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CT&F - Ciencia, Tecnología y Futuro

Print version ISSN 0122-5383

C.T.F Cienc. Tecnol. Futuro vol.5 no.4 Bucaramanga Jan./June 2014

 

1H- AND 13C-NMR STRUCTURAL CHARACTERIZATION OF ASPHALTENES FROM VACUUM RESIDUA MODIFIED BY THERMAL CRACKING

CARACTERIZACIÓN ESTRUCTURAL POR RMN-1H Y 13C DE ASFALTENOS DE RESIDUOS DE VACÍO MODIFICADOS POR RUPTURA TÉRMICA

Juan-Carlos Poveda*1, Daniel-Ricardo Molina1 and Edgar-Francisco Pantoja-Agreda2

1Universidad Industrial de Santander, Bucaramanga, Santander, Colombia
2Corporación para la Investigación de la Corrosión, Piedecuesta, Santander, Colombia

e-mail: jcpoveda@uis.edu.co

How to cite: Poveda, J. C., Molina, D. R. & Pantoja-Agreda, E. F. (2014). 1H- and 13C-NMR structural characterization of asphaltenes from vacuum residua modified by thermal cracking. CT&F - Ciencia, Tecnología y Futuro, 5(4), 49-60.

(Received: Jan. 08, 2014; Accepted: Jun. 17, 2014)

*To whom correspondence should be addressed


ABSTRACT

1H- and 13C-NMR data were used to characterize asphaltenes and to follow their chemical changes when they were exposed to thermal cracking under different thermal conditions (673, 693 and 713 K), and treatment times (10, 20 and 30 minutes). Samples of asphaltenes were obtained from a Vacuum Residue (VR) of a mixture of Colombian crude oils. Samples were previously characterized by elemental analysis. Since the characterization of the aromatic substructure is important for this work, special attention was given to those regions in the 1H- and 13C-NMR spectra that showed the main changes: p.e. methyl hydrogens -in gamma position or more- to aromatic units ; methyl hydrogens -in beta positions- to aromatics units ; methylene hydrogens -in beta position- to aromatics ; hydrogens -in naphthenic units beta- to aromatics ; hydrogens -in paraffinic and alpha position naphthenic structures-in - to aromatics ; hydrogens in monoaromatic units ; hydrogens in polyaromatics ; carbons in methyl groups ; carbons in methyl groups -in alpha position- to aromatics ; protonated aromatic carbons ; pericondensed aromatic carbons ; aromatic carbons linked to methyl groups; catacondensed aromatic carbons and aromatic carbons linked to paraffinic or naphthenic structures

Keywords: Asphaltenes, NMR spectroscopy, Thermal cracking.


RESUMEN

Datos de RMN-1H y 13C fueron usados para caracterizar asfaltenos y seguir sus cambios químicos cuando fueron expuestos a ruptura térmica bajo diferentes condiciones de temperatura (673, 693 y 713 K) y tiempo de reacción (10, 20 y 30 minutos). Las muestras de asfalteno fueron obtenidas de un residuo de vacío (VR de sus siglas en inglés) de una mezcla de crudos Colombianos. Las muestras fueron previamente caracterizadas mediante análisis elemental. Debido a que la caracterización de la estructura aromática es importante, se dio especial atención al análisis de aquellas regiones en los espectros de RMN1H y -13C que muestran los cambios más importantes, p.e. hidrógenos metílicos posición gamma o más a unidades aromáticas , hidrógenos metílicos en posición beta a unidades aromáticas , hidrógenos metilénicos en posición beta a unidades aromáticas , hidrógenos en unidades nafténicas beta a unidades aromáticas , hidrógenos en estructuras parafínicas y nafténicas en posición alfa unidades aromáticas , hidrógenos en unidades monoaromáticas , hidrógenos en unidades poliaromáticas , carbonos metílicos , carbonos metílicos en posición alfa a unidades aromáticas , carbonos aromáticos protonados , carbonos aromáticos pericondensados , carbonos aromáticos unidos a grupos metilo , carbonos aromáticos catacondensados , y carbonos aromáticos unidos grupos parafínicos o nafténicos .

Palabras clave: Asfaltenos, Espectroscopia de RMN, Craqueo térmico.


RESUMO

Dados de RMN-1H e de 13C foram usados para caracterizar asfaltenos e seguir suas mudanças químicas quando expostos a ruptura térmica sob diferentes condições de temperatura (673, 693, 713 K) e de tempo de reação (10, 20, 30 minutos). As amostras de asfalteno foram obtidas de um resíduo de vácuo (VR, por sua sigla em inglês) de uma mistura de crus Colombianos. As amostras foram previamente caracterizadas mediante análise elementar. Devido a que a caracterização da estrutura aromática é importante, foi dada especial atenção à análise daquelas regiões nos espectros de RMN-1H e de -13C que mostram as mudanças mais importantes, por exemplo, hidrogênios metílicos em posição gama ou mais a unidades aromáticas , hidrogênios metílicos em posição beta a unidades aromáticas , hidrogênios metilênicos em posição beta a unidades aromáticas , hidrogênios em unidades naftênicas beta a unidades aromáticas , hidrogênios em estruturas parafínicas e naftênicas em posição alfa a unidades aromáticas , hidrogênios em unidades monoaromáticas , hidrogênios em unidades poliaromáticas , carbonos metílicos carbonos metílicos em posição alfa a unidades aromáticas , carbonos aromáticos protonados , carbonos aromáticos pericondensados , carbonos aromáticos unidos a grupos metila , carbonos aromáticos catacondensados , e carbonos aromáticos unidos a grupos parafínicos ou naftênicos .

Palavras-chave: Asfaltenos, Espectroscopia de RMN, Craqueamento térmico.


1. INTRODUCTION

Structural characterization of crude oils and their fractions is crucial in determining quality and refined products over the entire range of the fractions. From a global perspective, the production of heavy crude oils has dramatically increased, and analytical tools producing information regarding the chemical structures play a key role in the petrochemical industry.

The chemical characterization of crude oils and their fractions includes the use of different spectroscopic techniques (Andersen, Oluf Jensen & Speight, 2005; Ballard-Andrews, Guerra, Mullins & Sen, 2006; Eyssautier et al., 2011; Hurtado, Gámez & Martínez-Haya, 2010; Rodríguez et al., 2006). Special attention has been given to proton and carbon nuclear magnetic resonance spectroscopy, 1H and 13C-NMR (Cantor, 1978; Dickinson, 1980; Knight, 1967; Majumdar, Gerken, Mikula & Hazendonk, 2013). Since its origins, NMR spectroscopy has been used to characterize petroleum fractions in both lighter fractions -such as jet fuel and gas oils- as well as in heavy fractions -such as VRs, crude oils, tar pitches, resins, and asphaltenes-. NMR data provide information regarding the relative amount of structural composition in a sample. In conjunction with elemental analysis and average molecular weight data, it is possible to obtain quantitative information about the different types of protons and carbons present. This chemical characterization is defined in terms of average molecular parameter, AMPs, and provides information for representing the bulk sample structural properties (Gillet, Delpuech, Valentin & Escalier, 1980; Gupta, Dogra, Kuchhal & Kumar, 1986; Hirsch & Altgelt, 1970; Poveda & Molina, 2012; Rongbao; Zengmin & Bailing, 1988; Brown & Ladner, 1960; Rousseau & Fuchs, 1989; Yokoyama et al., 1981).

13C-NMR experiments are useful to obtain information about backbone carbon structure in both medium and heavy fractions, information that cannot be obtained from 1H-NMR. Since it is impossible to distinguish each compound in heavy crude oils and their fractions, and quantitatively predict the presence of a particular compound using NMR spectroscopy, it is necessary to apply chemical characterization. This is done on the basis of the main chemical groups, and by using specific regions in the NMR spectra. The 13C-NMR experiments require long data acquisition times (hours), because a large number of scans and large pulse delays are needed, as well as relaxation reagents. In data analysis, the primary problem is matching specific areas with specific structural fragments. In this regard, several pulse sequences have been applied to specify the assignments in the spectra, including 1D and 2D experiments such as the Distortion Enhancement Proton Test (DEPT); Proton-Proton COrrelation SpectroscopY (COSY); Heteronuclear Multi Quantum Coherence (HMQC); Heteronuclear Multiple Bond Correlation (HMBC) (Dosseh, Rousseau & Fuchs, 1991; Doan, Gillet, Blondel & Beloiel, 1995; Väänänen, Koskela, Hiltunen & Ala-Korpela, 2002), and Heteronuclear Single Quantum Coherence (HSQC) (Majumdar et al., 2013).

Structural characterization of the different fractions of crude oils or fractions obtained in refinery processes -using NMR spectroscopy- may help understand the changes that occur at the molecular level when fractions are subjected to processes such as thermal cracking, catalytic hydrogenation, and pyrolysis, among others. Structural characterization of heavy fractions received particular attention because they cannot be characterized by conventional analytical techniques. Structural characterization helps understand how the operating conditions of a process unit can affect the molecular structure of a cut or fraction.

In this work, we use the NMR spectroscopy and area assignments reported by the authors (Poveda & Molina, 2012) to analyze the structural changes of asphaltenes obtained from a vacuum residue thermally cracked at three reaction times (10, 20 and 30 minutes) and different temperatures (673, 693 and 713 K). Similar experimental conditions were previously reported by other authors (Yasar, Trauth & Klein, 2001; Ancheyta, Trejo & Rana, 2009; Butz & Oelert, 1995). The studied VR was obtained from a mixture of Colombian heavy crude oils.

2. EXPERIMENTAL SECTION

Thermal Cracking

The VR was obtained from a mixture of Colombian crude oils in a vacuum distillation unit. The VR was diluted in 1-methylnaphthalene up to 10 per cent in weight. The reactor used for the thermal cracking experiments was constructed with stainless steel and a volume of 12.5 mL with dimensions of 120 mm (length) by 6.5 mm (diameter), and was operated in steady state regimen at pressures up to 3.0 MPa (Inert blanket maintained for these experiments). Reactor temperatures used in the experiments were digitally controlled at 673, 693 and 713 K. At each temperature, sample fluxes along the reactor were maintained at 4.8, 7.5 and 14.8 mL per hour, giving residence times of 10, 20 and 30 minutes, respectively.

Asphaltenes Extraction

After VR samples were thermal cracked under selected experimental conditions, they were fractionated by the ASTM Standard Test Method for Determination of Asphaltenes (Heptane Insolubles) in Crude Petroleum and Petroleum Products (ASTM D6560-12) to extract the asphaltenes. All the asphaltene samples were concentrated and dried at 333 K, under an inert atmosphere (N2), until no changes in weight were registered.

Elemental Analysis

Asphaltenes were characterized by elemental analysis: carbon, hydrogen, nitrogen (ASTM D5291-10/ ASTM D5373-08), and sulfur (ASTM D4239-12). The results are reported in Table 1.

Nuclear Magnetic Resonance Spectroscopy

The 1H- and 13C-NMR spectra were obtained with a Bruker AMX spectrometer at 300 and 75.47 MHz, respectively. 4% wt/wt sample solutions prepared in CDCl3 (99.8 % D) were analyzed via 1H-NMR. 30° pulses (Bruker zg30 pulse sequence) were used, and the delay time was 2 s (sweep width 3900.25 Hz). Sixteen scans were averaged for each spectrum. 10% wt/wt sample solutions in CDCl3 (99.8% D) were analyzed via 13C-NMR, using Cr(acac)3 as paramagnetic relaxation reagent at a 0.05 M concentration. The 30° pulses (Bruker zgig30 pulse sequence) were used, with a delay time of 20 seconds (sweep width 16666.67 Hz). 3000 scans were averaged for each spectrum. In both cases, spectra were recorded using a 5 mm probe with a spinning rate of 10 Hz and a temperature of 298.15 K. 1H- and 13C-NMR spectra of asphaltenes from the reference VR sample are shown in Figures 1 and 2 respectively, noticing that these spectra look like many others reported in literature.

NMR data were processed using the standard procedure as follows: free induction decays were apodized using exponential windows with a weight factor of 1, followed by the Fourier transform, zero- and one-order phase, and base line correction. Finally, the selected areas, accordingly with the areas of the procedure previously reported by the authors (Poveda & Molina, 2012), were integrated and normalized. The procedure was integrated and normalized. The procedure was repeated eight times, average values were calculated and the absolute errors were not higher than 4.5%, as shown in Tables 2 and 3.

3. MOLECULAR CHANGES OF ASPHALTENES AFTER THERMAL CRACKING

Structural changes of asphaltenes samples obtained after thermal cracking of VRs were analyzed based on the areas of 1H- and 13C-NMR reported by authors (Poveda & Molina, 2012). Tables 2 and 3 present the regions in the 1H- and 13C-NMR spectra and the average values of calculated areas.

4. RESULTS AND DISCUSSION

Physicochemical Characterization and NMR Considerations

Elemental analysis (Table 1) reveals that as the reaction severity increases, the percentage of carbon and nitrogen increases, while the percentage of hydrogen and sulfur decreases. The changes in the elemental analysis show that chemical changes are occurring during the thermal cracking process. Condensation of the aromatic substructures may increase as the reaction occurs, and the relative percentage of hydrogen decreases as a result of cleavage of the bonds linking paraffinic substructures to the aromatic cores. Produced saturated molecules can be eliminated as gases, and the relative ratio of carbon to hydrogen increases as a consequence of the increment in the relative amount of aromatics. These data play in favor of the elimination of small molecules with relative high amounts of hydrogen as CH4, C2H6, C3H8, with C⁄H ratios of 0.25, 0.33 and 0.375; respectively. On the other hand, aromatics as benzene (C6H6), naphthalene (C10H8), and coronene (C24H12), show C⁄H ratios of 1.0, 1.25 and 2.0, respectively. Based on the elemental analysis, we can calculate the C/H ratio as (%C/12)/(%H/1), reported values are shown in Table 1. As the severity of thermal cracking increases, C/H ratio increases as shown in Figure 3. The calculated C/H ratio -for those asphaltenes in the original vacuum residue- show a value of 0.899, lower than the calculated for benzene. This result suggests that not only aromatics are present in the sample, but also paraffinic chains. As a result, C/H values diminish. For the limit case, when longer aliphatic chains are present, the maximum C/H value could be 0.5, which diminishes as the number of carbons decreases. The maximum C/H value 2.225 was observed at a reaction time of 30 min, and a temperature of 713 K. The calculated value indicates that asphaltenes condensate as the reaction occurs. It can be argued that changes in the molecular structure start from a low condensed aromatic structure with pendant paraffinic chains, to a higher condensed structure with lower number of side paraffinic chains.

In 13C-NMR spectra, unusual chemical shifts of the aromatic carbons were observed. Values between 110 and 160 are common (Asaoka, Nakata, Shiroto & Takeuchi, 1983), but the 13C-NMR spectra of samples local induced magnetic fields can perturb the chemical showed chemical shifts up to 82 ppm (Figure 2). shifts observed for small aromatic molecules. The The observed chemical shifts can be primarily phenomenon of stacking can also be observed as the attributed to some structural reordering in the aromatic concentration of NMR analyzed solutions increase. This substructure. Higher degrees of aromatic condensation allows intermolecular interactions, and the molecular can be responsible for strong annular electron currents arrangement energetically favors the stabilization of that produce local induced magnetic fields. These clusters.

Structural Characterization of Asphaltenes using NMR Spectroscopy after Thermal Cracking

Structural changes were followed studying the changes of functional group areas in the 1H- and 13C-NMR spectra. This allows identifying the main changes in chemical structures occurring during the thermal cracking process. The analysis focused on the structural changes occurring in the aromatic, naphthenic and paraffinic substructures, and how those increased or decreased as function of the reaction variables.

From the 1H-NMR spectra and integrated areas we can observe that as the severity conditions of thermal cracking increases (residence time and reaction temperature), some areas show particular tendencies, as explained here. For the H1 region, were resonances of paraffinic hydrogens appear in CH3 groups, the relative area decreases because thermal treatment reduces the amount of such group, probably by a C-C bond scission. Also, the same tendency was observed in the region, where and hydrogens appear, corresponding to CH3 and CH2 in a β position to aromatic rings.

An interesting behavior was observed when the areas of regions H6 and H7 were analyzed. In these regions, the hydrogens in aromatic systems appear, both monoaromatics and polyaromatics. Integrated areas do not show a general tendency as observed in regions H1 and H2. This behavior can be interpreted as many processes at molecular scale take place during cracking. Aromatic cores can change as a consequence either from the elimination of fragments, or capture of saturated carbons in alpha position to the aromatic core. When region H4 was analyzed, a correlation between the areas and reaction conditions was not observed.

From a molecular point of view, this behavior could be explained by a two-step mechanism: first, the formation of radicals allows the possible fusion of paraffinic chains to the aromatic cores, forming naphthenic rings; and second, if hydrogen elimination takes place from naphthenic rings, an increase in the number of aromatic rings is possible.

Thermal cracking reactions are one of the most extensively studied processes in heavy fractions such as VRs (Ancheyta et al., 2009). From some experimental results therein published, the structural changes observed in the asphaltenes during thermal cracking are in agreement with the reaction mechanisms reported in the literature (Hayashitani, Bennion, Donnelly & Moore, 1978). These reaction mechanisms are the scission of C-C and C-H bonds, aromatization, alkylation, condensation, and dehydrogenation (Hayashitani et al., 1978).

The structural complexity of asphaltenes makes the analysis of changes of molecular structure really difficult. Therefore, some authors employ model compounds to study the possible changes occurring during thermal cracking (Savage & Klein, 1987). The asphaltenes consist mainly of a core, or cores of polycondensed aromatic rings with alkyl and naphthenic chains. With the increase in temperature, the C-C bond of the pendant chains can be broken, and hydrocarbons of low molecular weight, possibly as gases, are formed. Savage, Klein and Kukes (1985) report that lighter paraffins were formed from secondary reactions of larger saturated chains and not exclusively by primary decomposition of asphaltenes. Secondary reactions involve the cracking of naphthenes and long-chain alkanes.

In this work we observed that the ratio HAr/HSat (Figure 4), where HAr=H6+H7, and HSat=H1+H2+H3+H4 (Table 2), does not show a clear tendency as a function of reaction time. At a reaction time of 10 minutes, the HAr/HSat ratio does not show a clear behavior but decreases comparatively to the uncracked sample. At 673 K, the ratio HAr/HSat is close to 0.113, decreasing to 0.042 at 693 K, but increasing when temperature reaches 713 K. When reaction times are 20 and 30 minutes, the HAr/HSat ratio shows a tendency as a function of reaction temperature. At 20 minutes of reaction, the HAr/HSat ratio increases from 0.042 to 0.084. This behavior shows that asphaltenes of vacuum residue reduce the amount of saturated structures while the aromatics increases. This could be possible when C-C bond scissions increase at long reaction times, more than 20 minutes; therefore, parts of aliphatic chains of molecules are eliminated.

When we observe the CAr/CSat ratio (Figure 5), where CAr=C6+C7+C8, and CSat=C1+C2+C3+C4, the results are in good agreement with the proposed explanation for the behavior of the HAr/HSat ratio. At low reaction times (10 minutes), the amount of aromatic carbon relative to saturated carbon decreases. At these short times, the molecular processes can be characterized for molecular rearrangements, in order to increase the saturated structures. When reaction times reach 30 minutes, the amount of aromatic carbon increases, in accordance with saturated structures. As the reaction time increases, the reactions allow the formation of aromatics, possibly increasing the size of condensed aromatic units by a mechanism that involves the fusion and dehydrogenation of naphthenic rings to aromatics. Consequently, the size of aromatics rings increases.

As was reported by Butz and Oelert (1995), the cracking of asphaltenes at temperatures of 683, 708 and 733 K in a batch reactor shows that the rate of asphaltene conversion decreases continuously with an increase in the reaction time. Despite longer reaction times, the aromatic cores are more difficult to react.

5. CONCLUSIONS

  • The present work reports the structural changes in asphaltenes observed from thermal cracking a vacuum residue, determined on the basis of the integrated areas in the 1H- and 13C-NMR spectra. NMR spectroscopic analysis is an affordable technique to understand the molecular changes when heavy crude oils and their fractions are exposed to refinery processes as thermal cracking, catalytic hydrogenation, and others. Under the thermal cracking conditions used in this work, there is an increased reaction in temperatures and reaction times in cleaved asphaltenes, producing light gases and increasing the molecular complexity of asphaltenes remaining after processing. The results indicate that the asphaltenes exposed to thermal cracking increased their aromatic size. Additional experiments and analysis are required to understand the complex reactivity mechanism that takes place when heavy crude oils fractions are exposed to thermal treatments.

ACKNOWLEDGEMENTS

The authors would like to thank Escuela de Química at Universidad Industrial de Santander, and Ecopetrol S.A. -Instituto Colombiano del Petróleo for the support to make possible the completion of this work.


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AUTHORS

Juan Carlos Poveda
Affiliation: Universidad Industrial de Santander
Chemist, Universidad Industrial de Santander
Ph. D. in Chemistry, Universidad Nacional Autónoma de México
e-mail: jcpoveda@uis.edu.co

Daniel Ricardo Molina
Affiliation: Universidad Industrial de Santander
Chemist, Universidad Industrial de Santander
Ph. D. in Chemistry, Universidad Industrial de Santander
e-mail: dmolina@uis.edu.co

Edgar Francisco Pantoja Agreda
Affiliation: Corporación para la Investigación de la Corrosión
Chemical Engineering, Universidad Nacional de Colombia
M. Sc. in Chemical Engineering, Universidad Industrial de Santander
e-mail: pantoja.francisco@gmail.com