M. Walker scite author profile

Power‐to‐gas is a storage technology aiming to convert surplus electricity from renewable energy sources like wind and solar power into gaseous fuels compatible with the current network infrastructure. Results of CO2 dissociation in a vortex‐stabilized microwave plasma reactor are presented. The microwave field, residence time, quenching, and vortex configuration were varied to investigate their influence on energy‐ and conversion efficiency of CO2 dissociation. Significant deterioration of the energy efficiency is observed at forward vortex plasmas upon increasing pressure in the range of 100 mbar towards atmospheric pressure, which is mitigated by using a reverse vortex flow configuration of the plasma reactor. Data from optical emission shows that under all conditions covered by the experiments the gas temperature is in excess of 4000 K, suggesting a predominant thermal dissociation. Different strategies are proposed to enhance energy and conversion efficiencies of plasma‐driven dissociation of CO2.

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Polymorphism in Vanadyl Phthalocyanine

Griffiths

Walker

Goldstein

1976

Molecular Crystals and Liquid Crystals

121

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Sterilisation with low-pressure microwave plasmas

Feichtinger

Schulz

Walker

et al. 2003

Surface and Coatings Technology

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A novel plasma-assisted hollow fiber membrane concept for efficiently separating oxygen from CO in a CO2 plasma

Chen

Buck

Kistner

et al. 2020

Chemical Engineering Journal

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Spectroscopic Investigation of a Microwave‐Generated Atmospheric Pressure Plasma Torch

Leins

Walker

Schulz

et al. 2012

Contrib. Plasma Phys.

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The investigated new microwave plasma torch is based on an axially symmetric resonator. Microwaves of a frequency of 2.45 GHz are resonantly fed into this cavity resulting in a sufficiently high electric field to ignite plasma without any additional igniters as well as to maintain stable plasma operation. Optical emission spectroscopy was carried out to characterize a humid air plasma. OH-bands were used to determine the gas rotational temperature Trot while the electron temperature was estimated by a Boltzmann plot of oxygen lines. Maximum temperatures of Trot of about 3600 K and electron temperatures of 5800 K could be measured. The electron density ne was estimated to ne ≈ 3 · 10 20 m −3 by using Saha's equation. Parametric studies in dependence of the gas flow and the supplied microwave power revealed that the maximum temperatures are independent of these parameters. However, the volume of the plasma increases with increasing microwave power and with a decrease of the gas flow. Considerations using collision frequencies, energy transfer times and power coupling provide an explanation of the observed phenomena: The optimal microwave heating is reached for electron-neutral collision frequencies νen being near to the angular frequency of the wave ω.

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M. Walker

Plasma‐driven dissociation of CO₂ for fuel synthesis

Polymorphism in Vanadyl Phthalocyanine

Sterilisation with low-pressure microwave plasmas

A novel plasma-assisted hollow fiber membrane concept for efficiently separating oxygen from CO in a CO2 plasma

Spectroscopic Investigation of a Microwave‐Generated Atmospheric Pressure Plasma Torch

Contact Info

Product

Resources

About

M. Walker

Plasma‐driven dissociation of CO2 for fuel synthesis

Polymorphism in Vanadyl Phthalocyanine

Sterilisation with low-pressure microwave plasmas

A novel plasma-assisted hollow fiber membrane concept for efficiently separating oxygen from CO in a CO2 plasma

Spectroscopic Investigation of a Microwave‐Generated Atmospheric Pressure Plasma Torch

Contact Info

Product

Resources

About

Plasma‐driven dissociation of CO₂ for fuel synthesis