Catalytic decomposition of biogas to produce H2-rich fuel gas and carbon nanofibers. Parametric study and characterization

Llobet, S. de; Pinilla, J.L.; Lázaro, M.J.; Moliner, R.; Suelves, I.

doi:10.1016/j.ijhydene.2011.10.123

Cited by 26 publications

(18 citation statements)

References 34 publications

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“…Nevertheless, the exploitation of biogas for different applications appears as an interesting option, particularly when considering its renewable origin. In this context, the Catalytic Decomposition of Biogas (CDB) to simultaneously produce syngas (SG) with high hydrogen contents and bio-carbon nanofibers (BCNFs) has been studied in detail [18,19]. As CNFs, BCNFs from biogas have initially a certain degree of structural order and therefore, they are classified within graphitic carbons.…”

Section: Introductionmentioning

confidence: 99%

Graphitic nanomaterials from biogas-derived carbon nanofibers

Cuesta

Cameán

Ramos

et al. 2016

Fuel Processing Technology

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Carbon nanofibers with different microstructure and elemental composition that were produced in the catalytic decomposition of synthetic biogas mixtures, in a rotary-bed reactor using nickel and nickel-cobalt catalysts at 600 ºC and 700 ºC, were heat treated in the temperature interval 2600-2800 ºC to explore their ability to graphitize. The influence of treatment temperature as well as carbon nanofibers composition, particularly metallic species, on the structural and textural properties of the materials prepared is discussed. Graphitic nanomaterials with great development of the three-dimensional structure (d 002 ~ 0.3360 nm, L c ~ 48 nm, L a ~ > 100 nm) and low porosity (S BET ~ 20 m 2 g -1 ) have been achieved. Because of the catalytic effect of silicon in the presence of inherent nickel and cobalt metals, more structurally ordered materials were obtained from the carbon nanofibers by adding silica. Based on the results of this work, the utilization of biogasderived carbon nanofibers for the production of synthetic nanographite to be used in different applications, such as electrode material in energy storage devices in which both high degree of graphitic order and small surface area are required, appears feasible.

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Section: Introductionmentioning

confidence: 99%

Graphitic nanomaterials from biogas-derived carbon nanofibers

Cuesta

Cameán

Ramos

et al. 2016

Fuel Processing Technology

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“…The nickel domain size of the calcined fresh catalyst was 19 nm while after the reduction pre-treatment (under a H 2 flow at 550 °C) and passivation (under a 1% O 2 -99% N 2 flow at room temperature) was 31 nm. This catalyst has been extensively used and a thorough characterization can be found in previous works of our research group [19,24].…”

Section: Catalyst Preparationmentioning

confidence: 99%

CH4 and CO2 partial pressures influence and deactivation study on the Catalytic Decomposition of Biogas over a Ni catalyst

Llobet

Pinilla

Lázaro

et al. 2013

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A conceptually similar approach to dry reforming of CH 4 (DRM) called Catalytic Decomposition of Biogas (CDB) is proposed. CDB is based on the direct decomposition of CH 4 and CO 2 , which are the most abundant components in biogas (typically with CH 4 :CO 2 molar ratios higher than 1). The main difference between DRM and CDB lies in the desired products obtained in each process. While in DRM carbon formation is not desired and thus avoided, in CDB carbon accumulation in form of filamentous structures is promoted. In this work, the effect of CH 4 and CO 2 partial pressures on the initial reaction rates of CDB was studied using a Ni/Al 2 O 3 catalyst. Furthermore, a deactivation study was carried out in order to determine the experimental conditions (CH 4 and CO 2 partial pressures and temperature) at which carbon formation did not deactivate the catalyst. It was proved that after a certain time on stream, CDB can reach the steady state even though the CH 4 :CO 2 molar ratio is higher than one (typical biogas conditions). In addition, temperature increased reaction rates since CDB is an endothermic process, but it had no effect on catalyst deactivation.

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“…Operating conditions as temperature or feedstock composition (CH 4 :CO 2 ratio) are key factors [17,18]. Thermodynamic analysis revealed that high temperatures and/or CH 4 :CO 2 ratios below the unity are necessary to avoid carbon formation [19], even though from an industrial point of view the opposite conditions are more convenient.…”

Section: Introductionmentioning

confidence: 99%

“…Depending on the previous relative rates, catalyst deactivation could be prevented if steps ii) and iii) are faster than iv) [30]. Under these conditions, the front face of catalyst particles remain free of carbon, leaving accessible active sites to CH 4 and CO 2 and allowing the formation of NFC without catalyst deactivation [12,17,31]. With this background in mind, we recently addressed a novel approach to the decomposition of CH 4 /CO 2 mixtures (the so-called catalytic decomposition of biogas (CDB)) which consisted in the simultaneous production of syngas (H 2 and CO mixture) and bio-nanostructured filamentous carbon (BNFC) [32].…”

Section: Introductionmentioning

confidence: 99%

“…Corthals et al [43] reported the formation of multiwall carbon nanotubes (MWCNT) over a NiMgTiO 3 catalyst and fishbone-like CNF over a NiMgAl 2 O 4 catalyst. Our previous studies with a Ni/Al 2 O 3 catalyst [17,32,44] revealed the formation of fishbone-like CNF at 600 ºC and a mixture of fishbone and parallellike CNF at 700 ºC. In the previous studies, NFC were produced employing different metal-based catalysts.…”

Section: Introductionmentioning

confidence: 99%

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Relationship between carbon morphology and catalyst deactivation in the catalytic decomposition of biogas using Ni, Co and Fe based catalysts

Llobet

Pinilla

Moliner

et al. 2015

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A novel approach to the decomposition of biogas consisting in the simultaneous production of syngas (H 2 and CO mixture) and bio-nanostructured filamentous carbon (BNFC) is proposed. Catalysts with different active phases such as Ni, Co or Fe on Al 2 O 3 are studied in the temperature range between 600 and 900 ºC. Their behaviour was analysed considering CH 4 and CO 2 conversions, reaction rates, catalyst stability and carbon production. Additionally, the BNFC produced were characterised by transmission electron microscopy. Depending on the active phase and the reaction temperature, different carbon types were identified: fishbone, parallel and chain-like BNFC and encapsulating carbon. Large amounts of BNFC and good catalyst stability were achieved with the Ni/Al 2 O 3 catalyst at 600 ºC, pointing out that carbon accumulation is not directly responsible of catalyst deactivation and that the key factor is the nature of carbon formed during the reaction.

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Catalytic decomposition of biogas to produce H2-rich fuel gas and carbon nanofibers. Parametric study and characterization

Cited by 26 publications

References 34 publications

Graphitic nanomaterials from biogas-derived carbon nanofibers

Graphitic nanomaterials from biogas-derived carbon nanofibers

CH4 and CO2 partial pressures influence and deactivation study on the Catalytic Decomposition of Biogas over a Ni catalyst

Relationship between carbon morphology and catalyst deactivation in the catalytic decomposition of biogas using Ni, Co and Fe based catalysts

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