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New Magnetic Fe Oxide-Carbon Based Acid Catalyst Prepared from Bio-Oil for Esterification Reactions

Abstract

In this work, bio-oil (an organic matrix rich in oxygen functionalities) was used to efficiently dissolve and disperse Fe3+ which upon thermal treatment produced a carbon containing dispersed and encapsulated Fe oxide magnetic nanoparticles. These materials were prepared by dissolution of 8, 16 and 24 wt.% Fe3+ salt in bio-oil followed by treatment at 400, 450, 500 or 600 ºC in N2 atmosphere. X-ray diffraction (XRD), scanning (SEM) and transmission electron microscopies (TEM), elemental analysis, thermogravimetric-mass spectrometry (TG-MS), potentiometric titration, Raman and Mössbauer spectroscopies showed that Fe3+ species in bio-oil is reduced to produce magnetic nanoparticles phases: magnetite Fe3O4 and maghemite γ-Fe2O3. At low temperatures, the iron phases were less protected, and the carbon matrix was more reactive, while in temperatures above 500 ºC, the iron phases were more stable, however, the carbon matrix was less reactive. Reaction of these magnetic carbon materials with concentrated H2SO4 produced surface sulfonic acidic sites (ca. 1 mmol g-1), especially for the materials obtained at 400 and 450 ºC. The materials were used as catalysts on esterification reaction of oleic acid with methanol at 100 ºC and conversions of 90% were reached, however, after 2 consecutive uses, the conversion decreased to 30%, being required more studies to improve the material stability.

Keywords:
bio-oil; Fe3+ dissolution; magnetic carbons; sulfonation; acid catalyst; esterification


Introduction

Bio-oil is a renewable and low-cost feedstock, which is generated by biomass flash pyrolysis.11 Mortensen, P. M.; Grunwaldt, J.-D.; Jensen, P. A.; Knudsen, K. G.; Jensen, A. D.; Appl. Catal., A 2011, 407, 1.,22 Bridgwater, A. V.; Biomass Bioenergy 2012, 38, 68. It is composed by water, alcohols, furans, acids, ketones, carbohydrates,33 Mullen, C. A.; Boateng, A. A.; Goldberg, N. M.; Lima, I. M.; Laird, D. A.; Hicks, K. B.; Biomass Bioenergy 2010, 34, 67. and usually have highly oxygenated large carbon structures.44 Guo, X.; Zheng, Y.; Zhang, B.; Chen, J.; Biomass Bioenergy 2009, 33, 1469.,55 Boateng, A.; Sadaka, S.; J. Anal. Appl. Pyrolysis 2012, 95, 38. These oxygen groups are considered undesirable since they bring some properties such as acidity, corrosion and thermal instability.66 Kim, J.-S.; Bioresour. Technol. 2015, 178, 90. Different upgrade processes such as cracking,77 Hew, K. L.; Tamidi, A. M.; Yusup, S.; Lee, K. T.; Ahmad, M. M.; Bioresour. Technol. 2010, 101, 8855. decarboxylation,88 Khromova, S. A.; Smirnov, A. A.; Selishcheva, S. A.; Kukushkin, R. G.; Dundich, V. O.; Trusov, L. I.; Yakovlev, V. A.; Catal. Ind. 2013, 5, 260. decarbonylation,99 Isa, K. M.; Ying, L. J.; Saad, S. S.; Kasim, F. H.; Rahim, M. A. A.; J. Adv. Res. Fluid Mech. Therm. Sci. 2016, 27, 12. hydrodeoxygenation1010 Yang, T.; Shi, L.; Li, R.; Li, B.; Kai, X.; Fuel Process. Technol. 2019, 184, 65. have been investigated to decrease the oxygen content to convert bio-oil into fuel,1111 Czernik, S.; French, R.; Feik, C.; Chornet, E.; Ind. Eng. Chem. Res. 2002, 41, 4209. adhesives1212 Oldham, D. J.; Fini, E. H.; Chailleux, E.; Constr. Build. Mater. 2015, 86, 75. and chemicals.1313 Chaiwat, W.; Gunawan, R.; Gholizadeh, M.; Li, X.; Lievens, C.; Hu, X.; Wang, Y.; Mourant, D.; Rossiter, A.; Bromly, J.; Li, C.-Z.; Fuel 2013, 112, 302.

On the other hand, very few studies1414 Mendonça, F. G.; Gomes, J. P. M.; Tristão, J. C.; Ardisson, J. D.; Soares, R. R.; Lago, R. M.; Fuel 2016, 184, 36.

15 Milina, M.; Mitchell, S.; Pérez-Ramírez, J.; Catal. Today 2014, 235, 176.
-1616 Ballotin, F. C.; Perdigão, L. T.; Rezende, M. V. B.; Pandey, S. D.; da Silva, M. J.; Soares, R. R.; Freitas, J. C. C.; Teixeira, A. P. C.; Lago, R. M.; New J. Chem. 2019, 43, 2430. have taken advantage of the oxygen and acidic properties of bio-oil. For example, the acidic characteristics of the aqueous fraction of bio-oil was used to extract iron from mining tailings to produce different materials and fuels1414 Mendonça, F. G.; Gomes, J. P. M.; Tristão, J. C.; Ardisson, J. D.; Soares, R. R.; Lago, R. M.; Fuel 2016, 184, 36. and derivatization of esterification reactions.1515 Milina, M.; Mitchell, S.; Pérez-Ramírez, J.; Catal. Today 2014, 235, 176. The reactivity of the oxygen groups of bio-oil have also been used to produce carbon nanostructures such as graphene, nongraphite, nanotubes and nanoparticles by the simple reaction with H2SO4.1616 Ballotin, F. C.; Perdigão, L. T.; Rezende, M. V. B.; Pandey, S. D.; da Silva, M. J.; Soares, R. R.; Freitas, J. C. C.; Teixeira, A. P. C.; Lago, R. M.; New J. Chem. 2019, 43, 2430.

In this work, bio-oil structural oxygen acidic groups were used to disperse Fe3+ ions. Upon thermal decomposition at different temperatures, 400-600 ºC, Fe3+/bio-oil solution produces a carbon containing Fe oxides magnetic nanoparticles due to the carbonization and reduction of highly dispersed Fe3+ species. These magnetic carbon materials can have several applications in different areas such as catalysis,1717 Li, X.; Shi, J.; Wang, Z.; Duan, X.; Chen, G.; Guan, Q.; Li, X.; Lei, T.; BioResources 2017, 12, 7525.

18 Pasinszki, T.; Krebsz, M.; Kótai, L.; Sajó, I. E.; Homonnay, Z.; Kuzmann, E.; Kiss, L. F.; Váczi, T.; Kovács, I.; J. Mater. Sci. 2015, 50, 7353.
-1919 de Mendonça, F. G.; Rosmaninho, M. G.; da Fonseca, P. X.; Soares, R. R.; Ardisson, J. D.; Tristão, J. C.; Lago, R. M.; Environ. Sci. Pollut. Res. 2017, 24, 6151. adsorption,2020 Tristão, J. C.; Oliveira, A. A. S.; Ardisson, J. D.; Dias, A.; Lago, R. M.; Mater. Res. Bull. 2011, 46, 748. drug delivery,2121 Al Faraj, A.; Shaik, A. P.; Shaik, A. S.; Int. J. Nanomed. 2014, 10, 157. hyperthermic materials.2222 Dalal, M.; Greneche, J.-M.; Satpati, B.; Ghzaiel, T. B.; Mazaleyrat, F.; Ningthoujam, R. S.; Chakrabarti, P. K.; ACS Appl. Mater. Interfaces 2017, 9, 40831.

It is also described the sulfonation of these carbons, which showed reactivity dependent of thermal treatment temperature to produce magnetic acid materials which have potential application in acid-catalyzed reactions.2323 Yu, H.; Niu, S.; Lu, C.; Li, J.; Yang, Y.; Energy Convers. Manage. 2016, 126, 488. They can be used in hydrogenation,2424 Canivet, J.; Süss-Fink, G.; Green Chem. 2007, 4, 391. photocatalysis,2525 Velasco, L. F.; Maurino, V.; Laurenti, E.; Fonseca, I. M.; Lima, J. C.; Ania, C. O.; Appl. Catal., A 2013, 452, 1. electrocatalysis,2626 Müller, F.; Ferreira, C. A.; Franco, L.; Puiggalí, J.; Alemán, C.; Armelin, E.; J. Phys. Chem. B 2012, 116, 11767. dehydration and dehydrogenation of alcohols2727 Hasan, Z.; Hwang, J.-S.; Jhung, S. H.; Catal. Commun. 2012, 26, 30. and esterification reactions.2828 Santos, E. M.; Teixeira, A. P. C.; da Silva, F. G.; Cibaka, T. E.; Araújo, M. H.; Oliveira, W. X. C.; Medeiros, F.; Brasil, A. N.; de Oliveira, L. S.; Lago, R. M.; Fuel 2015, 150, 408.

The catalytic esterification of fatty acids was also evaluated using sulfonated carbon based on bio-oil, once this reaction is an important alternative to convert acid vegetable oils into biodiesel. Sulfuric acid has been used as homogeneous catalyst,2929 Liu, T.; Li, Z.; Li, W.; Shi, C.; Wang, Y.; Bioresour. Technol. 2013, 133, 618. however, corrosion problems and loss of the catalyst have been considered important drawbacks.3030 Dawodu, F. A.; Ayodele, O.; Xin, J.; Zhang, S.; Yan, D.; Appl. Energy 2014, 114, 819.,3131 Mar, W. W.; Somsook, E.; Procedia Eng. 2012, 32, 212.

Therefore, the sulfonation process of carbon materials to develop heterogeneous catalysts to produce biodiesel using acidic oils is of considerable importance.3232 Brand, R. A.; Nucl. Instrum. Methods Phys. Res., Sect. B 1987, 28, 398.,3333 Ngaosuwan, K.; Goodwin, J. G.; Prasertdham, P.; Renewable Energy 2016, 86, 262. Biomass incomplete carbonization and sulfonation has been done to produce acid catalyst. In literature, it was found that corn straw,2929 Liu, T.; Li, Z.; Li, W.; Shi, C.; Wang, Y.; Bioresour. Technol. 2013, 133, 618. glucose3030 Dawodu, F. A.; Ayodele, O.; Xin, J.; Zhang, S.; Yan, D.; Appl. Energy 2014, 114, 819. and starch of mung bean,3131 Mar, W. W.; Somsook, E.; Procedia Eng. 2012, 32, 212. were used as carbon source to produce sulfonated carbon materials with 2.64, 1.0 and 1.53 mol g-1 of acidity which were used as acid catalysts on esterification reactions.

Thus, in this work, a novel application of bio-oil to produce an efficient acidic and magnetic carbon-based catalysts was investigated.

Experimental

Bio-oil production

Bio-oil was obtained in a plant at Federal University of Uberlândia, MG, Brazil, from pyrolysis of sugarcane straw at 450 ºC. It is composed of carbohydrates, phenols, furans, guaiacols, syringols and presented 46% C and 7% of H.1616 Ballotin, F. C.; Perdigão, L. T.; Rezende, M. V. B.; Pandey, S. D.; da Silva, M. J.; Soares, R. R.; Freitas, J. C. C.; Teixeira, A. P. C.; Lago, R. M.; New J. Chem. 2019, 43, 2430.

Iron impregnation

Bio-oil (5.0138 g) was dissolved in 20 mL of ethanol and impregnated with an ethanolic solution of 8, 16 and 24 wt.% Fe, Fe(NO3)3.9H2O.3434 Li, H.; Wang, Y.; Zhu, Y.; Xu, X.; Wu, A.; Deng, X.; BioResources 2018, 13, 6221.,3535 Chen, T.; Peng, L.; Yu, X.; He, L.; Fuel 2018, 219, 344. The solution remained under stirring for 30 min. After this time, the solvent was evaporated and the solid obtained were dried for 12 h at 353 K. The dried sample were named here as B8Fe, B16Fe or B24Fe, respective to the Fe percentage.

Pyrolysis

About 800 mg of B8Fe were thermally treated in a tubular oven at 400, 450, 500 and 600 ºC for 1 h in N2 atmosphere (50 mL min-1).3434 Li, H.; Wang, Y.; Zhu, Y.; Xu, X.; Wu, A.; Deng, X.; BioResources 2018, 13, 6221.,3535 Chen, T.; Peng, L.; Yu, X.; He, L.; Fuel 2018, 219, 344. The obtained materials were named hereon as (B8Fe)400, (B8Fe)450, (B8Fe)500 and (B8Fe)600, respective to the thermal treatment temperature.

Sulfonation

0.5000 mg of the pyrolyzed sample was submitted to a sulfonation reaction with a ratio 9.2:1 m/m of concentrated H2SO4:bio-oil at 120 ºC for 2 h, under magnetic stirring.2828 Santos, E. M.; Teixeira, A. P. C.; da Silva, F. G.; Cibaka, T. E.; Araújo, M. H.; Oliveira, W. X. C.; Medeiros, F.; Brasil, A. N.; de Oliveira, L. S.; Lago, R. M.; Fuel 2015, 150, 408.,3636 Zhou, Y.; Niu, S.; Li, J.; Energy Convers. Manage. 2016, 114, 188. After the reaction, the materials were washed with distilled water until pH ca. 5.50 and dried at 80 ºC for 12 h. The catalyst yield was calculated according to equation 1:

(1) Yield % = w final / w initial × 100

where winitial is the material weight before thermal treatment and wfinal is the weight after pyrolysis and sulfonation process.

The catalysts were named as (B8Fe)400S, where S refers to sulfuric acid treatment.

Materials characterization

The content of some elements (carbon, hydrogen, nitrogen and sulfur) on the synthesized materials was determined by elemental analysis using PerkinElmer CHN analyzer. Scanning electron microscopy (SEM) images were obtained in a FIB, Quanta FEG 3D FEI equipment. The samples were dispersed in acetone and deposited onto a silicon plate. The transmission electron microscopy (TEM) images were obtained in a G2-20, SuperTwin FEI, 200 kV.

X-ray diffraction (XRD) studies were performed on a Shimadzu diffractometer, model XRD-7000 with Cu Kα and a scan speed of 4º min-1. Thermogravimetric analysis (TGA) was performed on a Shimadzu DTG 60H with air flow (50 mL min-1) and a heating rate of 10 K min-1 up to 1273 K. Catalyst acidity was measured by potentiometric titration. The solid (0.05 g) were suspended in acetonitrile (40 mL) and shaken for 24 h. Then, the suspension was potentiometrically titrated with a 0.025 mol L-1 n-butylamine solution in toluene. The electrode potential variation was measured with a BEL pH instrument.

Simultaneous thermogravimetric-mass spectrometry (TG-MS) analyses were performed. The base peaks (m/z 18, 28, 44, 64 and 80) were selected to be monitored in a NETZSCH TG/STA equipment coupled with Aelos spectrometer, model 7.0. The samples specific surface areas were analyzed by adsorption of N2 at 77 K using analyzer Quantachrome, model NOVA 1200e. The samples were degassed at 80 ºC for 4 h before the analyses. The absorption spectroscopy measurements in the infrared region with Fourier transform (FTIR) attenuated total reflectance (ATR) were performed on PerkinElmer equipment, model Spectrum 1000. Spectra were collected in the range of 400-4000 cm-1 region, with 64 accumulations.

Raman spectra of carbon material obtained from bio-oil were acquired using Raman Senterra spectrometer, 532 nm laser line was used for excitation with the exposure time of 60 s and 10 mW of power.

57Fe Mössbauer spectra (MS) were obtained at room temperature and at 30 K, in transmission geometry with a source of 57Co in Rh matrix. Spectral hyperfine parameters were calculated using the Normos least-squares-fit software package.3232 Brand, R. A.; Nucl. Instrum. Methods Phys. Res., Sect. B 1987, 28, 398.

Catalytic runs

The esterification reactions of oleic acid with methanol were performed in a sealed tube glass reactor with sampling septum in a thermostatic bath with magnetic stirring. Dodecane was used as internal standard. The solid catalysts, i.e., (B8Fe)400S, (B8Fe)450S, (B8Fe)500S and (B8Fe)600S, were used in variable loads (ca. 1-10 wt.%). The reactions were performed at temperature ranging of 60-100 ºC.3737 Ibrahim, N. A.; Rashid, U.; Taufiq-Yap, Y. H.; Yaw, T. C. S.; Ismail, I.; Energy Convers. Manage. 2019, 195, 480. The oleic acid:methanol molar ratio used was 1:303838 Zhang, H.; Luo, X.; Shi, K.; Wu, T.; He, F.; Yang, H.; Zhang, S.; Peng, C.; Carbon 2019, 147, 134. (0.58 mL of oleic acid and 2.22 mL of methanol).

Catalyst reuse

The reuse test was performed using 10 wt.% of catalyst (B8Fe)450S, 1:30 oleic acid:methanol, at 100 ºC during 6 h. After each reaction, the catalyst was separated from the products using a magnet, washed with methanol and reuse reactions were performed.

Catalyst leaching

Leaching was evaluated at the oleic acid:methanol molar ratio of 1:30, using 10 wt.% of catalyst (B8Fe)450S. For the tests, the catalyst was transferred to the reaction medium containing only methanol. The system was maintained under constant stirring for 90 min at 100 ºC. After this period, methanol was removed and transferred to a vial containing only oleic acid, thus proceeding with the reaction.

Analysis of products

After the reaction, the mixture was dissolved in 3 mL of hexane. The methyl ester was quantified in a gas chromatography coupled with flame ionization detector (GC-FID) using a Shimadzu GC-2010, equipped with a Carbowax capillary column (0.25 m × 0.25 mm × 30 m).

Results and Discussion

Previous GC-MS and 1H nuclear magnetic resonance (NMR) characterization of bio-oil showed a complex matrix composed of syringols, phenols, carboxylic acids, aldehydes, ketones, alcohols and a heavier fraction containing oligomers with different oxygen functionalities.1616 Ballotin, F. C.; Perdigão, L. T.; Rezende, M. V. B.; Pandey, S. D.; da Silva, M. J.; Soares, R. R.; Freitas, J. C. C.; Teixeira, A. P. C.; Lago, R. M.; New J. Chem. 2019, 43, 2430. FTIR and elemental analyses confirmed the presence of a great amount of oxygen groups, ca. 48% (Figure 1).

Figure 1
Infrared spectrum (ATR) and elemental analysis of bio-oil (adapted from reference 16).

It is interesting to observe that Fe(NO3)3 could be well solubilized in rather hydrophobic organic matrix bio-oil. Although the mechanism responsible for this solubilization of Fe3+ is not clear, the interaction/complexation with different oxygen groups such as phenolic and carboxylic is most likely involved in this process.

Three different bio-oil solutions in ethanol were prepared containing 8, 16 and 24 wt.% Fe(NO3)3 (in relation to bio-oil content). After 30 min of stirring, the solvent was evaporated to produce a viscous/vitreous precursor. No visual indication that Fe(NO3)3 was crystallized, segregated or separated from the bio-oil was observed. The precursors were thermally treated in nitrogen atmosphere at 450 ºC for 1 h.

XRD analyses of the obtained materials (Figure S1 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , Supplementary Information (SI) section) showed the formation of magnetic iron phases, e.g., magnetite (Fe3O4)/maghemite (γ-Fe3O4). The samples were sulfonated with H2SO4 and tested as catalysts in oleic acid esterification reactions. The tests showed that when materials (B16Fe)450S and (B24Fe)450S were used, a large amount of iron oxide was leached, and no formation of biodiesel occurred. Probably, in these samples, the carbon was not sufficient to protect the iron phases.

Therefore, the effect of thermal treatment was investigated in more detail for the sample B8Fe which was treated at 400, 450, 500 and 600 ºC. In general, the samples presented low cristallinity as showed by XRD (Figure S2 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section), with two peaks observed for all samples at ca. 24º related to the amorphous carbon3333 Ngaosuwan, K.; Goodwin, J. G.; Prasertdham, P.; Renewable Energy 2016, 86, 262. and 35º, likely related to Fe3O4 (magnetite) (JCPDS1-1111) or γ-Fe2O3 (maghemite) (JCPDS:39-1346).3939 Meshkani, F.; Rezaei, M.; Chem. Eng. Res. Des. 2015, 95, 288.

After sulfonation (Figure 2), a broad peak at 24º was observed for sample (B8Fe)400S. However, the peak related to iron phase disappeared, due to iron leaching in the presence of H2SO4.

Figure 2
XRD patterns of samples (B8Fe)400S, (B8Fe)450S, (B8Fe)500S and (B8Fe)600S.

As the temperature of treatment increased, the iron phase became more structured and the peaks at 35 and 43º related to Fe3O4 (magnetite) or γ-Fe2O3 (maghemite) were observed. Scherrer equation was used to estimate the crystallite size of the iron oxide which was in the range of 3-5 nm.

Mössbauer spectra before (Figure S3 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section) and after sulfonation (Figure 3), consisted of a set of six-lines pattern related to a ferromagnetic material indicating a mixture of maghemite/magnetite (hyperfine parameters are shown in Table S1 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section). According to measurements, the samples at room temperature presented a superparamagnetic behavior. At 30 K, (B8Fe)450 and (B8Fe)450S still present superparamagnetic character, however, as temperature of thermal treatment increased, the samples presented a higher degree of organization.

Figure 3
Mössbauer spectra at 30 K of samples (B8Fe)450S, (B8Fe)500S and (B8Fe)600S.

According to XRD and Mössbauer results, after bio-oil impregnation with Fe(NO3)3 and thermal treatment (400-600 ºC) under N2 atmosphere, occurred the partial reduction of Fe3+ leading to the formation of a Fe2+/Fe3+ oxide. Although the mechanism for this reduction is not clear, it is most likely that reducing species such as H2, CO, organics and amorphous carbon formed during bio-oil decomposition4040 Liu, W.-J.; Tian, K.; Jiang, H.; Yu, H.-Q.; Sci. Rep. 2013, 3, 2419. are involved in Fe3+ reduction.

SEM analyses of material treated at 400 ºC (Figure 4) showed that before sulfonation, the material presented particles between 50 and 300 µm. Moreover, mapping and energy-dispersive X-ray spectroscopy (EDS) (Figure S4 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section) analyses showed that iron was leached by sulfuric acid indicating that the carbon formed did not encapsulate/protect the Fe oxide particles.

Figure 4
Scanning electron microscopy images of iron materials before, (B8Fe)400, and after sulfonation (B8Fe)400S, (B8Fe)450S, (B8Fe)500S and (B8Fe)600S.

After sulfonation (Figure 4), particles of 50 µm and irregular surfaces were observed.

TEM images for material treated at 400 ºC and sulfonated showed no iron in its structure confirming acid leaching (Figure S5 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section). For samples treated at temperatures 450, 500 and 600 ºC (Figures 5-6), iron was dispersed all over the materials surface and remained encapsulated by the carbon matrix. The images and histogram (Figure 6) showed that iron nanoparticles have sizes between 5-20 nm.

Figure 5
Transmission electron microscopy images of materials (B8Fe)450 and (B8Fe)450S.

Figure 6
(Top) Transmission electron microscopy images of materials (B8Fe)500S and (B8Fe)600S and (bottom) particle size distribution.

The yield of catalyst synthesis as well as the evaluation of the sulfonation process was carried out by elemental analyses. Table 1 shows C, H, N and S contents in these materials.

Table 1
C, H and N content of bio-oil and materials impregnated with 8 wt.% of iron (B8Fe) and sulfonated

After pyrolysis and H2SO4 reaction, the materials were ground and extensively washed with deionized water until pH 6.0. In general, the materials yield decreased with pyrolysis temperature increase: 50.3, 47.3, 42.1 and 39.7% for (B8Fe)400S, (B8Fe)450S, (B8Fe)500S and (B8Fe)600S, respectively. Indeed, at higher temperatures more volatiles were released from the organic matrix.

The original bio-oil (before thermal treatment and sulfonation) presented 45.5, 6.6 and 0.5% of C, H and N,1616 Ballotin, F. C.; Perdigão, L. T.; Rezende, M. V. B.; Pandey, S. D.; da Silva, M. J.; Soares, R. R.; Freitas, J. C. C.; Teixeira, A. P. C.; Lago, R. M.; New J. Chem. 2019, 43, 2430. respectively. According to elemental analysis, carbon content increased from ca. 46 to 48-54% and the H content decreased for sample (B8Fe)400S, due to dehydration and carbonization. Furthermore, the presence of 3.4-4.5% N indicates the presence of non-decomposed nitrate and likely nitrogen groups formed during the process.

Relatively high sulfur content was observed, i.e., 5.0%, for the sample (B8Fe)400S likely due to the sulfonation of the carbon formed after treatment at 400 ºC. On the other hand, S decreased to 3.8, 2.5 and 2.2% as the material was pre-treated at 450, 500 and 600 ºC, respectively. This result suggests that thermal treatment at temperatures higher than 400 ºC is producing carbons that are well structured and more difficult to sulfonate.

Raman spectra of materials (Figure 7) showed two bands characteristics of carbonaceous materials,4141 Cuesta, A.; Dhamelincourt, P.; Laureyns, J.; Carbon 1994, 32, 1523. the G band (1590 cm-1), which is related to more organized graphitic structures, and D band (1350 cm-1), which indicates the presence of defects in carbonaceous structures and amorphous carbon.

Figure 7
Raman spectra of materials (B8Fe)400S, (B8Fe)450S, (B8Fe)500S and (B8Fe)600S.

The D band intensity to G band ratio (ID/IG) is high (approximately 0.9) for all the materials spectra, which were also verified on other studies.4141 Cuesta, A.; Dhamelincourt, P.; Laureyns, J.; Carbon 1994, 32, 1523. These results can be indicated that the materials have high degree of defects.

The FTIR spectra of sulfonated materials (Figure S6 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section) showed two bands at 1583 and 1688 cm-1 related to aromatic C=C bonds.4242 Del Río, J. C.; Gutiérrez, A.; Romero, J.; Martínez, M. J.; Martínez, A. T.; J. Anal. Appl. Pyrolysis 2001, 58-59, 425. Furthermore, for material (B8Fe)400S a broad band near 3026 cm-1 related to -OH stretching was observed. At 1143 and 1019 cm-1, two bands related to the symmetric and asymmetric stretching of O=S=O group indicate the presence of -SO3H groups.4343 Branca, C.; Giudicianni, P.; Di Blasi, C.; Ind. Eng. Chem. Res. 2003, 42, 3190. At temperatures higher than 400 ºC, a significant decrease on the bands intensity was observed, confirming the release of oxygenated compounds during carbonization.4444 Yu, H.; Niu, S.; Lu, C.; Li, J.; Yang, Y.; Fuel 2017, 208, 101. Besides that, decrease on the intensity bands relative to sulfonic groups was also verified.4444 Yu, H.; Niu, S.; Lu, C.; Li, J.; Yang, Y.; Fuel 2017, 208, 101.

The TG curves in air of the sample (B8Fe)400 showed an initial weight loss of 6% related to water, followed by 55% loss between 230-400 ºC related to carbon oxidation/organics decomposition (Figure S7 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section) leaving ca. 38% of iron oxide. On the other hand, the TG curve of the material (B8Fe)400S indicated a final iron oxide content of only 7% due to leaching caused by sulfuric acid treatment.

The materials (B8Fe)500, (B8Fe)500S, (B8Fe)600 and (B8Fe)600S showed similar TG curves (Figure S8 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section), i.e., mass losses between 300 and 430 ºC, concerning the oxidation of carbonaceous structures. In all curves, about 37 to 44% of the inorganic was observed, before and after the sulfonation process. It is probably related to iron phases which are protected and covered by coal and to ashes from the coal oxidation.4545 Wieczorek-Ciurowa, K.; Kozak, A. J.; J. Therm. Anal. Calorim. 1999, 58, 647. For materials (B8Fe)450 and (B8Fe)450S, the weight loss began near 260 ºC, indicating that materials are less stable, leading to a final weight of 30 and 25%, respectively. The higher weight loss for (B8Fe)450S could be related to iron leaching.

In order to analyze what occurred during material thermal decomposition, a TG-MS experiment (Figure 8) was performed monitoring the m/z signals 18, 28, 44 and 64 with materials (B8Fe)450 and (B8Fe)450S, in argon atmosphere. Both samples showed initial weight loss until 150 ºC due to water (m/z 18). Adsorbed CO2 was also released at ca. 100 ºC. After 150 up to ca. 700 ºC several signals related to CO2 were observed probably due to the decomposition of oxygen groups present in the carbon structure. The m/z signal 28 related to CO was observed between 600-700 ºC and is usually related to the decomposition of oxygen directly linked to the carbon structures.4646 Yu, M.; Zhong, C.; Zhang, Y.; Chen, Q.; Ao, X.; Lei, X.; Li, C.; J. Anal. Appl. Pyrolysis 2018, 134, 293.

Figure 8
TG and MS curves on argon atmosphere, heating rate of 10 ºC min-1 of materials: (a) (B8Fe)450; (b) (B8Fe)450S.

It was observed that sulfonation with H2SO4 caused slight changes in the TG-MS desorption profiles. However, the main difference is the presence of an m/z signal 64 between 250-400 ºC related to SO2 originated from HSO3- surface groups.4747 Hara, M.; Yoshida, T.; Takagaki, A.; Takata, T.; Kondo, J. N.; Hayashi, S.; Domen, K.; Angew. Chem., Int. Ed. 2004, 43, 2955.

The number of acid sites determined based on the total amount of sulfur indicated values of 1.56 mmol g-1 for the sample (B8Fe)400S and 1.19 mmol g-1 for (B8Fe)450S. On the other hand, potentiometric titration measurements (Figure S9 Supplementary Information Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file. , SI section) suggested much lower values of ca. 0.2 mmol g-1 for the sample (B8Fe)400S which strongly decreased for treatment at higher temperatures. Again, these results indicate that thermal treatments at 500 and 600 ºC led to the formation of a very stable carbon less susceptible to sulfonation.

Sulfonated biochar based on pine and starch presented 0.2-0.9 mmol g-1 of acid sites density.4848 Kastner, J. R.; Miller, J.; Geller, D. P.; Locklin, J.; Keith, L. H.; Johnson, T.; Catal. Today 2012, 190, 122. However, solid catalysts based on glucose,4949 Takagaki, A.; Toda, M.; Okamura, M.; Kondo, J. N.; Hayashi, S.; Domen, K.; Hara, M.; Catal. Today 2006, 116, 157. starch and cellulose,5050 Lou, W.-Y.; Zong, M.-H.; Duan, Z.-Q.; Bioresour. Technol. 2008, 99, 8752. presented density of acid sites higher than 1 mmol g-1, which is explained by their large area, pore volume and pore size. According to studies,5050 Lou, W.-Y.; Zong, M.-H.; Duan, Z.-Q.; Bioresour. Technol. 2008, 99, 8752. materials with larger areas and pore size make the reactants more accessible to SO3H groups. Studies4646 Yu, M.; Zhong, C.; Zhang, Y.; Chen, Q.; Ao, X.; Lei, X.; Li, C.; J. Anal. Appl. Pyrolysis 2018, 134, 293.,4949 Takagaki, A.; Toda, M.; Okamura, M.; Kondo, J. N.; Hayashi, S.; Domen, K.; Hara, M.; Catal. Today 2006, 116, 157. showed that lower acid densities can be attributed to higher cross linking and degree of polymerization at higher temperatures, reducing sulfonation efficiency.

The materials were characterized by adsorption/desorption using Brunauer-Emmett-Teller (BET) method and the surface areas were similar, e.g., 3, 2, 2 and 3 m2 g-1 for (B8Fe)400S, (B8Fe)450S, (B8Fe)500S and (B8Fe)600S, respectively. These low values can be attributed to the presence of a great amount of organic compounds, which could be released at higher temperatures.5151 Araujo, R. O.; Chaar, J. S.; Queiroz, L. S.; da Rocha Filho, G. N.; da Costa, C.; da Silva, E. F.; Landers, G. C. T.; Costa, R.; Costa, M. J. F.; Gonçalves, A. A. S.; de Souza, L. K. C.; Energy Convers. Manage. 2019, 196, 821.

52 Neeli, S. T.; Ramsurn, H.; Carbon 2018, 134, 480.
-5353 Kumar, U.; Maroufi, S.; Rajarao, R.; Mayyas, M.; Mansuri, I.; Joshi, R. K.; Sahajwalla, V.; J. Cleaner Prod. 2017, 158, 218.

Catalytic tests

Esterification reactions of oleic acid in the presence of methanol catalyzed by the produced materials were studied (Figure 9). The use of the same quantity of catalyst, e.g., 10 wt.%, 1:30 oleic acid:methanol, for 6 h at 100 ºC, showed different conversions. As expected, when the material (B8Fe)400S was used, the reaction occurred rapidly, reaching the equilibrium in 2 h. The conversion after 6 h was 99%. In the other hand, when the material (B8Fe)450S was used, the reaction gradually reached the equilibrium after 5 h, with a conversion of 90%.5454 Fraga, A. C.; Quitete, C. P. B.; Ximenes, V. L.; Sousa-Aguiar, E. F.; Fonseca, I. M.; Rego, A. M. B.; J. Mol. Catal. A: Chem. 2016, 422, 248. When other materials were assessed, (B8Fe)500S and (B8Fe)600S, no significant catalytic effect was observed, what corroborates potentiometric titration analysis. The insignificant conversion was also observed for blank reaction and for material (B8Fe)450 (not showed).

Figure 9
Oleic acid conversion versus time on esterification reaction: effect of the catalyst nature. Reaction conditions: 10 wt.% catalyst, 1:30 oleic acid:methanol, 100 ºC.

The difference on materials catalytic activity is strictly related to pyrolysis temperature. At low temperatures (400-450 ºC), the materials were partially carbonized, which allowed the organic groups to react with H2SO4. The rise of temperature produced a well-structured carbon which present low concentration of surface acid sites,4848 Kastner, J. R.; Miller, J.; Geller, D. P.; Locklin, J.; Keith, L. H.; Johnson, T.; Catal. Today 2012, 190, 122. what was confirmed by CHNS and potentiometric titration. It is also important to highlight that iron played no significant role on the material acidity, once the material (B8Fe)450 showed no catalytic activity.

In fact, esterification reactions using wood-based activate carbon catalyst in similar conditions (1:10 oleic acid methanol, 10 wt.% at 100 ºC, 3 h) had also a significant esterification activity, being the biochars synthesized at lower temperatures the most active catalysts.4848 Kastner, J. R.; Miller, J.; Geller, D. P.; Locklin, J.; Keith, L. H.; Johnson, T.; Catal. Today 2012, 190, 122. The more drastic conditions used in this work can be explained due to lower acid sites. In fact, herein, the materials were sulfonated for 2 h at 120 ºC, while in the previous study,4848 Kastner, J. R.; Miller, J.; Geller, D. P.; Locklin, J.; Keith, L. H.; Johnson, T.; Catal. Today 2012, 190, 122. the materials were in contact with H2SO4 for 12-18 h.

More detailed investigation was carried out with the magnetic catalyst (B8Fe)450S, in which the temperature effect was studied. The temperature rises from 60 to 100 ºC produced a gradual increase in the yield of esters from 56 to 90% (Figure 10). This effect is likely kinetic but also related to the higher solubility of methanol in oleic acid,5555 Saravanan, K.; Tyagi, B.; Shukla, R. S.; Bajaj, H. C.; Appl. Catal., B 2015, 172-173, 108. a high temperature often obtains satisfactory yields, as showed in a study5656 Li, J.; Liang, X.; Energy Convers. Manage. 2017, 141, 126. with acid magnetic catalyst, in which the yield increased from 78.9 to 98.9% when the temperature rose from 50 to 70 ºC.

Figure 10
Oleic acid conversion versus time on esterification reaction: effect of the reaction temperature. Reaction conditions: 10% catalyst (B8Fe)450S, 1:30 oleic acid:methanol, 6 h reaction, at 60, 80 and 100 ºC.

After the reaction, the catalyst (B8Fe)450S was separated from the products using a magnet, washed 2 times with methanol and reuse reactions were performed. After 2 reuses a decrease on the conversion to 30% was observed (Figure 11). Previous works4444 Yu, H.; Niu, S.; Lu, C.; Li, J.; Yang, Y.; Fuel 2017, 208, 101.,4545 Wieczorek-Ciurowa, K.; Kozak, A. J.; J. Therm. Anal. Calorim. 1999, 58, 647. suggested that deactivation processes are likely related to -SO3H groups leaching and due to organic molecules, that poison the material active sites. Unlike other magnetic catalysts, which could be reused for 6 times,1717 Li, X.; Shi, J.; Wang, Z.; Duan, X.; Chen, G.; Guan, Q.; Li, X.; Lei, T.; BioResources 2017, 12, 7525.,5656 Li, J.; Liang, X.; Energy Convers. Manage. 2017, 141, 126. in this study the material did not present high stability, that could also be related to the synthesis method used.

Figure 11
Oleic acid conversion versus number of uses on esterification reaction: recycling reactions of catalyst (B8Fe)450S. Reaction conditions: 10.0 wt.% catalyst, 1:30 oleic acid:methanol, 100 ºC, 6 h.

In fact, leaching processes were also performed by leaving the catalyst in contact with methanol for 30 min, after that, methanol was added to a flask with oleic acid. It can be seen that about 32% of the catalyst active sites were leached to the reaction medium.

The catalytic tests showed that sulfonated materials were active to esterification reactions, with conversions of 90%, however, the legislation requires a conversion of > 96%. In that way, it would be necessary to increase the oleic acid:methanol ratio to move the reaction towards products formation or increase the number of acidic sites, adding more catalyst to the reaction medium.

The mechanism involves the proton of SO3H groups, which works as a Brønsted acid. Furthermore, at temperatures higher than 450 ºC, the materials were magnetic, which facilitates the material removal from reaction medium. Reuse tests of (B8Fe)450S demonstrated that after 3 uses the conversion decreases to 30%, probably because of leaching or methylation of SO3H. Studies3636 Zhou, Y.; Niu, S.; Li, J.; Energy Convers. Manage. 2016, 114, 188. performed with a carbon based on bamboo catalyst showed that after 2 h of reaction, using 6 wt.% of catalyst, 1:5 oleic acid:ethanol at 90 ºC, the conversion was 97%. However, after the 5th use, the conversion decrease to 27.84%.

The results obtained in this work, e.g., SEM, TEM, TG, Mössbauer and XRD, indicated that Fe3+ can be dispersed in bio-oil and upon thermal treatment at temperatures higher than 400 ºC is reduced to form magnetite Fe3O4 nanoparticles:

(2) Fe bio oil 3 + Fe 3 O 4 / carbon matrix

During decomposition the presence of oxidizing molecules, e.g., H2O and CO2, or when exposed to air, part of these Fe3O4 nanoparticles are oxidized to another magnetic phase maghemite γ-Fe2O3.

(3) Fe 3 O 4 / carbon matrix γ Fe 2 O 3 / carbon matrix

These materials can be sulfonated by a simple reaction with concentrated H2SO4. The most efficient sulfonation was observed for the material obtained at 400 ºC. However, sulfonation of the material (B8Fe)400 led to a strong Fe leaching indicating that the metal was exposed and not encapsulated by the carbon matrix. As a result of this leaching the material was not magnetic. On the other hand, the material obtained at 450 ºC, (B8Fe)450, showed good results for the sulfonation process but no significant Fe leaching suggesting that the Fe oxide particles are protected/encapsulated in the carbon matrix. Thermal treatment at 500 and 600 ºC produced carbons very resistant to sulfonation. These results are summarized schematically in Figure 12.

Figure 12
Scheme of carbonization and sulfonation processes of Fe3+/bio-oil.

The material (B8Fe)450S showed good results for the esterification of oleic acid reaching 90% of conversion, similar to the most efficient catalysts described in the literature,5151 Araujo, R. O.; Chaar, J. S.; Queiroz, L. S.; da Rocha Filho, G. N.; da Costa, C.; da Silva, E. F.; Landers, G. C. T.; Costa, R.; Costa, M. J. F.; Gonçalves, A. A. S.; de Souza, L. K. C.; Energy Convers. Manage. 2019, 196, 821. however, more studies should improve the material stability in the reaction medium.

Conclusions

The organic matrix bio-oil rich in oxygen functionalities can be used to efficiently dissolve/disperse Fe3+. Upon thermal treatment the bio-oil decomposition led to the formation of a carbonaceous matrix and the partial reduction of Fe3+ to Fe2+ to form magnetic nanoparticles of Fe3O4 and maghemite γ-Fe2O3. This composite based on Fe magnetic nanoparticles dispersed/encapsulated in a carbon matrix has several potential applications in adsorption, catalysis and materials science. The effect of pyrolysis temperature was important, once as temperature increases, the material becomes less reactive due to sulfuric acid. These magnetic carbons were used as acid catalyst in different reactions, such as esterification of oleic acid and methanol, which reached 90% of conversion. Reuse reactions were also performed and after 2nd use, the conversion decreased to 30%, being necessary other studies to improve the catalyst stability in reaction medium.

Supplementary Information

Supplementary data are available free of charge at http://jbcs.sbq.org.br as PDF file.

Acknowledgments

The authors acknowledge the UFMG microscopy center, INCT Midas, CNPQ, CAPES and FAPEMIG.

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Publication Dates

  • Publication in this collection
    27 July 2020
  • Date of issue
    Aug 2020

History

  • Received
    22 Jan 2020
  • Accepted
    30 Mar 2020
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