Reservoir Fluid Geodynamics: The Chemistry and Physics of Oilfield Reservoir Fluids after Trap Filling

Mullins, Oliver C.; Zuo, Julian Y.; Pomerantz, Andrew E.; Forsythe, Jerimiah C.; Peters, Kenneth E.

doi:10.1021/acs.energyfuels.7b02945

Cited by 23 publications

(22 citation statements)

References 115 publications

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“…Key issues that have been addressed include reservoir connectivity , and its inverse compartmentalization, , baffling, , viscous oil and tar mat formation, , upstructure mobile tar, aquifer support, asphaltene onset pressure, , wax precipitation, solution gas gradients, timing of charge, fault block migration, , biogenic gas charge into oil, and spill–fill trap filling, , along with traditional geochemical concerns of biodegradation, ,, gas washing, and water washing. ,, These wide-ranging concerns treated in various RFG oilfield studies establish that the development and application of asphaltene thermodynamics extends far beyond issues that are directly impacted by asphaltenes, such as tar mat formation. Instead, RFG exploits thermodynamics, which itself is unlimited in its applications. ,,,− …”

Section: Reservoir Fluid Geodynamics (Rfg)mentioning

confidence: 99%

Overview of Asphaltene Nanostructures and Thermodynamic Applications

et al. 2020

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Previously, asphaltene science had been hindered by many significant uncertainties regarding molecular weight, molecular structure, and nanocolloidal characteristics in laboratory solvents and crude oils. These debates were of sufficient magnitude to forestall development and utility of asphaltene modeling for various applications. In the last 2 decades, advances in asphaltene science using many sophisticated techniques have greatly reduced corresponding uncertainties, enabling development of simple asphaltene models for a variety of applications. Here, we provide an overview of key findings in asphaltene science; dominant molecular and nanocolloidal structures are described. These structures with simple thermodynamic formalisms are shown to work well in oilfield reservoirs, specifically including light oils, black oils, and heavy oils. This novel thermodynamic approach using asphaltene nanostructures has enabled characterization of different processes that impact or preclude equilibration of reservoir fluids in geologic time. These processes combine to form the new technical discipline, "reservoir fluid geodynamics", that has proven value in many reservoir studies. In addition, these asphaltene nanostructures are shown to apply to interfacial tension of asphaltene solutions, using simple thermodynamics for surfaces. In addition, we contrast past and current debates in asphaltene science, especially regarding asphaltene molecular architecture, which has been largely resolved. Molecular structural characterization of asphaltenes reviewed herein shows that asphaltenes are dominated by island structures, but some asphaltenes also have a secondary content of structures with an "aryl-linked core", which we propose as a third class of molecular architecture along with island and archipelago designations. The aryl-linked core structure is defined as having a single, contiguous sp 2 -hybridized carbon network containing one or more aryl linkages, in which adjacent aromatic rings are directly bonded together but do not share a common bond in a ring. In contrast, a traditional island structure also has a single, contiguous sp 2 -hybridized carbon network but has adjacent aromatic rings exclusively fused (sharing a common bond in a ring) with no aryl linkages. The definition of archipelago remains unchanged and consists of multiple, discontinuous sp 2 -hybridized carbon networks, in which these different aromatic ring systems are connected by one or more sp 3 -hybridized carbons. This new classification, "aryl-linked core", has been assigned to both island and archipelago structures in different publications; thus, this new designation should reduce confusion and help resolve structure− function relations, especially regarding aggregation and reactivity. More broadly, the advances in asphaltene science have ushered in powerful, new applications that are continuing to expand.

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Section: Reservoir Fluid Geodynamics (Rfg)mentioning

confidence: 99%

Overview of Asphaltene Nanostructures and Thermodynamic Applications

et al. 2020

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“…An industry-wide study of 28 deepwater Gulf of Mexico reservoirs showed that 75% of the reservoirs underperformed in production rate or total recovery primarily as a result of unrecognized compartmentalization . Many reservoir studies have confirmed that if the reservoir crude oils are in thermodynamic equilibrium, then the reservoir is connected; it takes massive fluid compositional redistribution to equilibrate reservoir fluids, thus requiring connectivity. ,− In contrast, pressure equilibration among different compartments requires only small mass transport and does not require excellent connectivity in reservoirs. − Pressure communication is a necessary but insufficient condition to establish flow communication in reservoirs.…”

Section: Introductionmentioning

confidence: 99%

“…Asphaltene gradients are the most recent reservoir fluid property to be addressed by a proper thermodynamic treatment, − and they provide the most stringent test of thermodynamic equilibrium. ,− Asphaltene gradients can be measured accurately, especially through the use of in situ fluid measurements in oil wells, referred to as “downhole fluid analysis” (DFA) in oilfield well logging . The latest generation of well logging tools that performs DFA can measure fluid gradients accurately and efficiently .…”

Section: Introductionmentioning

confidence: 99%

“…As noted, compositionally equilibrated reservoir fluids imply reservoir connectivity. If reservoir fluids are not equilibrated in a connected reservoir, then frequently a fluid process can be identified in recent geologic time that precludes equilibrium. ,,,− The collection of the fluid processes in geologic time constitute the newly codified technical discipline “reservoir fluid geodynamics” (RFG) (Figure ). …”

Section: Introductionmentioning

confidence: 99%

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Yen–Mullins Model Applies to Oilfield Reservoirs

Chen¹,

Bertolini²,

Dubost³

et al. 2020

Energy Fuels

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Fluid distributions throughout oilfield reservoirs have been measured with increasing accuracy and coverage, both vertical and laterally, in recent years. Currently, a routine observation is that, when reservoir crude oils are in thermodynamic equilibrium, then the reservoir is a single flow unit with fluid flow communication, addressing the most important oil production risk associated with reservoir structure. The most accurate method of determining fluid equilibration is by measurement and analysis of the distribution of dissolved (or suspended) asphaltenes in the oil. This analysis employs the Flory–Huggins–Zuo equation of state (EoS) with its reliance on the Yen–Mullins model of asphaltene nanostructures. This capability has enabled the introduction of a new technical discipline, reservoir fluid geodynamics, which provides a significant advance in the understanding of oilfield reservoirs. Other reservoir fluid components are also measured to assess equilibration of reservoir fluids, including dissolved gas, liquid-phase components, various biomarkers, and methane isotopic ratios. Often, there is a single species of asphaltenes in the reservoir in accordance with the Yen–Mullins model (molecules, nanoaggregates, and clusters). However, for some reservoirs, two species of asphaltenes are evident. These reservoirs provide a stringent test to (1) discern nanostructures of asphaltenes and (2) determine whether there are other prominent aggregate species of asphaltenes in addition to those indicated in the Yen–Mullins model. This paper explores five reservoirs: three of these reservoirs exhibit one dominant species; two exhibit two species of the Yen–Mullins model; and none of the reservoirs exhibits additional species, providing validation of asphaltene nanostructures in the Yen–Mullins model and its application with the Flory–Huggins–Zuo EoS for novel characterization of reservoirs.

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“…Несмотря на широкое использование высокотехнологичных геофизических методов разведки и современных вычислительных технологий для обработки полученной информации, геологическое строение введенных в эксплуатацию нефтяных месторождений уточняют на основе полученных данных о материальном составе извлекаемых пластовых флюидов [1,2]. Особый интерес проблема детализации геологического строения представляет для эксплуа-тируемых многопластовых месторождений, когда в результате применения интенсивных технологий повышения нефтеизвлечения возможно появление неконтролируемых межпластовых перетоков.…”

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Clarifying of the Geological Structure of the Operated Oil Deposit on the Composition of Oil Removed From Various Wells

Turov¹,

Guznyaeva²

2020

УСЕ (ACNR)

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Для уточнения геологического строения и режимов питания продуктивных скважин эксплуатируемого нефтяного месторождения исследован состав извлекаемой нефти и его вариации для трех скважин многопластового месторождения. Показано, что за период наблюдения (три пробоотбора в течение 6 месяцев) заметных изменений состава извлекаемой из наблюдаемых скважин нефти не произошло. Оценена суммарная погрешность (воспроизводимость) результатов анализа состава, которая не превышала ± 6 % отн. С учетом этой погрешности установлено, что по результатам анализа изомерного состава парафинов, нафталинов, фенантренов и дибензотиофенов и на основе сопоставления рассчитанных по изомерному составу геохимических параметров надежно определяются источники образцов нефти. Практически идентичный состав и совпадение значений геохимических параметров образцов нефти из двух скважин (расхождения их не превышают 3 % для парафиновых и 4 % для нафталиновых и фенантреновых индексов) рассматривается как доказательство работы этих скважин на один общий продуктивный пласт. Существенные отличия всех этих характеристик для образцов нефти из третьей скважины (различия достигают 35 % для парафиновых, 28 % для нафталиновых и 37 % для фенантреновых параметров) объясняются тем, что эта скважина извлекает нефть из другого нефтеносного пласта. Полученная информация дает возможность уточнить геологическое строение эксплуатируемого месторождения, оптимизировать режимы работы добывающих скважин, сформулировать научно обоснованные рекомендации по применению технологий повышения нефтеотдачи и оценить эффективность их применения. В случае неудачных операций при использовании технологий гидроразрыва пласта применение изложенной в работе методики идентификации источников извлекаемой нефти по ее составу позволит обнаруживать возникающие межпластовые перетоки флюидов. Ключевые слова: геологическое строение нефтяных месторождений, состав извлекаемой нефти, геохимические параметрыTo clarify the geological structure and feeding regimes of productive wells of an exploited oil field the composition of the recoverable oil and its variations for three wells of a multilayer field were studied. It was shown that during the observation period (three sampling within 6 months), no composition changes in recovered oil occurred. The total error (reproducibility) of the composition analysis results did not exceed ± 6 % rel. It was found that based on the isomeric composition of paraffins, naphthalenes, phenanthrenes and dibenzothiophenes and on the comparison of geochemical parameters calculated from the isomeric composition, the sources of oil samples are correctly identified. Practically identical composition and concurrence of the geochemical parameters values of oil samples from two wells (their differences do not exceed 3 % for paraffin and 4 % for naphthalene and phenanthrene indices) is considered as evidence of the operation of these wells on the same reservoir. The significant differences of all these characteristics for oil samples from the third well (differences reach 35 % f...

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Reservoir Fluid Geodynamics: The Chemistry and Physics of Oilfield Reservoir Fluids after Trap Filling

Cited by 23 publications

References 115 publications

Overview of Asphaltene Nanostructures and Thermodynamic Applications

Overview of Asphaltene Nanostructures and Thermodynamic Applications

Yen–Mullins Model Applies to Oilfield Reservoirs

Clarifying of the Geological Structure of the Operated Oil Deposit on the Composition of Oil Removed From Various Wells

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