<sup>1</sup>H <scp>NMR</scp> application in characterizing the refinery products of gasoline

Sun, Cheng; Wang, Zhixiao

doi:10.1002/cmr.a.21393

Cited by 14 publications

(10 citation statements)

References 11 publications

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“…The vinyl hydrogens signals were assigned as d 5.1-4.8 and 6.5-5.9 for monosubstituted (RHC=CHH, RHC=CHH, respectively); These assignments agree with Burri et al, 32 Meusinger, 30 and Sun and Wang. 40 The signal areas of the aliphatic (d 1.8-0.4) and aromatic (d 8.0-6.5) hydrogens from CG, PG and M 1,5,9 samples (Figure 3), supported the proportions between AKI, aromatic and saturated contents, previously determined by IR analyses (Figure 1).…”

Section: Samplesupporting

confidence: 83%

“…This fact is related to the overlapping of hydrogen signals from aliphatic hydrocarbon and −CH, −CH 2 and −CH 3 groups in β and γ positions of aromatic rings observed at d 1.8-0.4. 40 Therefore, the PG increasing content in blends (M 1 to M 9 ) results both to the decrease in the signal areas of hydrogens β and γ from aromatics, as well as the concomitant increasing in the signal areas for aliphatic hydrocarbon hydrogens. In order to reinforce these observations, PCA analyses of NMR data from CG, PG and M 1-9 samples were performed.…”

Section: Samplementioning

confidence: 95%

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1H NMR and Chemometric Methods to Estimate the Octane Number in Brazilian C Gasolines

Pinto¹,

Gambarra-Neto²,

Flores³

et al. 2020

J. Braz. Chem. Soc.

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Brazilian gasoline type C can be purchased with octane number as the main difference. This quality parameter directly affects the price. Intermediate formulations may not be easily distinguished from conform samples due to similarity in visual appearance and physicochemical properties. The use of anhydrous ethanol as an additive also influences the octane values of the product. In this context, the present study describes the use of 1 H nuclear magnetic resonance spectroscopy (1 H NMR) associated with chemometrics in the characterization and distinction of gasolines by different octane number. Conform samples of common, premium and blends of common-premium were used. Models of NMR-PCA (principal component analysis) and NMR-SIMCA (soft independent modelling of class analogies) showed a good correlation with the values determined by the standard method. The octane values predicted by the NMR-PLS (partial least squares) model achieved a good correlation root mean square errors of prediction (RMSEP = 0.50), with the values determined by the standard method as well.

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Section: Samplesupporting

confidence: 83%

Section: Samplementioning

confidence: 95%

1H NMR and Chemometric Methods to Estimate the Octane Number in Brazilian C Gasolines

Pinto¹,

Gambarra-Neto²,

Flores³

et al. 2020

J. Braz. Chem. Soc.

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“…Hydrocarbon type analysis of refinery naphtha stream or gasoline samples has been well studied by various analytical techniques, such as nuclear magnetic resonance (NMR), − gas chromatography (GC), , and high-performance liquid chromatography (HPLC). − Moreover, several ASTM methods based on the GC technique cover various gasoline range samples for hydrocarbon type estimation. For example, a GC-based detailed hydrocarbon analyzer (DHA) [ASTM D6730-01(2016)] where the olefin content in mass %age can be estimated up to 30% olefin and reformulyzer [ASTM D6839-18] where the PIONA can be estimated by both volume and mass %ages have been well used in laboratories.…”

Section: Introductionmentioning

confidence: 99%

A Rapid ¹H NMR-Based Estimation of PONA for Light and Narrow Cut Naphtha Samples of Refinery Streams toward BS-VI Gasoline

et al. 2021

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A rapid method based on quantitative 1 H NMR spectroscopy for the accurate estimation of paraffins (P), olefins (O), naphthenes (N), and aromatics (A), i.e., PONA, in extremely light to middle cut naphtha (boiling points ranging from C4/C5 to 130/140 °C and various heart cuts in-between, like C5-60, 60-70, 70-90, 90-140 °C cuts and many more that are being processed for BS-VI gasoline pool) has been developed. The method relies on accurate assignments of various kinds of quaternary-carbons, CHs, CH 2 s, and CH 3 s present in these light samples overwhelmingly populated with low-molecular-weight alkanes-alkenes, isoalkanesisoalkenes, and cycloalkanes-cycloalkenes as the constituents by edited HSQC NMR. Our earlier group molecular weight (GMWt)-based methods for PNA estimation has thus been appropriately modified in terms of assignment of 1 H NMR spectrum to CH n (n = 0, 1, 2, and 3) groups toward estimation of the relative number of carbon and hydrogen atoms, which are imperative to the GMWt-based method, to accommodate all possible variations. The GMWt method coupled with our recently developed multiplication factor-based olefin estimation wholly estimate the PONA for these lightest liquid streams from refineries. The developed method is well suited for monitoring pilot plant processes where high sample throughput and instant results are warranted. The values thus obtained were compared with detailed hydrocarbon analysis (DHA) following ASTM D6730 and by the reformulyzer-based ASTM D6839 method.

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“…There are numerous investigations reporting the successful application of both technologies in predicting some physical–chemical properties of gasoline. Among the most recent studies, it is possible to find applications of portable spectrometers or novel chemometric approaches that reportedly give more accurate predictions than the most established ones. − However, few studies have been published on the comparison of the 1 H NMR spectroscopy and NIR vibrational spectroscopy as potential techniques for properties estimation in the petrochemical industry, − and none of them includes the simultaneous estimation of the amount of gasoline physical–chemical properties analyzed in this work. In the current study we aim at comparing the performance of multivariate regression models developed using either NIR or 1 H NMR spectral data to predict 13 different gasoline parameters.…”

Section: Introductionmentioning

confidence: 99%

Using Spectroscopy and Support Vector Regression to Predict Gasoline Characteristics: A Comparison of¹H NMR and NIR

Leal

Silva

Ribeiro³

et al. 2020

Energy Fuels

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The applicability of two alternative spectroscopic techniques (i.e., 1 H NMR and NIR) for the quantitative characterization of gasoline was compared in this work. The chemometric approach followed to build the regression models was support vector regression, and two distinct kernel functions were tested: Gaussian and linear. Additionally, a significance test was performed on test set predictions to determine if the difference between the estimations of 1 H NMR and NIR-based models is statistically significant. According to the performance indexes of the developed models, NIR spectroscopy is preferable over 1 H NMR for the prediction of most gasoline physical−chemical properties. Still, for most of the cases, it was also demonstrated that the estimations resulting from both spectroscopic techniques are not significantly different from each other. The accuracy level attained with the support vector regression models is adequate and enables the replacement of the standard methods of analysis for at least 10 different gasoline quality parameters.

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¹H NMR application in characterizing the refinery products of gasoline

Cited by 14 publications

References 11 publications

1H NMR and Chemometric Methods to Estimate the Octane Number in Brazilian C Gasolines

1H NMR and Chemometric Methods to Estimate the Octane Number in Brazilian C Gasolines

A Rapid ¹H NMR-Based Estimation of PONA for Light and Narrow Cut Naphtha Samples of Refinery Streams toward BS-VI Gasoline

Using Spectroscopy and Support Vector Regression to Predict Gasoline Characteristics: A Comparison of¹H NMR and NIR

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1H NMR application in characterizing the refinery products of gasoline

Cited by 14 publications

References 11 publications

1H NMR and Chemometric Methods to Estimate the Octane Number in Brazilian C Gasolines

1H NMR and Chemometric Methods to Estimate the Octane Number in Brazilian C Gasolines

A Rapid 1H NMR-Based Estimation of PONA for Light and Narrow Cut Naphtha Samples of Refinery Streams toward BS-VI Gasoline

Using Spectroscopy and Support Vector Regression to Predict Gasoline Characteristics: A Comparison of1H NMR and NIR

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Product

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About

¹H NMR application in characterizing the refinery products of gasoline

A Rapid ¹H NMR-Based Estimation of PONA for Light and Narrow Cut Naphtha Samples of Refinery Streams toward BS-VI Gasoline

Using Spectroscopy and Support Vector Regression to Predict Gasoline Characteristics: A Comparison of¹H NMR and NIR