Methane Coupling to Ethylene and Longer-Chain Hydrocarbons by Low-Energy Electrical Discharge in Microstructured Reactors

Yu, Miao; Kreider, Peter B.; Reddick, Ian; Pommerenck, Justin; Collin, Ryan; AuYeung, Nick; Yokochi, Alex

doi:10.1021/acs.iecr.0c05984

Cited by 6 publications

(4 citation statements)

References 32 publications

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“…Characterization of Discharges within the Reactor. We have previously reported the I−V behavior of the electric discharge in our reactors, 31 and the I−V curve of the electric discharge with the diagnostic features (kilovolt level voltage, microampere level current, and voltage drop) usually can be divided into four major regimes (dark, spark, glow, and arc). The measurements on this multidischarge microreactor agree with this representative curve.…”

Section: Resultsmentioning

confidence: 99%

CO₂ Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling

Kreider

Pommerenck

et al. 2022

Ind. Eng. Chem. Res.

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The simple, robust, and energy-efficient reduction of CO2 to useful products is a significant goal of modern chemistry and chemical engineering. In this study, a novel CO2 reduction process was introduced by employing multiple low energy non-thermal electric glow discharges at the microscale. The process is neither dependent on limited lifetime catalysts nor consumable chemicals, enabling continuous operation over long periods, and operates at atmospheric pressure and temperature, thus simplifying process implementation. The influence of three parameters on the conversion of CO2 within the active volume and energy efficiency was studied, namely, the relative operational regimes on the V–I curve, the residence time of the reactant gas mixture in the plasma region, and the CO2 to water vapor molar ratio. High energy efficiencies of 80–95% and a CO2 conversion of 70–80% can be achieved in the active volume. A mathematical model reflecting geometry and flow conditions inside the microreactor was developed to simulate the chemical reaction process. Through an optimization process, the mathematical model parameters were determined to fit the experimental data and predict primary reaction constants for CO2 reduction.

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Section: Resultsmentioning

confidence: 99%

CO₂ Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling

Kreider

Pommerenck

et al. 2022

Ind. Eng. Chem. Res.

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“…Synthesis gas (H 2 and CO) has been commonly made in nonthermal plasmas with methane as a key reactant along with air or carbon dioxide. Although syngas production has been the goal of much of this research, ,,− there have also been studies focused on making larger hydrocarbons from methane. , In previous work at OSU, ,, carbon deposition on the electrodes over time harmed the operation of the reactor by making discharges unstable over time. At high methane fractions (>50% by mole), the discharge would short on the order of seconds to a minute.…”

Section: Introductionmentioning

confidence: 99%

Longevity Demonstration of Methane to C2 via a Nonthermal Plasma Microreactor

et al. 2023

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Hydrocarbon processing using plasmas has tremendous potential, yet there still exist many uncertainties pertaining to practical operation over long durations. Previously, it has been demonstrated that a nonthermal plasma operating in a DC glow regime can transform methane into C2 species (acetylene, ethylene, ethane) in a microreactor. Using a DC glow regime in a microchannel reactor allows for lower power consumption, at the expense of greater consequence of fouling. Since biogas can be a source of methane, a longevity study was undertaken to understand how the microreactor system would change over time with a feed mixture of simulated biogas (CO2, CH4) and air. Two different biogas mixtures were used, one of which contained 300 ppm H2S, while the other had no H2S. Potential difficulties observed from previous experiments included carbon deposition on the electrodes, which could interfere with the electrical characteristics of the plasma discharge as well as material deposition in the microchannel, which could affect gas flow. It was found that raising the temperature of the system to 120 °C helped prevent hydrocarbon deposition in the reactor. Purging the reactor periodically with dry air was also found to have positive effects as it removed carbon buildup on the electrodes themselves. Successful operation over a 50 h time period without any significant deterioration was demonstrated.

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“…The reactor used in this work is similar to the one used by this research group in Miao et al to study mixtures of CH 4 /O 2 and CH 4 /CO 2 in a nonthermal plasma. 6 Plasma reforming of methane has been studied previously with the goal of making syngas (H 2 and CO) 3,5,7 rather than the production of larger hydrocarbons. A review of the related research on methane/CO 2 nonthermal plasma systems can be seen in Table S1 in the Supporting Information.…”

Section: ■ Introductionmentioning

confidence: 99%

“…In the case of methane as the input species, the overall reaction of interest is an electron collision with a methane molecule leading to radical formation. If two of these radicals recombine, longer hydrocarbon chains can be built. In this study, carbon dioxide was used as the makeup gas to prevent rapid carbon deposition from the methane in the microreactor. The reactor used in this work is similar to the one used by this research group in Miao et al to study mixtures of CH 4 /O 2 and CH 4 /CO 2 in a nonthermal plasma . Plasma reforming of methane has been studied previously with the goal of making syngas (H 2 and CO) ,, rather than the production of larger hydrocarbons.…”

Section: Introductionmentioning

confidence: 99%

Parametric Study of Hydrocarbon Chain Growth from Methane via a Nonthermal Plasma Discharge Microreactor

Reddick

Shareghi

et al. 2022

Ind. Eng. Chem. Res.

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A parametric study was conducted in a nonthermal plasma reactor with an emphasis on converting methane and carbon dioxide to longer chain hydrocarbons. In contrast to previous plasma literature for this process, the approach here was distinctly different in that the glow/corona regimes were used without catalysis. Also, a microscale gap distance (rather than milliscale) was employed. Finally, the role of elevated pressure on plasma performance was examined, as higher pressure would bring the proposed process closer to industrial relevance. A microscale reactor with an electrode gap distance of only 500 μm was used to help reduce the voltage requirement for creating a stable nonthermal plasma glow discharge. Factors such as pressure, residence time, power, and composition were studied to determine their effects on conversion, product distribution, and energy efficiency. While some factors followed expected trends such as increasing power and residence time leading to more conversion, pressure was found to have significant effects on selectivity and energy efficiency. Increasing the pressure from 110 to 220 kPa greatly reduced the selectivity to higher hydrocarbons (36.2–16.4%) and increased syngas production. Higher pressure did increase the efficiency of the process (7–15%). This increase in efficiency was largely due to the fact that fractional conversion was only slightly affected by pressure despite the increase in the mass flow rate that increasing pressure causes while keeping residence time constant. This implies that electrons had more than enough energy to cause reactions such that the same fraction of methane could be reacted even with an increase in the ratio of methane molecules to electrons.

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Methane Coupling to Ethylene and Longer-Chain Hydrocarbons by Low-Energy Electrical Discharge in Microstructured Reactors

Cited by 6 publications

References 32 publications

CO₂ Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling

CO₂ Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling

Longevity Demonstration of Methane to C2 via a Nonthermal Plasma Microreactor

Parametric Study of Hydrocarbon Chain Growth from Methane via a Nonthermal Plasma Discharge Microreactor

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Methane Coupling to Ethylene and Longer-Chain Hydrocarbons by Low-Energy Electrical Discharge in Microstructured Reactors

Cited by 6 publications

References 32 publications

CO2 Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling

CO2 Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling

Longevity Demonstration of Methane to C2 via a Nonthermal Plasma Microreactor

Parametric Study of Hydrocarbon Chain Growth from Methane via a Nonthermal Plasma Discharge Microreactor

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Product

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CO₂ Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling

CO₂ Reduction by Multiple Low-Energy Electric Discharges in a Microstructured Reactor: Experiments and Modeling