A New Extended Structural Parameter Set for Stochastic Molecular Reconstruction: Application to Asphaltenes

Deniz, Celal Utku; Yaşar, Muzaffer; Klein, Michael T.

doi:10.1021/acs.energyfuels.7b01006

Cited by 12 publications

(23 citation statements)

References 54 publications

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“…Important structural attributes including the number of aromatic rings, naphthenic rings and different lengths of aliphatic chains were adjusted according to their quantitative probability Recently, the method was further refined and applied to Turkish asphaltenes. 68 A pair of the generated molecules is shown in Figure 16. Figure 16.…”

Section: Quantitative Molecular Representation (Qmr) Previous Deploymmentioning

confidence: 99%

“…Figure 16. Island (left) and archipelago (right) models of asphaltenes generated by stochastic molecular reconstruction proposed by structure generated through stochastic assembly proposed by Denitz et al 68 Sheremata et al 36 further developed the QMR generation model to incorporate structural data from 13 C NMR spectroscopy, a distribution of molecular building blocks following the archipelago-type structural framework, as well as both thioether and alkyl bridges. The authors reported a series of QMR-generated archipelago-type asphaltenes: C 283 H 337 N 3 O 4 S 9 , C 230 H 302 N 4 O 2 S 10 and C 318 H 395 N 6 O 6 S 8 V, with molecular weights of 4133 Da, 3476 Da and 4705 Da, respectively, of which the final molecule is shown in Figure 17.…”

Section: Quantitative Molecular Representation (Qmr) Previous Deploymmentioning

confidence: 99%

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Catalogue of Plausible Molecular Models for the Molecular Dynamics of Asphaltenes and Resins Obtained from Quantitative Molecular Representation

et al. 2019

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Computer simulation studies aimed at elucidating the phase behavior of crude oils inevitably require atomistically-detailed models of representative molecules. For the lighter fractions of crudes, such molecules are readily available, as the chemical composition can be resolved experimentally. Heavier fractions pose a challenge, on one hand due to their polydispersity and on the other due to poor description of the morphology of the molecules involved. The Quantitative Molecular Representation (QMR) approach is used here to generate a catalogue of 100 plausible asphaltene and resin structures based on elemental analysis and 1 H-13 C NMR spectroscopy experimental data. The computer-generated models are compared in the context of a review of previously proposed literature structures and categorized by employing their molecular weights, double bond equivalents (DBE) and hydrogen to carbon (H/C) ratios. Sample atomistic molecular dynamics simulations were carried out for two of the proposed asphaltene structures with contrasting morphologies, one island-type and one archipelago-type, at 7 wt% in either toluene or heptane. Both asphaltene models, which shared many characteristics in terms of average molecular weight, chemical composition and solubility parameters showed marked differences in their aggregation behavior. The example showcases the importance of considering diversity and polydispersity when considering molecular models of heavy fractions.

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Section: Quantitative Molecular Representation (Qmr) Previous Deploymmentioning

confidence: 99%

Section: Quantitative Molecular Representation (Qmr) Previous Deploymmentioning

confidence: 99%

Catalogue of Plausible Molecular Models for the Molecular Dynamics of Asphaltenes and Resins Obtained from Quantitative Molecular Representation

et al. 2019

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“…Many structures in the literature (Figure ) can be classified as physical or chemical models. , For example, the asphaltene model proposed by Yen in 1961 is a physical model which was mainly derived from assumptions on rods, disks, and dots and physical principles of diffraction. , Many other structures can be considered as chemical models, including the average structures derived from NMR, MS, or elemental compositions. − Those deduced average structures from analyses should also be confirmed by comparing them with mixtures of known structures at known concentrations. Although these averaged or representative structures are convenient representations of the sample, they are limited by the lack of the full diversity of individual molecules and their unique features. , It should be noted that some of these models also represent the organization of structures or architectures (aggregates or clusters), or incorporation of both chemical and physical elements, and hence it is important for the reader to consult the original references to understand what information each model represents …”

Section: Introductionmentioning

confidence: 99%

Applications of Noncontact Atomic Force Microscopy in Petroleum Characterization: Opportunities and Challenges

Zhang

2021

Energy Fuels

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Despite a tremendous amount of research, molecular characterization of petroleum remains a significant scientific challenge because petroleum is an exceptionally complex molecular mixture. This paper reviews recent advances in the application of noncontact atomic force microscopy (nc-AFM) to the petroleum field. The complexity of petroleum presents a number of experimental and computational challenges to achieve the full potential of this new technique. Initial results on categorizing structures as either alternant or nonalternant polycyclic aromatic hydrocarbons (PAHs), recognizing empirical structural patterns, quantifying the local aromaticity and bond orders, and computing the electronic structures will be presented. The effect of sample preparation in AFM and the influence of petroleum structural parameters on imaging results, such as molecular weight, thermal cracking of weak linkages, nonplanar geometries or conformations, the presence of heteroatoms, and trace amounts of free radicals will be discussed. This review also highlights the application of the AFM imaging technique, including recent results from characterizing molecules in petroleum pitch M-50. The observed predominant methyl substituents on M-50 pitch led to the design of dimethylpyrene, confirming the role of methyls in promoting molecular weight growth of aromatic hydrocarbons and revealing new insights into the polymerization mechanism. The knowledge of definitive petroleum structures may enable new reaction pathways and sustainable uses for petroleum molecules in applications such as carbon materials and infrastructures.

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“…This process is repeated N times to produce N molecules. The number of molecules ( N ) is determined by taking into account the stochastic structure of the algorithm (reproducibility) and efficient use of time. − When the molecule generation process is complete, mixing rules are applied to calculate the properties of the mixture. An objective function that compares these calculated values with analytical data is defined.…”

Section: Introductionmentioning

confidence: 99%

“…An objective function that compares these calculated values with analytical data is defined. This objective function is nondifferentiable due to the stochastic nature of the problem and is generally minimized via simulated annealing − and genetic algorithm methods. ,, Throughout the optimization process, the location and scale parameters of each structural identifier’s PDF are adjusted to form the most compatible set of molecules with analytical data.…”

Section: Introductionmentioning

confidence: 99%

Effect of Boiling Point and Density Prediction Methods on Stochastic Reconstruction

Deniz

Yaşar

et al. 2018

Energy Fuels

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Stochastic reconstruction (SR) methods are used to generate a series of molecules that mimic the properties of complex mixtures using partial analytical data. Determining a quantitative composition using these methods is limited by the property prediction methods used. This paper addresses the use of two key measurements in the characterization of petroleum fractions, namely density and boiling point distributions. It is known that the different methods used in estimating these two basic properties have varying error rates. Boiling point prediction performances of the various group contribution methods were tested via the molecular library established for molecules that can be found present in the petroleum fractions. It has been observed that the combined use of these methods results in close to a 50% reduction in sum of squared errors than any single method. The predictive performances of the density calculation methods were similarly tested. The best-calculated density results were found via the Yen–Woods method with support from the linear mixing rule based on molar fractions.

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A New Extended Structural Parameter Set for Stochastic Molecular Reconstruction: Application to Asphaltenes

Cited by 12 publications

References 54 publications

Catalogue of Plausible Molecular Models for the Molecular Dynamics of Asphaltenes and Resins Obtained from Quantitative Molecular Representation

Catalogue of Plausible Molecular Models for the Molecular Dynamics of Asphaltenes and Resins Obtained from Quantitative Molecular Representation

Applications of Noncontact Atomic Force Microscopy in Petroleum Characterization: Opportunities and Challenges

Effect of Boiling Point and Density Prediction Methods on Stochastic Reconstruction

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