Format And Type Fonts CHEMICAL ENGINEERING TRANSACTIONS VOL. 45, 2015 A publication of The Italian Association of Chemical Engineering www.aidic.it/cet Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Sharifah Rafidah Wan Alwi, Jun Yow Yong, Xia Liu Copyright © 2015, AIDIC Servizi S.r.l., ISBN 978-88-95608-36-5; ISSN 2283-9216 DOI: 10.3303/CET1545115 Please cite this article as: Chokcharoenchai B., Jitkarnka S., 2015, Co3o4/γ-al2o3 as a catalyst for green chemicals production via catalytic dehydration of bio-ethanol, Chemical Engineering Transactions, 45, 685-690 DOI:10.3303/CET1545115 685 Co3O4/γ-Al2O3 as a Catalyst for Green Chemicals Production via Catalytic Dehydration of Bio-Ethanol Bandith Chokcharoenchai, Sirirat Jitkarnka a a The Petroleum and Petrochemical College Chulalongkorn University, Dep. Petrochemical Technology, Chula Soi 12, Phayathai Rd., Wangmai, Pathumwan, Bangkok, 10330, Thailand. sirirat.j@chula.ac.th The catalytic dehydration of bio-ethanol is an effective route to transform alcohol to valuable hydrocarbons and chemicals such as olefins and aromatics. There are a variety of reactions that involve, after ethylene is formed as an intermediate, such as oligomerization, aromatization, and alkylation. Products can be, for examples, butylene, benzene, derivatives of benzene, and oxygenates. In this research, cobalt oxide- promoted alumina (Co3O4/-Al2O3) was examined, aiming to investigate the production of high valuable oxygenate compounds and hydrocarbons in bio-ethanol dehydration. The amount of Co loading was fixed at 5.0 %. The catalysts were characterized using SAA, XRD, and XPS, and tested in a fixed-bed reactor under atmospheric pressure at 500 °C for 8 h. Additionally, the gaseous products were analyzed using an on-line GC, and the oil products were analyzed using GCxGC-MS/TOF. With oxide loading, the amount of C9 and C10 + aromatics increased in the oil as ethylene decreased in the gas. The major components in the oil are oxygenate compounds, which consisted of ketones and alcohols such as 2-butanone, 2-pentanone, and phenol, together with hydrocarbons such as benzene, and a trace amount of p-xylene, ethyl-benzene, and naphthalene. The ratio of oxygenates and hydrocarbons was 19:1. Furthermore, XPS result indicated that Co3O4 mainly existed on -Al2O3, and after use, some of Co3O4 transformed to CoO. 1. Introduction High cost solvents such as pentanones have increasingly been used for medical treatment, preparation of pharmaceuticals, and pesticides, and other industrial applications. Currently, available processes for producing pentanones are, for example, liquid phase oxidation of 2-pentanol and hexanoic acid, but gave high amounts of hazardous and toxic reagents that affect to the environment (He et al. 2005). Moreover, the available processes are not only un-environmental friendly, but also composed of multi-steps that involved basic-catalyzed condensation to aldor species, followed by dehydrogenation of the intermediates on an acid catalyst, and then the last is selective hydrogenation, yielding unsaturated carbonyl compounds and generating a large amount of wastes. In the last decade, several types of catalyst were employed for pentanones production. For example, He et al. (2005) employed Pd/MnOx-ZrO2-ZnO catalyst for one step- synthesis of 2-pentanone from ethanol. Alternatively, the catalytic dehydration of bio-ethanol is one of the available processes, which has potential to synthesize a high cost solvent, like 2-pentanone. The advantages of bio-ethanol dehydration are no waste generation, low pollution, greener, and environmental friendly route. Additionally, it not only has a lot of advantages, but also gives the hydrocarbons in gasoline range as co-products. As aforementioned, a simple catalyst such as cobalt oxide-modified alumina is an interesting catalyst to produce high cost solvent from the catalytic dehydration of bio-ethanol. Since cobalt oxide was employed in methanol oxidation (Zafeiratos et al., 2010) Therefore, the aim of this work was to examine the formation of oxygenate compounds and hydrocarbons in the catalytic dehydration of bio-ethanol using Co3O4/Al2O3 catalyst. Additionally, the catalyst was characterized using surface area analyzer (SAA), X-ray diffraction (XRD), and X-ray-Photoelectron Spectroscopy (XPS). 686 2. Experimental 2.1 Catalyst Preparation -Al2O3 (-Alumina) used in this work was supplied form Sigma Aldrich, Singapore. Cobalt (II) nitrate hexahydrate was used as the cobalt precursor. A metal solution of cobalt nitrate was loaded on the support using incipient wetness impregnation technique until the amount of 5.0 % Co loading was achieved. After impregnation, the wet catalyst was dried at 110 °C overnight, and then calcined until 600 °C, 10 °C/min and held for 3 h. The calcined catalyst was pelletized, crushed, and sieved to 20-40 mesh particles. 2.2 Catalytic Testing The catalytic dehydration of bio-ethanol was performed in a continuous isothermal fixed-bed U-tube reactor controlled at 500 °C under atmospheric pressure for 8 h. The high purity grade bio-ethanol (99.5 %) was fed by a syringe pump with carrier gas, helium, through the catalyst bed. The gaseous product was passed through an online-GC, and the liquid condensed in a cooling unit was collected, and the oil was extracted from the liquid product by using carbon disulfide. 2.3 Product Analysis The gaseous products were analyzed by using a GC-TCD (Agilent 6890N) to determine the gas composition, and GC-FID (Agilent 6890N) was used to determine the bio-ethanol and oxygenate contents. The extracted oils were analyzed by using Gas Chromatography (Agilent technology 7890) with Time-of- Fight Mass Spectrometer (LECO, Pegasus® 4D TOF/MS) equipped with the 1 st GC column was a non- polar Rtx®-5sil MS (30 m × 0.25 mm × 0.25 µm), and the 2 nd GC column was an Rxi®-17 MS column (1.790 m × 0.1 mm ID ×0.1 µm) to determine the composition. 2.4 Catalyst Characterization The Brunauer-Emmett-Teller (BET) technique was used to determine the specific surface area, total pore volume, and pore size of catalysts using Thermo Finnigan/Sorptomatic 1990 surface area analyzer. The pore size distribution was calculated using BJH method. The X-ray diffraction of catalysts was determined using Rigagu SmartLab® in BB/Dtex mode with CuKα radiation. The machine collected the data from 10 o - 80 o (2θ) at 5 o /min with the increment of 0.01 o . X-ray Photoelectron Spectroscopy (XPS) spectra were obtained using a AXIS ULTRA DLD . The system was equipped with a monochromatic Al x-ray source and hemispherical analyzer. The spectrometer was operated with the pass energy of 160 and 40 eV for wide and narrow scan. All peaks were calibrated from referring C 1s spectra located at 284.7 eV. 3. Results and Discussion 3.1 Catalyst Characterization The BET surface area and pore volume decrease when cobalt is loaded on alumina as shown in Table 1. The decreases in surface area and pore volume of a catalyst, prepared by using incipient wetness impregnation technique, suggest that cobalt solution was adsorbed deeply in the pores of alumina, resulting in the formation of cobalt oxide particle inside the pores. The XRD patterns are shown in Figure 1 to confirm the characteristic of alumina and the existing of cobalt oxide on alumina surface. The peaks located at 2θ = 37.34 o , 45.65 o and 67.51 o are the characteristics of alumina (Liu et al., 2012), and the peaks detected at 2θ = 31.37 o , 45.41 o , 59.37 o and 65.22 o correspond to the oxide form of Co3O4 (Batista et al., 2003). These results can confirm the characteristics of gamma phase of the alumina, and are the basic evidence supporting the chemical state of cobalt oxide catalyst. Additionally, in order to further confirm the chemical state of the cobalt oxide, X-ray Photoelectron Spectroscopy was employed, and the results are shown in Figure 2(a) and (b) for fresh and spent catalyst. The XPS spectrum of fresh catalyst display that the Co 2p3/2 binding energies at 779.4 and 781.5 eV are assigned to Co3O4 and CoO on the γ-alumina surface (Biesinger et al., 2011), and accounted for 69.2 % and 30.8 %. Moreover, there is a characteristic satellite peak of Co3O4 located at 786.5 eV (Khassin et al., 2012). The XPS spectrum of the spent catalyst is illustrated in Figure 2(b). The Co 2p3/2 binding energy at 781.8 eV is assigned to CoO (Biesinger et al., 2011), and the two-overlapped characteristic satellite peaks of CoO are also observed at 786.3 and 790.9 eV (Khassin et al., 2012). Furthermore, from the XPS study, it is observed that there is a change of binding energy taking place after the catalytic testing. This implies that Co3O4 is entirely reduced to CoO during the reaction testing. 687 Table 1: Physical properties of alumina and cobalt-promoted alumina Sample Surface area(m 3 /g) a Pore volume(cm 3 /g) a Pore diameter(nm) b Al2O3 Co3O4/Al2O3 206.4 171.8 0.1792 0.1406 47.58 45.34 a determined using BET method b determined using B.J.H method Figure 1: XRD pattern of alumina (bottom) and Cobalt-promoted alumina (top). Figure 2: Co 2p3/2 XPS spectra of (a) fresh and (b) spent 5 wt% cobalt oxide-promoted γ-alumina. 3.2 Effect of alumina on the catalytic dehydration of bio-ethanol It was found that -alumina gave ethanol conversion 98.0 %. Moreover, with the use of -alumina yielded ethylene as the major product in gas. Additionally, the composition of extracted oils is shown in Table 2. The results shows that extracted oil contains mainly oxygenate compounds. The major of oxygenate Co3O4 Co 2+ Co 2+ satellite (B) (A) 688 compounds are alcohols (i.e. phenol), with ketones (i.e. 2-butanone, 2-pentanone, 2-hexanone, and 3- hexanone) as co-products. For hydrocarbons, benzene, toluene, mixed-xylenes, C9, and C10 + aromatics are traces of components. Table 1: Gaseous product distribution from bio-ethanol dehydration Concentration (wt%) Sample CH4 C2H4 C2H6 C3H6 C3H8 C4H8 C4H10 CO2 Non-catalyst 0.0 99.1 0.6 0.2 0.0 0.1 0.0 0.0 Al2O3 Co3O4/Al2O3 0.0 3.2 96.0 81.3 0.5 1.2 1.0 2.2 0.0 0.0 0.5 0.7 0.0 0.0 2.1 11.2 Data were taken at the eight hour of time-on-stream 3.3 Effect of Co3O4 on γ-Al2O3 In the case of Co3O4-promoted -alumina, it can be observed that methane, ethane, propylene, and butylene are insignificantly enhanced, but ethylene is suppressed in the gaseous products. Moreover, as shown in Table 2, the oxygenate compounds and hydrocarbons are accounted for 95.5 % and 4.5 % in oil. As compared to parent alumina, Co3O4-promoted catalyst enhanced oxygenates rather than hydrocarbon production. The composition of oxygenate compounds were identified using GCxGC-TOF/MS, and it was found that oxygenate compounds are composed of alcohols, ketones, and a trace of esters. Figure 3: Reaction pathways of ethanol to 2-pentanone (He et al., 2005) 689 The majority of phenol products is 3-methyl-phenol as shown in Figure 4(a). It consists of almost 50 % of all phenol compounds. The total content of all phenol and its derivatives in oxygenate products is 78.7 %. In addition, 2-pentanone is found as the main product in ketones, and it holds almost 80 % of all ketone compounds. The formation of oxygenate compounds, especially 2-pentanone, from ethanol was explained by He et al. (2005). When ethanol is fed and passed over a metal oxide catalyst, hydrogen at hydroxyl group of ethanol is firstly adsorbed on oxygen vacancies, and then ethoxy species are formed. Moreover, the ethoxy species can undergo dehydrogenation, via α-H abstraction, and subsequent electron transfer to metal cation, yielding acetaldehyde (Idriss et al. 2000). Additionally, acetaldehyde itself can undergo condensation reaction to form aldor species which are thermodynamically transformed to acetone, and yield formaldehyde as a co-product. Likewise, acetaldehyde and acetone can react to one another, forming 2-pentanone via acetaldehyde-acetone condensation and hydrogenation with water as a by- product. High molecular weight pentanones can be formed when 2-pentanone further undergo condensation with other acetones, as shown in Figure 3. Table 2: Liquid product distribution from bio-ethanol dehydration Sample Non-catalyst Al2O3 Co3O4/Al2O3 Product distribution (wt %) Oxygenates 89.0 92.1 95.5 Non-aromatics 1.44 0.60 0.00 Benzene 4.28 5.18 2.08 Toluene 0.31 0.64 0.38 p-Xylene 0.20 0.24 0.30 o-Xylene 0.02 0.16 0.09 m-Xylene 0.03 0.22 0.09 Ethylbenzene 0.12 0.37 0.10 C9 aromatics 0.10 0.07 0.45 C10 + aromatics 4.53 0.38 1.04 Data were taken at the eight hour of time-on-stream Additionally, the formation of oxygenate compounds is occurred by ethanol adsorbed at the vacancy of metal oxide surface, leading to ethoxy species formation. Zafeiratos et al. (2010) found that cobalt oxide could be reduced by methanol, forming carbon dioxide and water as by-product. This implies that Co3O4 is reduced by ethanol during the catalytic testing, forming ethoxy species that adsorbed on the metal oxide surface. The carbon dioxide formation in the gaseous products supports the explanation. (a) (b) Figure 4: Compositions of Phenols (a) and Ketones (b) found in oxygenate compounds (wt %) from using Co3O4/Al2O3. In addition, the hydrocarbon products obtained from using Co3O4 as a promoter are slightly suppressed as compared to the parent alumina. The hydrocarbons are composed of benzene, toluene, mixed-xylenes C9, C10 + -aromatics, and a trace of non-aromatics. Among the hydrocarbons, C9 and C10 + -aromatics are insignificantly enhanced while benzene, toluene, and mixed-xylenes are suppressed; indicating that these 690 hydrocarbons are further converted to C9 and C10 + -aromatics inside the pores of alumina. Furthermore, as seen in Table 1, ethylene that decreases in the gaseous products is believed to be an important intermediate to directly transform to propylene and then to aromatics. 4. Conclusions Cobalt oxide-promoted alumina was examined in the catalytic dehydration of bio-ethanol in order to examine the formation of oxygenates and hydrocarbons. From our study, it was revealed that cobalt oxide can be used to produce 2-pentanone, which is used in many applications in industry and has high value. The obtained oxygenate compounds were composed of phenols, ketones, and a trace of esters. Moreover, the hydrocarbons were composed of non-aromatics, benzene, toluene, mixed-xylenes, C9, and C10 + - aromatics. Additionally, XPS analysis revealed that the fresh cobalt oxide-promoted catalyst was not pure Co3O4 at initial, but contained a mixture of CoO and Co3O4. However, Co3O4 was entirely reduced to CoO after use, during the formation of ethoxy species in the catalytic dehydration of bio-ethanol. References Batista M.S., Santos Rudye K.S., Assaf Elisabete M., Assaf José M., Ticianelli Edson A., 2003, Characterization of the activity and stability of supported cobalt catalysts for the steam reforming of ethanol, Journal of Power Sources, 124, 99-103. Biesinger M.C., Payne B.P., Grosvenor A.P., Lau L.W.M., Gerson A.R., Smart R. St C., ,2011, Resolving surface chemical states in XPS analysis of first row transition metals, oxides and hydroxides: Cr, Mn, Fe, Co and Ni, Applied Surface Science, 257, 2717-2730. He D., Ding Y., Chen W., Lu Y., Luo H.. 2005. One-step synthesis of 2-pentanone from ethanol over K- Pd/MnOx-ZrO2-ZnO catalyst. Journal of Molecular Catalysis A: Chemical, 226: 89-92 Idriss, H., Seebauer E.G., 2000. Reactions of ethanol over metal oxides. Journal of Molecular Catalysis A: Chemical, 152, 201-212. Khassin A.A., Yurieva Tamara M., Kaichev V.V., Bukhtiyarov V.I., Budneva A.A., Paukshtis E.A., Parmon V.N., 2001, Metal–support interactions in cobalt-aluminum co-precipitated catalysts: XPS and CO adsorption studies, Journal of Molecular Catalysis A: Chemical, 175(1–2), 189-204. Liu C., Li J., Zhang Y., Chen S., Zhu J., Liew K., 2012, Fischer–Tropsch synthesis over cobalt catalysts supported on nanostructured alumina with various morphologies, Journal of Molecular Catalysis A: Chemical, 363–364, 335-342. Zafeiratos S., Dintzer T., Teschner D., Blume R., Hävecker M., Knop-Gericke A., Schlögl R., 2010, Methanol oxidation over model cobalt catalysts: Influence of the cobalt oxidation state on the reactivity, Journal of Catalysis, 269, 309-317.