0D Kinetic Modeling of Noble Gas Mixed N<sub>2</sub>-H<sub>2</sub> Plasmas for Ammonia Synthesis
POSTER
Abstract
J.B. HALL, Z. LIN, S. ABE, Z. CHEN, S. JAISWAL, A. DIALLO (PPPL), B.E. KOEL Princeton U. -
A zero-dimensional (0D) kinetic model has been developed for N2-H2-noble gas (He or Ar) atmospheric pressure plasmas based on the ZDPlasKin plasma kinetics solver [1] to understand both the volumetric and surface (Ru or Fe on ??-Al2O3) reactions related to plasma-assisted catalysis as a potentially lower energy alternative to the standard Haber-Bosch process for ammonia synthesis. Results have shown that the dominant metastables, Armeta (1s5 and 1s3) and He(23S), formed via electron-impact excitation, can support N atom and ion formation through the reactions N2 + Armeta → 2N + Ar and N2 + He(23S) → N + N+ + He + e. These N species play an important role in NH3 formation via N + H2* →NH + H (H2* is an electronically excited species) in our dielectric barrier discharge reactor for electron number densities 106-1010 cm-3. Effects of the neutral gas flow rates for both He and Ar on the plasma chemistry are also investigated. We pair the He modeling results with a He Collisional-Radiative (CR) model for plasma diagnostics and compare with He line intensity ratios experimentally obtained by optical emission spectroscopy.
[1] S. Pancheshnyi et al., 2008 Computer code ZDPlasKin (www.zdplaskin.laplace.univ-tlse.fr)
A zero-dimensional (0D) kinetic model has been developed for N2-H2-noble gas (He or Ar) atmospheric pressure plasmas based on the ZDPlasKin plasma kinetics solver [1] to understand both the volumetric and surface (Ru or Fe on ??-Al2O3) reactions related to plasma-assisted catalysis as a potentially lower energy alternative to the standard Haber-Bosch process for ammonia synthesis. Results have shown that the dominant metastables, Armeta (1s5 and 1s3) and He(23S), formed via electron-impact excitation, can support N atom and ion formation through the reactions N2 + Armeta → 2N + Ar and N2 + He(23S) → N + N+ + He + e. These N species play an important role in NH3 formation via N + H2* →NH + H (H2* is an electronically excited species) in our dielectric barrier discharge reactor for electron number densities 106-1010 cm-3. Effects of the neutral gas flow rates for both He and Ar on the plasma chemistry are also investigated. We pair the He modeling results with a He Collisional-Radiative (CR) model for plasma diagnostics and compare with He line intensity ratios experimentally obtained by optical emission spectroscopy.
[1] S. Pancheshnyi et al., 2008 Computer code ZDPlasKin (www.zdplaskin.laplace.univ-tlse.fr)
Presenters
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James B Hall
Princeton University
Authors
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James B Hall
Princeton University
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Shota Abe
Princeton University
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Zhe Chen
Princeton University
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Zihan Lin
Princeton University
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Surabhi Jaiswal
Princeton University, Eastern Michigan University
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Ahmed Diallo
Princeton Plasma Physics Laboratory
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Bruce E Koel
Princeton University