Abstracts

Introduction

There are many new challenges ahead in the field of heterogeneous catalysis in terms of the chemical process and reactions to be promoted by the use of nano catalysts. As an example, the conversion of methane, which is usually performed by different direct or indirectly routes, require specific catalysts. Non oxidative methane process is relevant for investigating the different possibilities of methane activation and posterior interaction between the molecules or intermediates and the surface of the catalyst and thus, for understanding the reaction mechanisms governing the formation of C–C bonding, the reaction condition influencing the formation of these ligands, as well as, the product distribution, which are of fundamental interest, not only for the non-oxidative coupling but also on processes related to the methane transformation.

Martins et al.¹1 Martins, R. L.; Baldanza, M. A. S.; Souza, M. M. V. M.; Schmal, M.; Appl. Catal., A2007, 318, 207. reported the role of different supports (silica, alumina and zirconia) on the non-oxidative conversion of methane on Pt loaded catalysts, with or without the presence of MoO₃. Moya et al.²2 Moya, S. F.; Martins, R. L.; Ota, A.; Kunkes, E. L.; Behrens, M.; Schmal, M.; Appl. Catal., A2012, 411-412, 105. studied the non-oxidative methane coupling on nanostructured supported palladium catalysts and Antje Ota et al.³3 Ota, A.; Kunkes, E. L.; Krohnert, J.; Schmal, M.; Behrens, M.; Appl. Catal., A2013, 452, 203. studied the particle size effect in methane activation over supported palladium nanoparticles. Moya et al.⁴4 Moya, S. F.; Martins, R. L.; Schmal, M.; Appl. Catal., A2011, 396, 159. studied the monodispersed and nanostructrured Ni/SiO₂ catalyst for the non-oxidative methane activation.

Also, direct cracking of methane on supported Ni catalyst were reported in the literature.⁵5 Muradov, N. Z.; Energy Fuels1998, 12, 41.

6 Poirier, M. G.; Sapundzhiev, C.; Int. J. Hydrogen Energy1997, 22, 429.^-77 Choudhary, T. V.; Goodman, D. W.; Catal. Lett.1999, 59, 93.

This process is moderately endothermic, with little gain in energy needed per mol of H₂ production and the reaction is thermodynamically favored at higher temperatures. The H₂/CH₄ is low during methane cracking with carbon structure formation. Direct cracking forms nanofilament carbons with graphite planes as precursor. On supported nickel catalysts, hydrocarbons are decomposed at the interface gas-metal followed by dissolution and carbon diffusion through the metal particles. These carbons then precipitate at the interface, dragging out the metallic particle of the support with the formation of carbon filaments, as observed by Aiello et al.⁸8 Aiello, R.; Fiscus, J. E.; zur Loye, H-C.; Amiridis, M. D.; Appl. Catal., A2000, 192, 227. for the Ni/SiO₂ and Albertonet al.⁹9 Alberton, A. L.; Souza, M. M. V. M.; Schmal, M.; Appl. Catal., B2011, 103(3-4), 326. for the Ni/Al₂O₃ catalysts. Methane cracking for hydrogen production was studied over Ni/Ni alloy catalysts supported on pure or WO₃/MoO_3– modified zirconias by Martinset al..¹⁰10 Martins, R. L.; Baldanza, M. A. S.; Alberton, A. L.; Vasconcelos, S. M.; Schmal, M.; Appl. Catal., B2011, 103, 326. On unsupported Ni nanoparticles there are formation of carbon nanotubes.

Metallic catalysts, in the catalysis concept, are usually prepared by the deposition of small nanometer-sized particles (< 20 nm) of an active phase, a metal, finely dispersed on a cheaper high-surface-area support, commonly a porous oxide. The dispersion is used mainly to improve the surface-to-volume ratio of the active phase. Additionally, this practice also leads to a better distribution of reaction heat, better poison resistance, and improve catalyst life by preventing metal sintering. Supported catalysts are prepared by impregnation of the porous solid with a precursor metal salt followed by oxidation and reduction pretreatments. However, that practice leads to the formation of nanoparticles with a wide range of sizes and shapes displaying a distribution of surface sites capable of promoting many different reactions. No molecular control on the nature of the active sites is expected, and only limited control on the selectivity of reactions can be achieved. Controlling the size of the nanoparticles used for catalysis can lead to huge changes in catalytic behavior. The importance of nanoparticles and nanostructure to the performance of catalysts has stimulated wide efforts to develop methods for their synthesis and characterization, making this area of study an integral part of nanoscience.¹¹11 Bell, A. T.; Science2003, 299, 1688. Fortunately, metal nanoparticles can now be made with quite narrow size distributions by using, beside others, colloidal¹²12 Grass, M. E.; Yue, Y.; Habas, S. E.; Rioux, R. M.; Teall, C. I.; Yang, P.; Somorjai, G. A.; J. Phys. Chem. C2008, 112, 4797. or dendrimer¹³13 Albiter, M. A.; Zaera, F.; Appl. Catal., A2011, 391, 386. based chemistry. The morphology of these materials depends on the syntheses conditions, and has been described by different authors as nanotowers, nanocone, nanobottle, nanoflowers, nanoarrows, nanorod, nanowires and so on. The challenge is to disperse the colloidal nanoparticles on high-surface area supports and to activate them without losing the original size and shape distribution. As a matter of fact, the control of the morphology of the nanoparticles, perhaps, seems to be more important than monitoring the performance of catalysts by controlling the size of the nanoparticles of the active phase. It has been known that some catalytic processes are structure sensitive, meaning that their activity or selectivity changes significantly with the method used for the catalyst preparation.

In this work, we present methane activation on Ni nanoparticles with different morphologies synthesized by different methods for the methane activation and characterized before and after activation of methane.

Experimental

Preparation of catalysts

Ni catalysts with 25 wt. % of NiO were prepared by incipient wetness impregnation of Ni(NO₃)₂.6H₂O, using as ZrO₂ precursor the Zr(OH)₄ (MEL Chemical). Usually zirconia, obtained by calcination of Zr(OH)₄ at 923 K, involves two phases: stable monoclinic zirconia (M) and metastable tetragonal zirconia (T). The zirconia obtained by calcination of pure Zr(OH)₄ at 923 K for 3 h is mostly monoclinic, while Ni modified zirconias (where Ni content is equal or greater than 20 wt. %) are predominantly tetragonal in structure.¹⁰10 Martins, R. L.; Baldanza, M. A. S.; Alberton, A. L.; Vasconcelos, S. M.; Schmal, M.; Appl. Catal., B2011, 103, 326. After drying at 373 K for 24 h, the catalyst was calcined in the presence of synthetic air at 923 K for 3 h, at a ramping rate of 1 K min^–1.

The NiO with controlled crystallite sizes were prepared by three different methods.

(i) Precipitation of nickel hydroxide with sodium carbonate precursor salts dissolved in ethylene glycol (EG) (NiEG) according to Li et al. :¹⁴14 Li, Y.; Zhang, B.; Xie, X.; Liu, J.; Xu, Y.; Shen, W.; J. Catal.2006, 238, 412. Ni(NO₃)₂.6H₂O was dissolved in ethylene glycol (0.05 mol in 150 mL of EG), heated gradually at 393 K under stirring and kept at this temperature for 30 min, followed by drop wise addition of a solution of 500 mL of 0.2 mol L^–1 of Na₂CO₃, aged for 1 h at 393 K, filtered, washed with distilled-deionized water and then dried at 373 K for 16 h. The resulting sample was calcined at 673 K for 4 h flowing synthetic air at 50 mL min^–1.

(ii) Precipitation of nickel dimethylglyoxyme as precursor (NiDMG) according to Ni et al. :¹⁵15 Ni, X.; Zhao, Q.; Zhou, F.; Zheng, H.; Cheng, J.; Li, B.; J. Cryst. Growth2006, 289, 299. 3 g of Ni(NO₃)₂.6H₂O was dissolved in 650 mL of distilled-deionized water. A solution of 334 mL of ethanol containing 1% of dimethylglyoxyme was added dropwise to the solution with the formation of a red precursor of Ni(DMG)₂. After centrifugation and washing with distilled-deionized water, the precipitated solid was dried at 373 K for 16 h and calcined at 673 K for 4 h under atmospheric air and heating rate of 3 K min^–1.

(iii) NiO was obtained after hydrotreatment and calcination of β-Ni(OH)₂ precursor (NiHT) according to Zhuet al. :¹⁶16 Zhu, L. P.; Liao, G. H.; Yang, Y.; Xiao, H. M.; Wang, J. F.; Fu, S. Y.; Nanoscale Res. Lett.2009, 4, 550. about 1 mmol of Ni(CH₃COO)₂.4H₂O was dissolved in 5 mL distilled-deionized water followed by addition of 15 mL ethanol and 5 mL of CO(NH₂)₂, under strong stirring. Then, adding 2 mL of NH₄OH (35% v/v) drop by drop, resulting a strong blue solution with the formation of a complex [Ni (NH₃)₆²⁺]. This solution was transferred to an autoclave, coated by Teflon and heated in a furnace at 120 ºC for 12 h. After cooling, the resulted precipitate was centrifuged and washed several times with distilled-deionized water, dried at 50 ºC for 8 h, forming the (β-Ni(OH)₂) precipitate. NiO was formed after calcination at 673 K for 4 h and a heating rate of 3 K min^–1.

Characterizations

The X-ray powder diffraction measurements were performed in a Rigaku Miniflex diffractometer operated at 30 kV and 40 mA, using the graphite monochromated Cu Kα radiation. The diffractograms were recorded over 2θ values ranging from 10 to 90º, with a scanning rate of 2 s step^–1 and 0.02 step sizes.

Sample images were recorded in a field emission gun scanning electron microscope (FEG-SEM) (FEI Company) model QUANTA 400, equipped with an energy dispersive X-ray spectroscopy (EDS) system without treatment. The samples were first dispersed in isopropyl alcohol, using ultrasonic bath for 10 min, then a small amount of this solution was dropped on a copper grid and dried before analysis.

Catalytic tests

Temperature programmed surface reaction (TPSR) experiments were carried out, by using pure methane at 50 cm³3 Ota, A.; Kunkes, E. L.; Krohnert, J.; Schmal, M.; Behrens, M.; Appl. Catal., A2013, 452, 203. min^–1, varying the temperature from 298 to 773 K, at a heating rate of 10 K min^–1. The masses of catalyst used were 25 mg for the unsupported and 100 mg for the supported catalysts, respectively. TPSR experiments were performed in a Micromeritics TPD/TPR 2900 equipment coupled to a Balzers quadrupole mass spectrometer as detector. The gases used were CH₄ (99.95% purity), He (99.995 purity).

Activity tests were conducted at atmospheric pressure in a Pyrex micro reactor of fixed bed using 100 mg of the supported and 25 mg of the unsupported Ni catalysts, respectively. Output gases were analyzed in a gas chromatograph coupled online brand Varian, model CP-3800 GC, equipped with column CP Poraplot Q, operating in isothermal condition. He was used as carrier gas. The products were analyzed by flame ionization detector (FID) and thermal conductivity detector (TCD). Before reaction, the catalysts were pretreated with pure CH₄, at 30 cm³3 Ota, A.; Kunkes, E. L.; Krohnert, J.; Schmal, M.; Behrens, M.; Appl. Catal., A2013, 452, 203. min^–1, 773 K, and heating rate of 10 K min^–1.

Results

Temperature programmed surface reaction (TPSR) and XRD analyses before and after reaction

The adsorption and decomposition mechanism of methane on metallic surfaces is an exothermic activation process of dissociative and homolytic in nature. The kinetics of CH₄ adsorption on metallic surfaces has been studied in the literature by TPSR on different supported metals, films and crystallites. However, there is little about the methane decomposition on unsupported nanosized metallic crystals. Therefore, we prepared the nanosized crystallites by different methods, which were tested and characterized before and after the reaction decomposition and after exposure of the catalyst to methane for 5 h.

The supported 25NiZ and unsupported NiEG catalysts

Temperature programmed surface reaction results for the supported 25NiZ catalyst are presented in Figure 1a, showing the methane (m/z 15), hydrogen (m/z 2) and water (m/z 18) profiles with increasing temperature up to 773 K and at a heating rate of 10 K min^–1. Figure 1b shows the profiles of the unsupported NiEG sample.

Figure 1
Temperature programmed surface reaction profiles (TPSR) of 25NiZ (a) and NiEG (b) catalysts.

The behavior of these samples is quite different. For the supported 25NiZ sample, the water profile (m/z 18) increases initially with time on stream but after reaching a maximum peak it decreases, indicating firstly methane decomposition and simultaneously H₂ (m/z 2) consumption, which can be attributed to the reduction of NiO to metallic sites and water formation. In fact, methane is highly decomposed initially, decreasing then with time at lower conversion, indicating thus the partial deactivation of the catalyst, due to the carbon deposition. On the other hand, the unsupported NiEG sample showed constant profiles with time on stream after initial activation, including for water (m/z 18), suggesting a slower process of NiO reduction during the reaction. No longer had deactivation occurred, but only decomposition of methane at higher conversions.

In fact, the diffractograms of the supported 25NiZ catalyst before and after reaction, which are presented in Figure 2A, evidence firstly the presence of a tetragonal phase of zirconia and before reaction only the nickel oxide. However, after reaction, it presents only metallic Ni⁰ cubic phase, as shown in the diffraction peaks at 44.5º (111), 51.8º (200) and 76.4º (220). Besides, there are diffraction peaks at 26º (002) and 42º (101), which are assigned to the carbon phase as graphite structure.

Figure 2
XRD of 25NiZ catalyst (A) before (a) and after (b) reaction; XRD of the NiEG catalyst (B) before (a) and after (b) reaction: G: graphite; T: tetragonal zirconia.

Figure 2B displays the diffractograms of the unsupported NiEG sample before and after reaction. Before the reaction, exhibits diffraction peaks at 37.26º (111), 43.28º (200), 62.88º (220), 75.38º (311) and 79.75º (222), which are assigned to NiO cubic phase. After reaction, exhibits diffraction peaks at 44.5º, 51.8º and 76.4º, which are attributed to the metallic Ni⁰, besides the peaks at 26º (002) and 42º (101), corresponding to a graphite structure.

The unsupported NiDMG sample

Figure 3A displays the mass spectra profiles of H₂O, CH₄ and H₂ of the NiDMG sample. Different from the previous NiEG sample, the NiDMG catalyst lost activity, since the H₂ evolution and methane consumption decreased with time on stream, after initial decomposition of methane and activation of NiO into metallic Ni⁰.

Figure 3
Temperature programmed surface reaction profiles (TPSR) of 25NiDMG (A); (B) XRD diffraction of the NiDMG catalyst before (a) and after (b) reaction decomposition at 773 K.

Indeed, Figure 3B shows the diffractograms of the unsupported NiDMG catalyst before and after reaction at 773 K for 5 h. Before the reaction, there are diffraction lines attributed to NiO cubic phase, beside the diffraction lines assigned to the Ni⁰ metallic crystalline phase. However, after the reaction, it shows only diffraction lines corresponding to the Ni⁰ metallic phase and of the graphite structure. However, when compared to the previous NiEG, these graphite diffraction lines are less intense.

The hydrotermal precursor (NiHT)

The unsupported NiHT was obtained after hydrotreatment and calcination of β-Ni(OH)₂ precursor.¹⁶16 Zhu, L. P.; Liao, G. H.; Yang, Y.; Xiao, H. M.; Wang, J. F.; Fu, S. Y.; Nanoscale Res. Lett.2009, 4, 550. Figure 4A displays the profiles of methane decomposition on the NiHT with increasing temperature. Like the NiEG sample, the profiles are very similar during the reaction. After an initial activation of Ni species by methane, which was done during time on stream, as evidenced by the profile of water formation, methane is decomposed, with the formation H₂ at a constant level.

Figure 4
Profiles during CH4 decomposition with increasing temperature of NiHT (A); XRD of the NiHT sample (B): before (a) and after (b) CH₄ decomposition at 773K. G: graphite.

Figure 4B displays the diffratograms of the NiHT before and after exposition to methane at 773 K by 5 h. Before reaction, the diffraction pattern shows the lines corresponding to the NiO cubic phase. After treatment, only refraction lines corresponding to metallic Ni⁰ phase and graphite were observed.

Scanning electronic microscopy (SEM-FEG)

Figure 5 displays the scanning electronic microscopic analyses. Figure 5a shows a nanoflower like type morphology in tridimensional form of NiO on the NiEG sample before the reaction. This morphology was originally observed on the hydroxide before calcination and seems to be very stable after thermal pretreatment; thus, removing water did not damage the structure of the precursor. The structure did not collapse or fracture, which can be attributed to the excellent contact between nanoparticles with high orientation degree.¹⁴14 Li, Y.; Zhang, B.; Xie, X.; Liu, J.; Xu, Y.; Shen, W.; J. Catal.2006, 238, 412.

Figure 5
SEM images of the NiEG sample (a) in oxide form: 100000×; SEM images of the NiDMG sample (b) in oxide form, 20000×.

Figure 5b shows SEM images of NiO after calcination of the NiDMG precursor, indicating the presence of bidimensional rods, which suggests made up of small particles that gather forming rods. By removing the organic molecule (DMG) during heating, the arrangement of the structure of the precursor NiDMG was not affected, and according to Gui et al.,¹⁷17 Gui, Z.; Liv, J.; Wang, Z.; Song, L.; Hu, Y.; Fan, W.; Chen, D.; J. Phys. Chem. B2005, 109, 1113. heating probably supplies energy to maintain the NiO nanoparticles highly oriented in the structure.

SEM images of the NiHT sample are displayed in Figure 6. The images are similar to the images of the NiEG sample, exhibiting nanosheets arranged with bends and hollow structure forming nanoflowers. However, comparing the images, it seems that the NiHT sample presents structures, which are less compacted. Zhu et al.¹⁶16 Zhu, L. P.; Liao, G. H.; Yang, Y.; Xiao, H. M.; Wang, J. F.; Fu, S. Y.; Nanoscale Res. Lett.2009, 4, 550. claims that urea and ammonia influence the formation of tridimensional structure during the preparation of the hydroxide precursor. The absence of urea results in a flaked structure and the absence of ammonia results in a structure in the form of combs.

Figure 6
SEM images of the NiHT sample.

Figure 7 displays the SEM images with the EDS analysis of C, Zr and Ni of 25NiZ catalyst after 5 h of methane exposition at 773 K. As observed by Aiello,⁸8 Aiello, R.; Fiscus, J. E.; zur Loye, H-C.; Amiridis, M. D.; Appl. Catal., A2000, 192, 227. on supported nickel catalysts, methane is decomposed at the interface gas-metal followed by dissolution and carbon diffusion through the metal particles. These carbons then precipitate at the interface dragging out the metallic particle of the support with the formation of carbon nanofilaments with metal particles at the tip. The EDS images show clearly the grain of zirconia free from carbon particles with Ni particles well dispersed on it as well as on carbon nanofilaments.

Figure 7
SEM image of 25NiZ with EDS analysis of C, Zr and Ni after 5 h of methane exposition at 773K.

Figure 8 displays the SEM images of NiEG after 5 h of methane exposition at 773 K. On unsupported Ni nanoparticles (NiEG, NiDMG and NiHT), there is formation of carbon nanofilaments, which acted as living supports taking the catalyst particles away and preventing them from sintering with adjacent particles. By this way, the metal particles are located at the tip of nanotubes.

Figure 8
SEM image of NiEG after 5 h of methane exposition at 773 K.

Activity tests

Activity tests were conducted at atmospheric pressure in a Pyrex micro reactor of fixed bed using 100 mg of the supported and 25 mg of the unsupported Ni catalysts at 773 K. Catalysts were pretreated with pure CH₄ at 30 cm³3 Ota, A.; Kunkes, E. L.; Krohnert, J.; Schmal, M.; Behrens, M.; Appl. Catal., A2013, 452, 203.min^–1 and 773 K, and heating rate of 10 K min^–1.

Figure 9 displays the results of the conversion of methane at 773 K for all catalysts. The unsupported NiEG, NiHT and the supported Ni catalysts (25NiZ) presented similar behavior and conversions around 9% with time on stream. However, the NiDMG catalyst presented much lower conversion, although the crystal sizes in nano size dimensions as the previous samples.

Figure 9
Conversion of methane on supported 25NiZ, and unsupported NiEG, NiDMG and NiHT catalysts.

Discussion

In et al.¹⁸18 In, Y. Z.; Sun, J.; Yi, J.; Lin, J. D.; Chen, H. B.; Liao, D. W.; J. Mol. Struct. 2002, 587, 63. studied comparatively chemisorption and methane conversion on metallic crystallite surfaces calculating the dissociation energy of C–H bonds of methane and showed that the main dissociated species is CH₃, because it has the highest energetic barrier to split the bonding, as observed for the reaction CH₃→ CH₂+ H* over all surfaces. The higher the adsorption strength, the higher is the energy necessary to move surface species that migrate over the surface to meet other fragments for reacting. They concluded that ethylene should be formed through dehydrogenation of ethane and not by coupling of methane. Ciobica et al.¹⁹19 Ciobica, I. M.; van Santen, R. A.; J. Phys. Chem. B2002, 106, 6200. calculated that on Ru (1120), the most stable species is CH₂^* and that the intermediates CH_x (1 < x < 3) are more stable when adsorbed on bridged sites, while C species are preferentially adsorbed on top sites.

As described in our previous paper,⁹9 Alberton, A. L.; Souza, M. M. V. M.; Schmal, M.; Appl. Catal., B2011, 103(3-4), 326. the first step of the homologation reaction is the adsorption of methane, followed by the hydrogenation step. During the adsorption of methane, there are different surface carbon adspecies, which can be hydrogenated. The H₂ evolution resulted from the association of hydrogen atoms provided from dissociative chemisorption of methane, as indicated by equations 2 and 3:

However, methane conversion increased besides water consumption during the reaction. These results suggest decomposition of methane (equation 2) besides methane reforming (equation 5).

However, CO was not detected, which suggests that shift reaction may occur (equation 6), due to the presence of water, during the activation process, beside the CO decomposition, according to Bourduard (equation 7) and the dry reforming (equation 8).

X-ray results

The commonly accepted model of methane decomposition and carbon growth on nickel catalysts consists of three stages:²⁰20 Li, Y. D.; Li, D. X.; Wang, G. W.; Catal. Today2011, 162, 1.^,2121 Dupuis, A. C.; Prog. Mater. Sci.2005, 50, 929. (i) methane molecules adsorb dissociatively on active surface Ni (100) and Ni (110) planes of the catalysts, which may exist as small aggregated nickel crystals, (ii) carbon diffuses into the bulk of the nickel crystallite and filaments would rapidly grow on the Ni (111) face of the crystallite due to the coincidental symmetry between the Ni (111) and the graphite (002) plane, (iii) nickel crystallites will be dragged out on the tip of the growing carbon filament. This will also prevent small crystallites contacting with neighboring particles or sintering into bigger ones.

To maintain the continuous growth of carbon nanofilaments or nanotubes, the balance between the methane decomposition rate, carbon diffusion rate and the precipitation rate can be achieved by using appropriate catalyst particle sizes. The disequilibrium occurs when the dissociation rate is much faster than the carbon diffusion rate and subsequently carbon layers will be formed on the active surfaces of the catalysts, resulting in the so-called deactivation process.²²22 Yang, R. T.; Chen, J. P.; J. Catal.1989, 115, 52. The initial carbon nanofilaments act as transporting agent and support to take individual particles away, and prevent sintering with adjacent particles of the catalyst, as displayed in Figures 7 and 8 for 25NiZ and NiEG catalysts. Other factors influencing the feasibility of carbon filament formation include the particle size and the surface area. Smaller particle sizes and larger surface areas (more porous structure) increase the probability for methane molecules to reach the active surface and to draw the nickel crystallites away and be supported on the tip of carbon nanofibers, thus preventing them from sintering into bigger crystals. It was interesting to note that the active Ni particles during the reaction were usually on the tip of one carbon nanofiber only. However, Wang et al.,²³23 Wang, H. Y.; Lua, A. C.; J. Phys. Chem.2012, 116, 26765. upon closer inspection of deactivated unsupported Ni catalyst, found that two Ni particles collided and coalesced together with two carbon nanofibers connecting them. In fact, the micrographs of the totally deactivated Ni catalysts suggest that the collisions between two Ni catalyst particles or between Ni particles and carbon nanofibers might also be a reason contributing to catalyst deactivation.

The crystallite sizes of the nano structured catalyst before the reaction were calculated according to Sherrer's equation and the results are presented in Table 1. As seen, the crystallite sizes changed from 6 nm to 27 nm, and depend on the preparation method. The supported 25NiZ catalyst presented bigger crystallites (27 nm), while the unsupported NiEG the lowest value (6 nm). These values are in the range of nanosized crystallites.

In our previous paper,¹⁷17 Gui, Z.; Liv, J.; Wang, Z.; Song, L.; Hu, Y.; Fan, W.; Chen, D.; J. Phys. Chem. B2005, 109, 1113. we prepared nickel nanoparticles for the non-oxidative methane activation. A nickel acetate solution was impregnated on silica support and then reduced with NaBH₄ (NiB/SiO₂) exhibiting only metallic Ni⁰ particles of the order of 15 nm. Part of this solid was then oxidized under mild conditions, where Ni ions were re-structured and redistributed as a Ni-Ox/SiO₂ oxide solid that, after reduction with hydrogen, favored the formation of smaller Ni⁰ particles of the order of 3.5 nm. Comparing the results, one can conclude that crystallite sizes of the unsupported NiEG, which was prepared by precipitation of nickel hydroxide with sodium carbonate precursor salts dissolved in ethylene glycol¹⁴14 Li, Y.; Zhang, B.; Xie, X.; Liu, J.; Xu, Y.; Shen, W.; J. Catal.2006, 238, 412. (NiEG), are comparable to the method prepared by impregnation of a nickel acetate¹⁷17 Gui, Z.; Liv, J.; Wang, Z.; Song, L.; Hu, Y.; Fan, W.; Chen, D.; J. Phys. Chem. B2005, 109, 1113. in contrast to the 25NiZ supported sample, which presented crystallite sizes 4 times bigger than the unsupported NiEG.

Activity

The reaction rates are presented in Table 1 for different catalysts. The rates of the NiO on the NiEG and NiHT precursors are similar and approximately equal to the reaction rate of the supported 25NiZ sample [8.04 × 10^–5mols (g_NiO. s)^–1], used as reference, but three times more active than the NiDMG sample [2.68 × 10^–5mols (g_NiO. s)^–1]. In fact, the activity seems to depend on the morphology. In particular, it suggests that the nanoflower like type NiEG exposes nanosized NiO crystallites for the methane decomposition or dissociation, which increases the activity. On the other hand, the nanorod shape crystallites, like NiDMG precursor, are less active and probably less stable.

The results indicate that these catalysts are active for the dissociation or decomposition of methane and for the formation of carbon nanospecies species of high reactivity at the surface. Quantitatively, there are significant differences between the different samples, the supported 25NiZ and the unsupported NiEG, NiHT and NiDMG samples, where the first three exhibited three times more adsorption capacity than the last one. Indeed, the metal oxide crystal sizes of the NiEG and NiHT are approximately 2 times lower than of NiDMG precursor, with exception of the supported 25NiZ catalyst (Table 1). In fact, Table 1 presents the carbon formation of the different samples and shows that the amount of carbon formation is related to the activity of the different NiO morphologies. In our previous study,⁴4 Moya, S. F.; Martins, R. L.; Schmal, M.; Appl. Catal., A2011, 396, 159. we observed that although the particle sizes of NiB/SiO₂ and Ni-Ox/SiO₂ differ by a factor of 5, the activity at 773 K or adsorption capacity of the Ni-Ox/SiO₂ catalyst was three times more active than NiB/SiO₂. The adsorption capacity is attributed to the metallic nanostructured particles. Therefore, the results suggest that the structure of the metal oxide and the morphology in particular, affect the methane dissociation.

Koerts²⁴24 Koerts, T.; Deelen, M. J. A.; van Santen, R. A.; J. Catal.1992, 138, 101. observed and classified the surface carbon species as C_α, C_β and C_γ. The most reactive is the carbide C_α type, followed by the less active C_β carbon, which is amorphous. The C_γ or graphitic carbon is the less active. According to authors, the C_α carbon species are formed on low surface coverages. Winslow et al.²⁵25 Winslow, P.; Bell, A. T.; J. Catal. 1985, 94, 385. and Duncan²⁶26 Duncan, T. M.; Winslow, P.; Bell, A. T.; J. Catal. 1985, 93, 1. indicated that methane is initially dissociated in C_α carbon adsorbed species, which can be transformed immediately to C_β, both phases in dynamic equilibrium. However, the C_β carbon species can be slowly transformed by aging into irreversible C_γ species, at rates depending on the temperature and structure of the catalyst.

The dissociative adsorption of methane on Ni catalysts has been studied by different authors, showing that the estimated value of the energetic barrier of methane dissociation on Ni (100) crystal surface faces were 0.28 eV²⁷27 Beebe Jr, T. P.; Goodman, D. W.; Kay, B. D.; Yates, J. T.; J. Chem. Phys.1987, 87, 2305. and 0.54 eV²⁸28 Chorkendorff, I.; Alstrup, I.; Ullmann, S.; Surf. Sci. 1990, 227, 291. and for Ni (111) crystal surface 0.77eV.²⁹29 Egeberg, R. C.; Ullmann, S.; Astrup, I.; Mullins, C. B.; Chorkendorff, I.; Surf. Sci.2002, 497, 183. Theoretical calculations indicated energetic barriers in the range of 0.69 ± 0.04 eV for methane dissociation on Ni (100) surfaces.³⁰30 Swang, O.; Faegri Jr., K.; Gropen, O.; Wahlgren, U.; Siegbahn, P.; Chem. Phys. 1991, 156, 379. In fact, calculations³¹31 Xing, B.; Pang, X-Y.; Wang, G-C.; Shang, Z-F.; J. Mol. Catal.A: Chem.2010, 315, 187. by density functional theory (DFT) estimated energy value of 0.60 eV on Ni (100) surface; however, the presence of oxygen inhibits the methane dissociation, which is attributed to the decreasing interaction between CH₃ and H atoms with the substrate. Therefore, to increase the exposition at the surface of the Ni (100) face, it is necessary to change their morphology. In fact, it suggests that nanostructures of nanoflowers like type may address the specific topology.

Conclusions

The NiO catalysts prepared using different methods for controlling the particle sizes with different organic precursors and Ni(NO₃)₂.6H₂O as source of Ni, were active for methane activation with H₂ and carbon nanotubes production. The initial carbon nanotubes acted as transporting agents and supports to take individual catalyst particles away and prevent them from sintering with adjacent particles. The results of this work indicate that there is a strong dependence of crystallite sizes and, in particular of the morphology, with the activation of methane and their stability. Crystallites of the order of magnitude of nanostructure favor the dissociation of methane and inhibit aggregation and formation of bigger particles that conducts to deactivation. The NiO of the NiEG and NiHT precursor presented crystallite sizes of the order of 6 and 8 nm, respectively, while the NiO of NiDMG precursor presented crystallite sizes of the order of 15 nm.

The activities of the NiO on the NiEG and NiHT precursors are similar and approximately equal to the activity of the 25NiZ supported sample and three times more active than the NiDMG precursor. As a matter of fact, it seems that the morphology and crystallite sizes of NiDMG catalyst leads methane dissociation rate much faster than the carbon diffusion rate and subsequently carbon layers of graphite will be formed on the active surfaces of the catalysts, resulting in the so-called deactivation process. Carbon nanofibers can only be produced when the balance between methane dissociation rate and carbon diffusion rate is maintained. In fact, the activity and the nano structured crystallites sizes depend on the morphology, which suggests that the nanoflower like type beside achieves the proper carbon diffusion rate and the precipitation rate, increases the exposing Ni (100) crystal surface for the methane decomposition or dissociation. Also, its structure stability can be attributed to the excellent contact between nanoparticles with high orientation degree.

Acknowledgments

Sylvia Moya, Maria Auxiliadora S. Baldanza, and the support of FINEP, CAPES and CNPq.

References

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