Isotope Labelling for Reaction Mechanism Analysis in DBD Plasma Processes

Navascués, Paula; Obrero‐Perez, Jose M.; Cotrino, José; González‐Elipe, Agustín R.; Gómez‐Ramírez, Ana

doi:10.3390/catal9010045

Cited by 16 publications

(20 citation statements)

References 31 publications

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“…At higher plasma power, however, ammonia may decompose in micro-discharges. 55,61,62 Fig. 8 shows good correlations between the NH 3 concentration measured at 450°C and plasma power.…”

Section: Catalysis Science and Technologymentioning

confidence: 81%

Plasma-catalytic ammonia synthesis beyond thermal equilibrium on Ru-based catalysts in non-thermal plasma

Rouwenhorst

Burbach

Vogel

et al. 2021

Catal. Sci. Technol.

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“…At higher plasma power, however, ammonia may decompose in micro-discharges. 55,61,62 Fig. 8 shows good correlations between the NH 3 concentration measured at 450°C and plasma power.…”

Section: Catalysis Science and Technologymentioning

confidence: 81%

Plasma-catalytic ammonia synthesis beyond thermal equilibrium on Ru-based catalysts in non-thermal plasma

Rouwenhorst

Burbach

Vogel

et al. 2021

Catal. Sci. Technol.

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“…It has been previously used to study different plasma-catalysis reactions, as the synthesis of ammonia, methane reforming, or the elimination of pollutants. [2,5,7,8,20] Figure 1 shows a sketch of the reactor set-up. Upper and bottom SS electrodes were separated by a pellet bed formed by a single packed layer of 3-mm pellets made of either dielectric (alumina [Al 2 O 3 ] and glass beads) or ferroelectric materials (barium titanate [BaTiO 3 ] and lead zirconate titanate [PZT]), respectively.…”

Section: Methodsmentioning

confidence: 99%

Electrical and reaction performances of packed‐bed plasma reactors moderated with ferroelectric or dielectric materials

Gómez‐Ramírez

Álvarez

Navascués

et al. 2020

Plasma Processes & Polymers

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The operational behavior of packed‐bed plasma reactors depends on the dimension, shape, and chemical properties of the pellets used as moderators, but little information exists about the influence of their specific dielectric properties. Herein, we comparatively study the electrical behavior of a packed‐bed reactor filled with pellets of either dielectric (Al2O3 and glass) or ferroelectric (BaTiO3 and lead zirconate titanate) materials. We found that plasma current was higher for ferroelectrics and presented a nonlineal dependence on voltage. Moreover, for BaTiO3, we found a drastic decrease at around its relatively low Curie temperature. Differences in electrical behavior have a direct effect on the reactor performance, as illustrated for the ammonia synthesis, demonstrating the importance of moderator material dielectric properties and their dependence on temperature.

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“…1.2% of the global CO 2 emissions . The requisite of combining the reduction of energy consumption with the production of ammonia in a distributed way close to final users has called for an active investigation of a variety or alternative processes, including plasma catalysis. − ,− A second motivation of this work is the use of ammonia as a suitable hydrogen storage vector and the advantages, with respect to classical catalysis, − of small plasma reactors for its low temperature decomposition into hydrogen, as required for mobile device applications.…”

Section: Introductionmentioning

confidence: 99%

Unraveling Discharge and Surface Mechanisms in Plasma-Assisted Ammonia Reactions

Navascués

Obrero‐Perez

Cotrino

et al. 2020

ACS Sustainable Chem. Eng.

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Current studies on ammonia synthesis by means of atmospheric pressure plasmas respond to the urgent need of developing less environmentally aggressive processes than the conventional Haber–Bosch catalytic reaction. Herein, we systematically study the plasma synthesis of ammonia and the much less investigated reverse reaction (decomposition of ammonia into nitrogen and hydrogen). Besides analyzing the efficiency of both processes in a packed-bed plasma reactor, we apply an isotope-exchange approach (using D2 instead of H2) to study the reaction mechanisms. Isotope labeling has been rarely applied to investigate atmospheric plasma reactions, and we demonstrate that this methodology may provide unique information about intermediate reactions that, consuming energy and diminishing the process efficiency, do not effectively contribute to the overall synthesis/decomposition of ammonia. In addition, the same methodology has demonstrated the active participation of the interelectrode material surface in the plasma-activated synthesis/decomposition of ammonia. These results about the involvement of surface reactions in packed-bed plasma processes, complemented with data obtained by optical emission spectroscopy analysis of the plasma phase, have evidenced the occurrence of inefficient intermediate reaction mechanisms that limit the efficiency and shown that the rate-limiting step for the ammonia synthesis and decomposition reactions are the formation of NH* species in the plasma phase and the electron impact dissociation of the molecule, respectively.

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Isotope Labelling for Reaction Mechanism Analysis in DBD Plasma Processes

Cited by 16 publications

References 31 publications

Plasma-catalytic ammonia synthesis beyond thermal equilibrium on Ru-based catalysts in non-thermal plasma

Plasma-catalytic ammonia synthesis beyond thermal equilibrium on Ru-based catalysts in non-thermal plasma

Electrical and reaction performances of packed‐bed plasma reactors moderated with ferroelectric or dielectric materials

Unraveling Discharge and Surface Mechanisms in Plasma-Assisted Ammonia Reactions

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