Toward Separation and Characterization of Asphaltene Acid and Base Fractions

Gharbi, Kheira; Benamara, Chahrazed; Benyounes, Khaled; Kelland, Malcolm A.

doi:10.1021/acs.energyfuels.1c01999

Cited by 12 publications

(9 citation statements)

References 34 publications

(62 reference statements)

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“…Analogous to other crude oil fractions such as saturates or asphaltenes, the definition of NAs does not derive from the molecular standpoint. Commonly, naphthenic acids constitute part of the resin fractions in crude oils; however, certain acidic functionalities occur in asphaltene molecules. ,, For this reason, the behavior of acids at the water–oil interface originates from the contribution of different species with the carboxyl group in their structure. Figure shows a representation of the 5-β-cholanic acid, which is a NA model molecule commonly employed in experimental studies. ,, …”

Section: Water-in-crude Oil Emulsionsmentioning

confidence: 99%

Outlook on the Role of Natural Surfactants on Emulsion Stability and Gas Hydrate Antiagglomeration in Crude Oil Systems

et al. 2022

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Gas hydrates constitute a major flow assurance issue in the transportation of oil and gas from the reservoir to the point of sale via pipelines. They can reduce or arrest the hydrocarbon production in a short period of time. Gas hydrate mitigation strategies involve the application of surfactant-like molecules able to prevent the agglomeration of hydrate particles and thus reducing their tendency to plug the flowlines. Some crude oils, commonly referred to as nonplugging oils, show a natural hydrate antiagglomerant tendency. This property has been related to crude fractions, such as asphaltenes and acids that naturally behave as surfactants. Given that these natural surfactants play a key role in the stabilization of water-in-crude oil emulsions, it has been practically unavoidable to consider hydrate antiagglomeration as a phenomenon linked to the stability of crude oil emulsions. Although hydrate natural antiagglomeration is a result of complex mechanisms involving crude oil composition, physicochemical conditions of the system, and fluid dynamics, the concentration and interfacial activity of natural surfactants are paramount in understanding the whole antiagglomeration process.

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Section: Water-in-crude Oil Emulsionsmentioning

confidence: 99%

Outlook on the Role of Natural Surfactants on Emulsion Stability and Gas Hydrate Antiagglomeration in Crude Oil Systems

et al. 2022

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“…Kelland et al developed a methodology for the fractionation of asphaltenes into their acidic, basic, and neutral components, applying the modified Ramljack method. 18 The results revealed that the composition of the acid fraction includes carboxylic acids, phenols, sulfoxide groups, and aliphatic groups, while the structure of the basic fraction contains amines and derivatives. Other authors have proposed alternative methodologies showing outstanding results but requiring the use of complex materials not commercially available, which disfavors the reproducibility of the results.…”

Section: Introductionmentioning

confidence: 97%

“…17 From elsewhere, according to the work of Siffert et al, there is a relationship between the flocculation of asphaltenes in a system of organic compounds and the surface electrical charge. 1 It implies that the distribution of all functional groups can be key in understanding the aggregation of asphaltenes from the perspective of electric charge, 18 considering that the net charge of an aggregate corresponds to the sum of charges provided by each functional group present in the molecules that make it up. For example, it can be generally stated that negatively charged asphaltenes tend to be dispersed by cationic amphiphiles, while positively charged amphiphiles tend to be dispersed by anionic amphiphiles.…”

Section: Introductionmentioning

confidence: 99%

Characterization of Acid Species in Asphaltenic Fractions by Fourier Transform Ion Cyclotron Resonance Mass Spectrometry and Infrared Spectroscopy

et al. 2022

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Despite significant advances in the characterization of asphaltenes, the study of this fraction of crude oil remains challenging for the scientific community and oil companies. It is well-known that asphaltenes are responsible for many of the difficulties found in the extraction, production, transportation, storage, and refining of petroleum. Although they are defined as the fraction of crude oil that is insoluble in paraffinic solvents of low-molecular-weight-type nheptane (C 7 ) or n-pentane (C 5 ), asphaltenes present a great compositional variety, concentrate a variety of elements (among which nitrogen, oxygen, sulfur, vanadium, and nickel stand out), apart from hydrogen and carbon, and are distinguished by grouping the molecules with greater aromaticity of crude oil. Given its high compositional and structural complexity, associating operational problems with specific characteristics of asphaltenes is a task that is still in force. Asphaltenes, in addition to being distinguished by their high aromaticity, are also known for their acid−base properties. The acid character varies according to the origin of the asphaltenes and is related to the presence of carboxylic acids, phenols, carbazoles, and indoles. The basic character can be attributed to the presence of amines, amides, and other nitrogen-containing compounds. Progressing in the detailed compositional characterization of the polar compounds comprising the n-heptane-insoluble fraction (asphaltenes) is still a necessary task toward the understanding of asphaltene aggregation phenomena and the relationship with crude oil properties, such as interfacial tension and viscosity. In the present work, the naphthenic acids of the insoluble fractions of five Colombian crude oils were characterized. The n-heptane-insoluble fraction was subjected to a washing process affording four subfractions, named as extractable 48 h, extractable 72 h, and extractable 96 h, which correspond to the heptane-soluble fractions that were recovered after each indicated time, and asphaltene 96 h, which corresponds to the remaining heptane-insoluble compounds after 96 h of washing. The samples were chosen so that they had a wide range of asphaltene content that varied from 3.0 to 19.2%. The acid fraction was obtained from each sample by solid-phase extraction using aminopropyl silica as an adsorbent material.

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“…However, the size of the aromatic core, the presence of heteroatoms on the core and the lateral chains as well as the length of the lateral chains must all be considered when choosing which model to use to depict the system. Although there is not a single, dominating form of asphaltene in all crude oil, it has been seen to contain both acid and base fractions, including phenols, carboxylic acids, sulfoxide groups, and aliphatic chains …”

Section: Introductionmentioning

confidence: 99%

“…Although there is not a single, dominating form of asphaltene in all crude oil, it has been seen to contain both acid and base fractions, including phenols, carboxylic acids, sulfoxide groups, and aliphatic chains. 16 The problem of asphaltene precipitation 17,18,27,28,19−26 and deposition 29−38 is well researched in the literature, with several control strategies such as mechanical and chemical options explored. The mechanical solutions involve the use of scrapers and pigs to remove the asphaltene deposit; 39−41 whereas, the chemical asphaltene control strategy involves the injection of fluids that have the propensity to interact with the asphaltene molecule, resulting in their increased solubility (dispersants) or prevention of its precipitation (inhibitors).…”

Section: ■ Introductionmentioning

confidence: 99%

Effect of Reservoir Mineralogy on Asphaltene Structure and Remediation Strategy Efficiency

et al. 2022

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For many years, formation damage caused by asphaltene precipitation and deposition has been an issue. The most detrimental impacts are changes to wettability, permeability, and flow area, which ultimately reduce production. To this end, several remediation methods, with considerable economic ramifications, have been adopted, including mechanical removal of the deposits or injection of chemicals to dissolve the deposits. Due to its advantages over mechanical procedures, chemical injection has been used extensively in the industry to remove asphaltene deposits; nonetheless, this method does not completely remove all the deposits. Xylene and petroleum naphtha are two of the most effective fluids used for asphaltene deposit remediation, with their effectiveness based on how aromatic the asphaltene deposit is. Considering this, the effectiveness of remedial activities will be impacted by changes in the aromaticity or structural characteristics of asphaltene. Therefore, the purpose of this study is to determine how reservoir rock mineralogy affects the structural characteristics of asphaltene molecules and how those characteristics affect remediation efforts. X-ray diffraction, Fourier-transform infrared spectroscopy, Rock-Eval analysis, Raman spectroscopy, and elemental analysis were used in this investigation to analyze the asphaltene samples. Furthermore, the effectiveness of xylene as an asphaltene remediation fluid was examined. The results show that the asphaltene samples from the Arab light, medium, and heavy crude oil samples are roughly the same in terms of composition but vary by structural makeup. Furthermore, the asphaltene samples from these crude oils lack the carboxylic functional group that gives most carbonate rocks their oil wetness, leading to intermediate wetness in the analyzed situations. Additionally, rock mineralogy has an impact on the structural characteristics of asphaltene, which in turn impacts how well remediation fluids work to clear up asphaltene deposits.

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Toward Separation and Characterization of Asphaltene Acid and Base Fractions

Cited by 12 publications

References 34 publications

Outlook on the Role of Natural Surfactants on Emulsion Stability and Gas Hydrate Antiagglomeration in Crude Oil Systems

Outlook on the Role of Natural Surfactants on Emulsion Stability and Gas Hydrate Antiagglomeration in Crude Oil Systems

Characterization of Acid Species in Asphaltenic Fractions by Fourier Transform Ion Cyclotron Resonance Mass Spectrometry and Infrared Spectroscopy

Effect of Reservoir Mineralogy on Asphaltene Structure and Remediation Strategy Efficiency

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