Burial and thermal maturity modeling of the Middle Cretaceous–Early Miocene petroleum system, Iranian sector of the Persian Gulf

Mashhadi, Zahra Sadat; Rabbani, Ahmad Reza; Kamali, Mohammad Reza; Mirshahani, Maryam; Khajehzadeh, Ahmad

doi:10.1007/s12182-015-0040-y

Cited by 23 publications

(10 citation statements)

References 34 publications

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“…This contains more than two-thirds of the proven oil reserves of the world (Rabbani 2007;Haghi et al 2013). Pabdeh (Paleocene), Gurpi (Campanian-Paleocene), Ahmadi member of Sarvak (Cenomanian), and Kazhdumi (Albian) are considered as the most probable source rocks of the Middle Cretaceous-Early Miocene petroleum system of the studied area (Mashhadi et al 2015). These formations are illustrated in Fig.…”

Section: Data Gathering and Preparationmentioning

confidence: 98%

Prediction of vitrinite reflectance values using machine learning techniques: a new approach

Sadeghtabaghi

Talebkeikhah

Rabbani

2020

J Petrol Explor Prod Technol

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Vitrinite reflectance (VR) is considered the most used maturity indicator of source rocks. Although vitrinite reflectance is an acceptable parameter for maturity and is widely used, it is sometimes difficult to measure. Furthermore, Rock-Eval pyrolysis is a current technique for geochemical investigations and evaluating source rock by their quality and quantity of organic matter, which provide low cost, quick, and valid information. Predicting vitrinite reflectance by using a quick and straightforward method like Rock-Eval pyrolysis results in determining accurate and reliable values of VR with consuming low cost and time. Previous studies used empirical equations for vitrinite reflectance prediction by the Tmax data, which was accompanied by poor results. Therefore, finding a way for precise vitrinite reflectance prediction by Rock-Eval data seems useful. For this aim, vitrinite reflectance values are predicted by 15 distinct machine learning models of the decision tree, random forest, support vector machine, group method of data handling, radial basis function, multilayer perceptron, adaptive neuro-fuzzy inference system, and multilayer perceptron and adaptive neuro-fuzzy inference system, which are coupled with evolutionary optimization methods such as grasshopper optimization algorithm, bat algorithm, particle swarm optimization, and genetic algorithm, with four inputs of Rock-Eval pyrolysis parameters of Tmax, S1/TOC, HI, and depth for the first time. Statistical evaluations indicate that the decision tree is the most precise model for VR prediction, which can estimate vitrinite reflectance precisely. The comparison between the decision tree and previous proposed empirical equations indicates that the machine learning method performs much more accurately.

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Section: Data Gathering and Preparationmentioning

confidence: 98%

Prediction of vitrinite reflectance values using machine learning techniques: a new approach

Sadeghtabaghi

Talebkeikhah

Rabbani

2020

J Petrol Explor Prod Technol

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“…The achievement of optimum thermal maturity of organic matter is essential for a rock to act as a prolific potential source rock as immature or postmature source rocks cannot generate hydrocarbons (Makky et al 2014;Mashhadi et al 2015). The thermal maturity is estimated using T max and HI from the Rock-Eval data.…”

Section: Thermal Maturity Levelmentioning

confidence: 99%

“…In case of the Patala Formation, the T max values range from 436 • (PN-1) to 447 • C (PN-11) with an average value of 439.9 (table 1), which indicates that the organicrich intervals of the formation are thermally mature and can generate hydrocarbons if rest of the source rock prerequisites are available (figure 6). In a sedimentary basin, both the burial depth and organic matter type affect the thermal maturity levels of organic matter (Selley and Sonnenberg 2014;Mashhadi et al 2015). Here, in case of the Patala Formation, the change in thermal maturity levels is also due to change in burial depth as well as due to change in types of the organic matter (table 1; figures 3 and 6).…”

Section: Thermal Maturity Levelmentioning

confidence: 99%

Hydrocarbon source rock potential evaluation of the Late Paleocene Patala Formation, Salt Range, Pakistan: Organic geochemical and palynofacies approach

et al. 2018

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Organic geochemical and palynofacies analyses were carried out on shale intervals of the Late Paleocene Patala Formation at Nammal Gorge Section, western Salt Range, Pakistan. The total organic carbon content and Rock-Eval pyrolysis results indicated that the formation is dominated by type II and type III kerogens. Rock-Eval T max vs. hydrogen index (HI) and thermal alteration index indicated that the analysed shale intervals present in the formation are thermally mature. S 1 and S 2 yields showed poor source rock potential for the formation. Three palynofacies assemblages including palynofacies-1, palynofacies-2 and palynofacies-3 were identified, which are prone to dry gas, wet gas and oil generation, respectively. The palynofacies assessment revealed the presence of oil/gas and gas prone type II and type III kerogens in the formation and their deposition on proximal shelf with suboxic to anoxic conditions. The kerogen macerals are dominated by vitrinite and amorphinite with minor inertinite and liptinite. The kerogen macerals are of both marine and terrestrial origin, deposited on a shallow shelf. Overall, the dark black carbonaceous shales present within the formation act as a source rock for hydrocarbons with poor-to-moderate source rock quality, while the grey shales act as a poor source rock for hydrocarbon generation.

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“…The petroleum system has recently been investigated in the NW Persian Gulf and adjacent onshore Iran as well as Iraq and Kuwait (e.g. Abdullah et al, 1997;Pitman et al, 2004;Rudkiewicz et al, 2007;Abeed et al, 2011Abeed et al, , 2012Opera et al, 2013;Mashhadi et al, 2015a;Baniasad et al, 2016Baniasad et al, , 2017Karimi et al, 2016b). In addition, a seriers of 1D and 2D basin modelling studies (Bashari, 2008;Jahantigh Pak et al, 2014;Mashhadi and Rabbani, 2015a, b;Baniasad et al, 2016) have attempted to reconstruct the burial and thermal history of Cretaceous source rocks in the NW Persian Gulf.…”

Section: Introductionmentioning

confidence: 99%

Burial, Temperature and Maturation History of Cretaceous Source Rocks in the Nw Persian Gulf, Offshore Sw Iran: 3d Basin Modelling

Baniasad

Sachse

Littke

et al. 2019

Journal of Petroleum Geology

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This study presents a 3D numerical model of a study area in the NW part of the Persian Gulf, offshore SW Iran. The purpose is to investigate the burial and thermal history of the region from the Cretaceous to the present day, and to investigate the location of hydrocarbon generating kitchens and the relative timing of hydrocarbon generation/migration versus trap formation. The study area covers about 20,000 km2 and incorporates part of the intra‐shelf Garau‐Gotnia Basin and the adjacent Surmeh‐Hith carbonate platform. A conceptual model was developed based on the interpretation of 2700 km of 2D seismic lines, and depth and thickness maps were created tied to data from 20 wells. The thermal model was calibrated using bottom‐hole temperature and vitrinite reflectance data from ten wells, taking into account the main phases of erosion/non‐deposition and the variable temporal and spatial heat flow histories. Estimates of eroded thicknesses and the determination of heat‐flow values were performed by burial and thermal history reconstruction at various well and pseudo‐well locations. Burial, temperature and maturation histories are presented for four of these locations. Detailed modelling results for Neocomian and Albian source rock successions are provided for six locations in the intra‐shelf basin and the adjacent carbonate platform. Changes in sediment supply and depocentre migration through time were analyzed based on isopach maps representing four stratigraphic intervals between the Tithonian and the Recent. Backstripping at various locations indicates variable tectonic subsidence and emergence at different time periods. The modelling results suggest that the convergence between the Eurasian and Arabian Plates which resulted in the Zagros orogeny has significantly influenced the burial and thermal evolution of the region. Burial depths are greatest in the study area in the Binak Trough and Northern Depression. These depocentres host the main kitchen areas for hydrocarbon generation, and the organic‐rich Neocomian and Albian source rock successions have been buried sufficiently deeply to be thermally mature. Early oil window maturities for these successions were reached between the Late Cretaceous (90 Ma) and the early Miocene (18 Ma) at different locations, and hydrocarbon generation may continue at the present‐day.

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Burial and thermal maturity modeling of the Middle Cretaceous–Early Miocene petroleum system, Iranian sector of the Persian Gulf

Cited by 23 publications

References 34 publications

Prediction of vitrinite reflectance values using machine learning techniques: a new approach

Prediction of vitrinite reflectance values using machine learning techniques: a new approach

Hydrocarbon source rock potential evaluation of the Late Paleocene Patala Formation, Salt Range, Pakistan: Organic geochemical and palynofacies approach

Burial, Temperature and Maturation History of Cretaceous Source Rocks in the Nw Persian Gulf, Offshore Sw Iran: 3d Basin Modelling

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