Direct Observation of Asphaltene Nanoparticles on Model Mineral Substrates

Raj, Gijo; Lesimple, Alain; Whelan, Jamie; Naumov, Panče

doi:10.1021/acs.langmuir.7b00866

Cited by 21 publications

(34 citation statements)

References 70 publications

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“…Adsorption from asphaltene solutions normally gives complete surface coverage by a film of material, but two approaches have been used to image individual nanoaggregates on surfaces. The first approach is to expose the solid substrate to a dilute solution of asphaltenes in toluene, then rinse and dry the sample for imaging. , The second is to expose the substrate to a crude oil, then remove residual liquid portions of the adsorbed asphaltene film by washing with toluene . Deposition from dilute solutions onto mica gave aggregates of height from 1.1 to 4.4 nm depending on the source crude oil, with average lateral dimensions of 16–41 nm.…”

Section: Insights From Surface Properties Of Nanoaggregatesmentioning

confidence: 99%

Distributed Properties of Asphaltene Nanoaggregates in Crude Oils: A Review

et al. 2021

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The molecules in petroleum asphaltenes follow a molecular structure continuum similar to the rest of the oil but differ in the formation of nanoaggregates in solution. The nature of the aggregation, its size distribution, and dimensions of the nanoaggregates is still debated, and the impact of this aggregation on phase behavior, physical properties, and the processing of heavy petroleum fractions remains unclear. This review first discusses the role of nanoaggregates in the phase separation of asphaltenes, then examines the literature on subfractionation of the asphaltene fraction to define how different molecules partition. Efforts to measure the distribution of nanoaggregate size are summarized, and the roles of size distribution in the behavior of asphaltenes during sedimentation, emulsion formation, and refinery processing are examined. Finally, the molecular basis for formation of a distribution of aggregate sizes/properties is considered. The molecular weight ranges as high as 40,000 Da but the size is below 100 nm. Although few direct experimental data are available for the distribution of aggregate properties, three behaviors indicate the importance of portions of the nanoaggregate population. The highest molecular weight aggregates are the least soluble, driving phase behavior when the asphaltenes are partially precipitated. A portion of these large aggregates are also most responsible for the stabilization of asphaltene films at oil–water interfaces, which stabilize oil-in-water emulsions. The vanadium and nickel species that are most resistant to removal during refining of vacuum residues are also found in the most aggregated fraction, although the stability of the aggregates at process temperatures is not yet proven. Average properties for the asphaltene fraction, including both free molecules and nanoaggregates, are sufficient for prediction of onset of asphaltene phase separation, gravity segregation, and properties such as density and viscosity.

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Section: Insights From Surface Properties Of Nanoaggregatesmentioning

confidence: 99%

Distributed Properties of Asphaltene Nanoaggregates in Crude Oils: A Review

et al. 2021

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“…At the nanoscale level, atomic force microscopy (AFM) is an interesting technique that offers access to three-dimensional information. For asphaltene characterization, AFM has been applied from single asphaltene molecule imaging (Schuler et al) , to observation of asphaltene aggregates in different media/support. − Therefore, AFM is a technique of choice for observation and comparison of the type and form of macroaggregates deposited on metal surfaces or sensors.…”

Section: Introductionmentioning

confidence: 99%

Understanding Asphaltene Fraction Behavior through Combined Quartz Crystal Resonator Sensor, FT-ICR MS, GPC ICP HR-MS, and AFM Characterization. Part I: Extrography Fractionations

et al. 2020

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Multiscale characterization of asphaltenes and their extrography fractions titrated with n-heptane was performed. Chemical characterization via FT-ICR MS and GPC ICP HR-MS, stability monitoring via QCR, and AFM images of deposits indicate that "island"-enriched samples tend to form fewer, well-organized deposit aggregates, whereas samples with abundant "archipelago"-like molecules produce larger aggregates and less well-organized deposits. The combination of QCR and AFM leads to the conclusion that "island"-enriched samples lead to smaller deposits compared to "archipelago"-like molecules.

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“…The attening of nanoparticles can explain the decreased average height of the nanoparticles on HOPG because of the high a nity of the alkyl chains to HOPG. 23,24 Grazing-incidence wide-angle X-ray scattering (GIWAXS) was conducted on the drop-cast lms of DP Zn T. Thus, the in-plane and out-of-plane diffraction of DP Zn T overlapped well (Fig. 2D), indicating the absence of angular dependency in the wide-angle region owing to the formation of spherical nanoparticles.…”

Section: Spherical Nanoparticle Formation Of Dp Zn Tmentioning

confidence: 95%

Porphyrin tripod as a monomeric building block for guest-induced reversible supramolecular polymerisation

Lee

Hwang

Lee

et al. 2022

Preprint

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Reversible supramolecular polymerisation and depolymerisation of biomacromolecules are common and fundamental phenomena in biological systems, which can be controlled by the selective modification of biomacromolecules through molecular recognition. Herein, a porphyrin tripod (DPZnT) connected through a triazole bridge was prepared as a monomeric building block for guest-induced supramolecular polymerisation. Although the lone pair electrons in triazolic nitrogen potentially bind to the zinc porphyrin units through axial ligation, the intrinsic steric hindrance suppressed the coordination of the triazole bridge to the porphyrin unit in DPZnT. Therefore, DPZnT formed spherical nanoparticles through π-π interactions. The addition of 1,3,5-tris(pyridine-4-yl)benzene (Py3B) caused the guest-induced fibrous supramolecular polymerisation of DPZnT by forming a 1:1 host-guest complex, which was further assembled into a fibrous polymer. Furthermore, addition of Cl− to DPZnT induced the transformation of spherical nanoparticles to fibrous supramolecular polymers. The fibrous supramolecular polymers of DPZnT obtained by adding Py3B or Cl− were depolymerised to their original spherical particles after adding Cu(ClO4)2 or AgNO3, respectively.

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Direct Observation of Asphaltene Nanoparticles on Model Mineral Substrates

Cited by 21 publications

References 70 publications

Distributed Properties of Asphaltene Nanoaggregates in Crude Oils: A Review

Distributed Properties of Asphaltene Nanoaggregates in Crude Oils: A Review

Understanding Asphaltene Fraction Behavior through Combined Quartz Crystal Resonator Sensor, FT-ICR MS, GPC ICP HR-MS, and AFM Characterization. Part I: Extrography Fractionations

Porphyrin tripod as a monomeric building block for guest-induced reversible supramolecular polymerisation

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