Health & Safety, Sinop University, Türkiye; 5Department of Chemistry, National Taiwan University, Taipei, Taiwan, ROC

Copper(II) complexes with pyrazine-modulated tetrapyridyltriamine ligands: synthesis, crystal structures, and antimicrobial properties


Two new mononuclear Cu(II) complexes, [Cu(H3pzpz)(NO3)]∙NO3∙H2O (1) and [Cu(H3tpz)Cl]2 ∙2(Cl)∙5H2O (2), with pyrazine-modulated oligo- α-pyridylamine ligands N2-(pyrazin-2-yl)-N6-(6-(pyrazin-2-ylaminopyridin-2-yl)pyridin-2,6-diamine (H3pzpz) and N2-(pyrazin-2-yl)-N6-(6-(pyridin-2-ylaminopyridin-2-yl)pyridin-2,6-diamine (H3tpz), have been synthesized, structurally characterized, and their antimicrobial efficacy has been studied. Single-crystal X-ray diffraction revealed that the central Cu(II) atom in complexes 1 and 2 was located in a distorted trigonal bipyramidal geometry. In both complexes, H3pzpz or H3tpz acts as a tetradentate ligand; it coordinates the copper(II) ion in an all-anti conformation, and the Cu(II) atom is five-coordinated in a distorted trigonal bipyramidal geometry. The distorted trigonal bipyramidal structures of the compounds are consistent with both the «inverted type» EPR spectra, in which g‖ is smaller than g┴, and two spin-allowed transitions in the visible region of their electronic spectra. The complexes are built into a three-dimensional network by extensive hydrogen bonding and intermolecular π-π interactions, which stabilize the crystal packing. The antimicrobial efficacy of 1 and 2 was evaluated against P. aeruginosa, M. phlei, A. niger, and P. chrysogenum. Both complexes demonstrated significant potency, with complex 2 showing superior activity, particularly against P. aeruginosa with an inhibition zone of 26 mm compared to 20 mm for complex 1 (at 100 μg/mL). The sulfur-binding affinity and redox activity of these metal complexes also present potential for neutralizing hydrogen sulfide (H2S) in petroleum reservoirs and preventing the oxidative degradation of crude oil. Specifically, the catalytic properties of Cu(II) complexes may be utilized as inhibitors or catalysts in hydrocarbon oxidation reactions during petroleum refining processes.

Keywords: modulated oligo-α-aminopyridine ligand; copper complex; hydrogen bonds; supramolecular networks; antimicrobial activity.

Date submitted: 12.03.2026     Date accepted: 15.05.2026

Two new mononuclear Cu(II) complexes, [Cu(H3pzpz)(NO3)]∙NO3∙H2O (1) and [Cu(H3tpz)Cl]2 ∙2(Cl)∙5H2O (2), with pyrazine-modulated oligo- α-pyridylamine ligands N2-(pyrazin-2-yl)-N6-(6-(pyrazin-2-ylaminopyridin-2-yl)pyridin-2,6-diamine (H3pzpz) and N2-(pyrazin-2-yl)-N6-(6-(pyridin-2-ylaminopyridin-2-yl)pyridin-2,6-diamine (H3tpz), have been synthesized, structurally characterized, and their antimicrobial efficacy has been studied. Single-crystal X-ray diffraction revealed that the central Cu(II) atom in complexes 1 and 2 was located in a distorted trigonal bipyramidal geometry. In both complexes, H3pzpz or H3tpz acts as a tetradentate ligand; it coordinates the copper(II) ion in an all-anti conformation, and the Cu(II) atom is five-coordinated in a distorted trigonal bipyramidal geometry. The distorted trigonal bipyramidal structures of the compounds are consistent with both the «inverted type» EPR spectra, in which g‖ is smaller than g┴, and two spin-allowed transitions in the visible region of their electronic spectra. The complexes are built into a three-dimensional network by extensive hydrogen bonding and intermolecular π-π interactions, which stabilize the crystal packing. The antimicrobial efficacy of 1 and 2 was evaluated against P. aeruginosa, M. phlei, A. niger, and P. chrysogenum. Both complexes demonstrated significant potency, with complex 2 showing superior activity, particularly against P. aeruginosa with an inhibition zone of 26 mm compared to 20 mm for complex 1 (at 100 μg/mL). The sulfur-binding affinity and redox activity of these metal complexes also present potential for neutralizing hydrogen sulfide (H2S) in petroleum reservoirs and preventing the oxidative degradation of crude oil. Specifically, the catalytic properties of Cu(II) complexes may be utilized as inhibitors or catalysts in hydrocarbon oxidation reactions during petroleum refining processes.

Keywords: modulated oligo-α-aminopyridine ligand; copper complex; hydrogen bonds; supramolecular networks; antimicrobial activity.

Date submitted: 12.03.2026     Date accepted: 15.05.2026

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DOI: 10.5510/OGP20260201209

E-mail: ismayilov.rayyat@gmail.com