Warm Plasma Reactor With Vortex Effect Enhanced Used for CH<sub>4</sub>–CO<sub>2</sub> Reforming

Pacheco, J.; Soria, Gustavo Adolfo Siles; Valdivia, Ricardo; Pacheco, Marquidia; Ramos, F; Frias, Hilda; Durán, M; Hidalgo, M. A.; Salazar, Juan P. L. C.; Silva, Jesus; Ibáñez, Mario

doi:10.1109/tps.2014.2337290

Cited by 7 publications

(4 citation statements)

References 5 publications

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“…Subsequently, a breakdown voltage is applied to ionize the working gas, initiating the synthesis process. The primary objective of the vortex effect is to enhance the interaction between the gas and the plasma reactive species, with the aim of improving the conversion process [15].…”

Section: Methodsmentioning

confidence: 99%

“…This versatility leads to the creation of one-dimensional (1D), two-dimensional (2D), Diverse plasma-based techniques have been pivotal in the synthesis of carbon nanostructures, each characterized by distinct operational mechanisms and advantages. The primary plasma techniques employed for the synthesis of carbon nanostructures include plasma-enhanced chemical vapor deposition [5,6], electric arc plasma discharge [7,8], inductively-coupled radiofrequency thermal plasma [9][10][11], microwave plasma discharge [12,13], plasma jet [14,15], sputtering and spark plasma sintering [16]. Each type of discharge has specific characteristics that influence the formation of different carbon allotropes such as: monolayer and multilayer graphene, carbon nanotubes, and other carbon nanostructures.…”

Section: Introductionmentioning

confidence: 99%

“…Warm plasma promotes a balanced energy distribution among particles, enabling more uniform interactions among electrons, ions, and neutrals. Warm plasma is an intermediate discharge state that amalgamates the benefits of both thermal and cold plasmas, leveraging the unique properties of each to achieve a balance of conditions conducive to a wide array of applications [15]. Some applications that have yielded positive results with the use of warm plasma have been hydrocarbon reforming processes using jet-type discharges and gliding electrical arcs [30,31].…”

Section: Introductionmentioning

confidence: 99%

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Carbon nanostructures synthesis by catalyst-free atmospheric pressure plasma jet

Neira-Velázquez,

Ku-Herrera,

Narro-Céspedes

et al. 2024

J. Phys. D: Appl. Phys.

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In this study, carbon nanostructures were synthesized utilizing a warm plasma jet at atmospheric pressure in a continuous and catalyst-free process. The procedure and apparatus were designed and constructed in our laboratory. Plasma was generated with 600 watts of electrical energy, using a high-voltage, high-frequency alternating current power source. The working gas utilized was a propane/butane mixture, with a concentration ratio of 60:40, respectively. A production rate of 300 mg/min of powdered material was achieved, with a particle size between 20 and 100 nm. The product was characterized by FTIR, thermogravimetric analysis, Raman spectroscopy, X-ray diffraction, and transmission electron microscopy. Results show the formation of multilayer carbon nanostructures with a low content of functional groups; the obtained material presented structural defects and amorphous carbon. This work demonstrates that, with adequate control, warm plasma jet discharges can be employed for the synthesis of carbon nanostructures. The process is scalable and can be utilized for hydrocarbon reforming and hydrogen production. However, further studies are needed to improve the quality of the nanostructures and process efficiency. The synthesized material can potentially be used in gas adsorption or in the manufacture of polymeric nanocomposites with enhanced thermal, electrical, and mechanical properties.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Carbon nanostructures synthesis by catalyst-free atmospheric pressure plasma jet

Neira-Velázquez,

Ku-Herrera,

Narro-Céspedes

et al. 2024

J. Phys. D: Appl. Phys.

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“…Additionally, in an increasing number of countries, plasma reactors can be powered by renewable electricity, thus offering a new route for renewable electricity-to-gas processes and applications (e.g., intermittent energy storage and valorization). Plasma technologies such as dielectric barrier discharge (DBD) [12][13][14][15][16], glow discharges [17,18], microwave discharges (MW) [11], corona discharges [19,20], radio-frequency discharges (RF) [21] and gliding arc discharges [7,8,[22][23][24][25] have been extensively investigated for reforming reactions. However, corona discharges and dielectric barrier discharges present high energy cost of syngas (>10 kWh m -3 ) and low energy efficiency (<10%) in biogas reforming [26,27].…”

Section: Introductionmentioning

confidence: 99%

Influence of Operating Parameters on Plasma-Assisted Dry Reforming of Methane in a Rotating Gliding Arc Reactor

Martin-del-Campo

Coulombe

Kopyscinski

2020

Plasma Chem Plasma Process

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The environmental impact of greenhouse gases such as carbon dioxide and methane can be reduced if they are used as feedstock to synthesize chemical building blocks such as syngas (CO, H 2) via dry reforming. Methane dry reforming is investigated using an Ar/CO2/CH4 rotating gliding arc (RGA) reactor powered by a dual-stage pulsed DC power supply. Tangential gas injection combined with a static magnetic field enabled the rotation and upward displacement of the arc along the conical cathode and the grounded anode, yielding to a larger plasma volume. Different parameters such as peak arc current (0.74 and 1.50 A), total gas flow rate (3.7, 4.7 and 6.7 SLPM), CO2/CH4 ratio (1.0, 1.5, 2.0) and gas inlet preheating (room temperature, 200 °C) were studied to determine the most efficient parameter combination. Gas conversion was measured online using a calibrated mass spectrometer and offline using a gas chromatograph. Noticeable increases in CO2 and CH4 conversions, as well as H2 and CO yields, were obtained when doubling the peak arc current. For the larger peak current, higher H2 yields were obtained at a CO2/CH4=1.0, and the best energy efficiencies were obtained at the lowest specific energy input values. No significant effect of the gas inlet temperature on the conversions or yields was found. Trace amounts of acetylene and ethylene, as well as some carbon deposits were observed as by-products of syngas generation. The low amount of by-products obtained implies a good selectivity for CO and H2, i.e., a cleaner syngas when produced with RGA discharge.

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Greenhouse gas treatment and H2 production, by warm plasma reforming

Pacheco

Soria

Pacheco

et al. 2015

International Journal of Hydrogen Energy

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Warm Plasma Reactor With Vortex Effect Enhanced Used for CH₄–CO₂ Reforming

Cited by 7 publications

References 5 publications

Carbon nanostructures synthesis by catalyst-free atmospheric pressure plasma jet

Carbon nanostructures synthesis by catalyst-free atmospheric pressure plasma jet

Influence of Operating Parameters on Plasma-Assisted Dry Reforming of Methane in a Rotating Gliding Arc Reactor

Greenhouse gas treatment and H2 production, by warm plasma reforming

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Warm Plasma Reactor With Vortex Effect Enhanced Used for CH4–CO2 Reforming

Cited by 7 publications

References 5 publications

Carbon nanostructures synthesis by catalyst-free atmospheric pressure plasma jet

Carbon nanostructures synthesis by catalyst-free atmospheric pressure plasma jet

Influence of Operating Parameters on Plasma-Assisted Dry Reforming of Methane in a Rotating Gliding Arc Reactor

Greenhouse gas treatment and H2 production, by warm plasma reforming

Contact Info

Product

Resources

About

Warm Plasma Reactor With Vortex Effect Enhanced Used for CH₄–CO₂ Reforming