Theoretical cross sections for electron collisions relevant for ammonia discharges part 1: NH<sub>3</sub>, NH<sub>2</sub>, and NH

Snoeckx, Ramses; Tennyson, Jonathan; Cha, Min Suk

doi:10.1088/1361-6595/ad0d07

Cited by 3 publications

(1 citation statement)

References 87 publications

(182 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The cross-section is obtained from the LXCat/Morgan database [71]. Following recent findings [72,73], we updated the calculations for the cracking reactions of NH 3 by electron impact. Before, these rates were a function of the electron temperature [13].…”

Section: A2 Volume Reactionsmentioning

confidence: 99%

Ammonia synthesis by plasma catalysis in an atmospheric RF helium plasma

Vervloedt,

von Keudell

2024

Plasma Sources Sci. Technol.

View full text Add to dashboard Cite

The in-plasma-catalytic synthesis of ammonia from nitrogen and hydrogen admixed to a helium RF plasma is studied with infrared absorption spectroscopy, optical emission spectroscopy, and through chemical kinetics modeling. Sandblasted glass is used as support for iron, platinum, and copper catalysts up to a surface temperature of 150 ○C. It is shown that the optimum ammonia production occurs at very small N2/(N2+H2) ratios with an increase of concentration with plasma power. The global kinetic modelling agrees well with the data for a variation of the N2+H2 admixture and the absorbed plasma power. The introduction of the catalyst enhances ammonia production by up to a factor of 2. Based on the comparison with the modelling, this is linked to a change in the electron kinetics due to the presence of the catalyst. It is postulated that introducing the catalyst increases the reduced electric field, because it reduces the secondary electron emission coefficient. As a result, the dissociation of N2 is stimulated, thereby enhancing the NH3 formation. These experiments show that the impact of the catalyst on the plasma performance in noble gas-diluted RF plasmas can be more important than the impact of the plasma on any catalytic surface process.

show abstract

Section: A2 Volume Reactionsmentioning

confidence: 99%

Ammonia synthesis by plasma catalysis in an atmospheric RF helium plasma

Vervloedt,

von Keudell

2024

Plasma Sources Sci. Technol.

View full text Add to dashboard Cite

show abstract

Calculation of thermodynamic properties and transport coefficients of Ar / N 2

Cheng,

Xianhui,

Yunfei

et al. 2024

J. Phys. D: Appl. Phys.

View full text Add to dashboard Cite

The composition, thermodynamic properties and transport coeﬃcients of Ar-H2-Si and N2-H2-Si plasma within a temperature range of 300-30,000 K and pressure range of 0.1-10 atm are calculated under the assumptions of local thermal equilibrium (LTE) and local chemical equilibrium (LCE). Taking Debye-Hückel corrections into account, the chemical equilibrium composition and thermodynamic properties of these two plasma systems are derived using the mass action law and classical statistical thermodynamics respectively. The transport coeﬃcients, including viscosity, conductivity, and thermal conductivity, are calculated using the Chapman-Enskog (C-E) method extended to a third-order approximation (second-order for viscosity and heavy particle translational thermal conductivity). Some of the results have been compared with those of other researchers, and there is a good level of agreement. The slight diﬀerence arises from the selection of interaction potential. The ﬁnal calculation reveals that the introduction of silicon vapor signiﬁcantly alters the thermodynamic properties and transport coeﬃcients of Ar⁄N2-H2-Si plasma, even at a small concentration of silicon vapor (1%), the eﬀect on the electrical conductivity can not be ignored. Furthermore, our calculation results provide the fundamental data for numerical simulations of magnetohydrodynamics (MHD) for the synthesis of silicon nanoparticles and silicon composites.

show abstract

BEB-based models for ionisation cross sections of electron and positron impact with diatomic molecules

Graves

2024

Eur. Phys. J. D

View full text Add to dashboard Cite

The ionising interactions of high-energy particles with molecules have applications in many areas. Despite this, some areas, including positron scattering, lack experimental data due to difficulties in performing experiments. Here, quick and simple methods for computing direct electron and positron impact ionisation cross sections are presented. These calculations, performed using the open-source software RAPID-CS, can provide a complete data set as a first approximation for when experimental, or more detailed computational work is not available. The cross-sectional data set includes the total, partial/fragment-specific, single-differential, average secondary electron energy and stopping power cross sections. The molecules N$$_2$$ 2 , O$$_2$$ 2 and CO were chosen to study due to the availability of positron scattering data. An overall good agreement with experimental and other computational results is presented. Graphical abstract Direct electron (left) and positron right) impact partial ionisation cross sections for N2. Total cross section: red, $$N^{+}_{2}$$ N 2 + partial cross section: blue, N$$^{+}$$ + partial cross section: green.electron: solid lines: BEB, experimental measurements by Lindsay and Mangan [36]:Ürosses, Straub et al. [37]: stars, Opel et al. [39]: squares. Positron: solid lines: BEB0, Dashed lines: BEBA, Marler and Surko [23]: red crosses, Bluhme et al. [24]: stars

show abstract

Theoretical cross sections for electron collisions relevant for ammonia discharges part 1: NH₃, NH₂, and NH

Cited by 3 publications

References 87 publications

Ammonia synthesis by plasma catalysis in an atmospheric RF helium plasma

Ammonia synthesis by plasma catalysis in an atmospheric RF helium plasma

Calculation of thermodynamic properties and transport coefficients of Ar / N 2

BEB-based models for ionisation cross sections of electron and positron impact with diatomic molecules

Contact Info

Product

Resources

About

Theoretical cross sections for electron collisions relevant for ammonia discharges part 1: NH3, NH2, and NH

Cited by 3 publications

References 87 publications

Ammonia synthesis by plasma catalysis in an atmospheric RF helium plasma

Ammonia synthesis by plasma catalysis in an atmospheric RF helium plasma

Calculation of thermodynamic properties and transport coefficients of Ar / N 2

BEB-based models for ionisation cross sections of electron and positron impact with diatomic molecules

Contact Info

Product

Resources

About

Theoretical cross sections for electron collisions relevant for ammonia discharges part 1: NH₃, NH₂, and NH