La0.6Sr0.4Co0.8Ga0.2O3‐δ (LSCG) hollow fiber membrane reactor: Partial oxidation of methane at medium temperature

Kathiraser, Yasotha; Kawi, Sibudjing

doi:10.1002/aic.14202

Cited by 35 publications

(20 citation statements)

References 62 publications

(100 reference statements)

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“…Kathiraser et al [215] reported a study on the La 0.6 Sr 0.4 Co 0.8 Ga 0.2 O 3-δ hollow fiber membrane. The authors introduced the Ga 3+ cation in the membrane structure to improve its mechanical stability.…”

Section: Partial Oxidation Of Methane (Pom)mentioning

confidence: 99%

Mixed Ionic-Electronic Conducting Membranes (MIEC) for Their Application in Membrane Reactors: A Review

et al. 2019

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Mixed ionic-electronic conducting membranes have seen significant progress over the last 25 years as efficient ways to obtain oxygen separation from air and for their integration in chemical production systems where pure oxygen in small amounts is needed. Perovskite materials are the most employed materials for membrane preparation. However, they have poor phase stability and are prone to poisoning when subjected to CO2 and SO2, which limits their industrial application. To solve this, the so-called dual-phase membranes are attracting greater attention. In this review, recent advances on self-supported and supported oxygen membranes and factors that affect the oxygen permeation and membrane stability are presented. Possible ways for further improvements that can be pursued to increase the oxygen permeation rate are also indicated. Lastly, an overview of the most relevant examples of membrane reactors in which oxygen membranes have been integrated are provided.

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Section: Partial Oxidation Of Methane (Pom)mentioning

confidence: 99%

Mixed Ionic-Electronic Conducting Membranes (MIEC) for Their Application in Membrane Reactors: A Review

et al. 2019

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“…Kathiraser et al [166] and Kathiraser and Kawi [167] showed a composite Lanthanum-Strontium-Cobalt-Gallium oxide membrane-type reactor to produced up to 94% and 73% conversion of methane and carbon dioxide, respectively, during dry reforming over Ni-supported and La-supported Al 2 O 3 catalyst system at moderate temperatures. Catalyst was completely stable with no detectable coke deposition for 160 h period.…”

Section: Effect Of Reactor Designmentioning

confidence: 99%

A review on coke management during dry reforming of methane

Muraza

Galadima

2015

Int. J. Energy Res.

288

139

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Summary The dry (CO2) reforming of methane is a great promising technology, particularly because of its dual advantages of natural gas valorization and mitigating global warming via carbon dioxide sequestration. However, coke management is the most difficult problem in commercialization of the process. We have therefore examined in this paper the various catalytic systems being evaluated for the dry reforming with emphasis on operating parameters, activity, and coke deposition. Other factors such as the catalyst promoter, the reactor system, and the periodical regeneration were also critically reviewed. The benefits of utilizing methane from natural gas and other sources, where carbon dioxide is considered as an impurity component, are emphasized. Structured basic catalysts, with periodic regeneration certainties, are strong candidates for industrial applications. Therefore, efforts to build commercial scales for the benefit of global energy industries were highlighted. Copyright © 2015 John Wiley & Sons, Ltd.

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“…If not oxidized, carbon remains attached to an otherwise active site and slows down the surface reaction in a manner similar to catalyst poisoning . Conversely, carbon oxidation can follow either partial oxidation or combustion depending on catalysts and reactant flow rates . As lattice oxygen is more active than gas‐phase oxygen species in oxidizing carbon species, the oxygen flux from water thermolysis on the feed side can affect the relative concentrations of these carbon species.…”

Section: Adding a Porous Layer For Performance Enhancementmentioning

confidence: 99%

“…To increase the oxygen flux further, we added a catalyst to the porous layer on the sweep side to accelerate the surface reaction. Nickel catalysts are reported to be one of the most effective base metal catalysts for POM in both packed bed or membrane reactors . While solid carbon is prone to form on nickel from methane decomposition, it is found that the active lattice oxygen from the catalysts or the support can facilitate the oxidation of surface carbon or soot .…”

Section: Further Enhancements Using a Nickel Catalystmentioning

confidence: 99%

Enhancing co‐production of H₂ and syngas via water splitting and POM on surface‐modified oxygen permeable membranes

Ghoniem

Uddi

2016

AIChE Journal

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In this paper, we report a detailed study on co-production of H 2 and syngas on La 0.9 Ca 0.1 FeO 3-δ (LCF-91) membranes via water splitting and partial oxidation of methane (POM), respectively. A permeation model shows that the surface reaction on the sweep side is the rate limiting step for this process on a 0.9 mm-thick dense membrane at 990 o C. Hence, sweep side surface modifications such as adding a porous layer and nickel catalysts were applied; the hydrogen production rate from water thermolysis is enhanced by two orders of magnitude to 0.37 μmol/cm 2 •s compared with the results on the unmodified membrane. At the sweep side exit, syngas (H 2 /CO = 2) is produced and negligible solid carbon is found. Yet near the membrane surface on the sweep side, methane can decompose into solid carbon and hydrogen at the surface, or it may be oxidized into CO and CO 2 , depending on the oxygen permeation flux.

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La_0.6Sr_0.4Co_0.8Ga_0.2O_3‐δ (LSCG) hollow fiber membrane reactor: Partial oxidation of methane at medium temperature

Cited by 35 publications

References 62 publications

Mixed Ionic-Electronic Conducting Membranes (MIEC) for Their Application in Membrane Reactors: A Review

Mixed Ionic-Electronic Conducting Membranes (MIEC) for Their Application in Membrane Reactors: A Review

A review on coke management during dry reforming of methane

Enhancing co‐production of H₂ and syngas via water splitting and POM on surface‐modified oxygen permeable membranes

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La0.6Sr0.4Co0.8Ga0.2O3‐δ (LSCG) hollow fiber membrane reactor: Partial oxidation of methane at medium temperature

Cited by 35 publications

References 62 publications

Mixed Ionic-Electronic Conducting Membranes (MIEC) for Their Application in Membrane Reactors: A Review

Mixed Ionic-Electronic Conducting Membranes (MIEC) for Their Application in Membrane Reactors: A Review

A review on coke management during dry reforming of methane

Enhancing co‐production of H2 and syngas via water splitting and POM on surface‐modified oxygen permeable membranes

Contact Info

Product

Resources

About

La_0.6Sr_0.4Co_0.8Ga_0.2O_3‐δ (LSCG) hollow fiber membrane reactor: Partial oxidation of methane at medium temperature

Enhancing co‐production of H₂ and syngas via water splitting and POM on surface‐modified oxygen permeable membranes