Basic knowledge on radiative and transport properties to begin in thermal plasmas modelling

Cressault, Yann

doi:10.1063/1.4920939

Cited by 18 publications

(11 citation statements)

References 107 publications

(98 reference statements)

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“…This challenge is evidenced by the determination of absorption coefficients. State-of-the art computations use millions of wavelength intervals [28], as exemplified by the work on microwave discharges of air, CO 2 , and CO 2 -H 2 mixtures by Kassir et al [42], and on plasmas containing metal vapors by Gleizes and Cressault [37]. Moreover, Planck's emission law is not valid for a system in NLTE, and radiative emission is function of the local thermodynamic state.…”

Section: Radiative Nonequilibriummentioning

confidence: 99%

Nonequilibrium Phenomena in (Quasi-)thermal Plasma Flows

Trelles

2019

Plasma Chem Plasma Process

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Thermal plasmas are utilized in diverse applications that require high power densities or throughputs, such as metal cutting, welding, spraying, metallurgy, and materials synthesis. Thermal plasma applications involve interactions between the highly energetic plasma and working gas streams, confining devices, or processing materials. Whereas thermal plasma implies a state of equilibrium (i.e. Local Thermodynamic Equilibrium, LTE), due to the above interactions, thermal plasma flows depict nonequilibrium phenomena of two types: kinetic and dissipative. Kinetic nonequilibrium manifests microscopically and is caused by localized imbalances between particles and fields interactions. Its occurrence is evidenced, for example, as deviations from thermal equilibrium between heavy-species and electrons or from mass-action laws. In contrast, dissipative nonequilibrium reveals macroscopically and is produced by external driving forces that incite distributed responses, such as the growth of instabilities, the occurrence of self-organization, or the establishment of turbulence. Although kinetic nonequilibrium has been increasingly incorporated in thermal plasma flow models (e.g. finite-rate chemistry, two-temperature models), it is the great advances in numerical computing that is enabling the exploration of dissipative nonequilibrium (e.g. pattern formation, small-scale turbulent features). Both types of nonequilibrium are reviewed, including their estimation and incidence, within the context of computational models and their relevance to thermal plasma sources and processes.

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Section: Radiative Nonequilibriummentioning

confidence: 99%

Nonequilibrium Phenomena in (Quasi-)thermal Plasma Flows

Trelles

2019

Plasma Chem Plasma Process

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“…Since, more studies on the radiative transfer equation have been done for pure gases (SF 6 , N 2 , Air, CO 2 ), binary mixtures (SF 6 -C 2 F 4 , C 4 F 8 -CO 2 , CO 2 -Cu [3,24]) and ternary mixtures (SF 6 -C 2 F 4 -Cu/W) in 1D-2D-3D geometry with imposed temperatures profiles [25][26][27][28]. An example is given in Figure 1 for the divergence of the flux for a SF 6 pure plasma at 1bar, obtained with different approached methods [1].…”

Section: No /mentioning

confidence: 99%

State of Art and Challenges for the Calculation of Radiative and Transport Properties of Thermal Plasmas in HVCB

Cressault

Teulet

Baumann

et al. 2019

PPT

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This paper is focused on the state-of-the-art and challenges concerning the thermophysical properties of thermal plasmas used in numerical modelling devoted to high voltage circuit breakers. <br />For Local Thermodynamic Equilibrium (LTE) and Non-Local Thermodynamic (NLTE) and/or Chemical Equilibrium (NLCE) plasmas, the methods used to calculate the composition, thermodynamic, transport and radiative properties are presented. <br />A review of these last data is proposed and some comparisons are given for illustrations.

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“…The radiation coming from the continuum is due to freebound and free-free transitions. 1,9) The radiative recombination is calculated with the knowledge of the Biberman factors (for argon species only 10) ). As this factor is not available in the literature for other atomic species, we applied the hydrogen-like approach 11) with the knowledge of the energy levels, the statistical weights and the quantum numbers issued from NIST 12) and Kurucz et Peyterman databases.…”

Section: Continuous and Discontinuous Radiationmentioning

confidence: 99%

“…1) In order to reduce the computing time, we did not use the line-by-line approach and preferred to use the approximation of the escape factor even if the corresponding emission can be overestimated depending on the pressure. 38) According to Drawin and Emard, 9) this factor was previously computed as a function of optical depths and broadening phenomena: the Doppler broadening, the pressure effects (resonance and Van der Waals broadenings) and the Stark broadening. 9) As conclusion, we elaborated a complete data bank including the properties of 25068 atomic lines: 11705 lines for argon species (Ar, Ar + , Ar 2+ , Ar 3+ ), 438 for mercury (Hg, Hg + ), 5159 for calcium (Ca, Ca + , Ca 2+ , Ca 3+ ), 1392 for sodium (Na, Na + , Na 2+ , Na 3+ ), 1459 for tungsten (W, W + , W 2+ ), 717 for Dysprosium (Dy, Dy + ), 181 for strontium (Sr, Sr + ), and 17 lines for Thallium (Tl, Tl + ), Iodine was neglected.…”

Section: Continuous and Discontinuous Radiationmentioning

confidence: 99%

Radiative properties of ceramic metal-halide high intensity discharge lamps containing additives in argon plasma

Cressault¹,

Teulet²,

Zissis³

2016

Jpn. J. Appl. Phys.

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The lighting represents a consumption of about 19% of the world electricity production. We are thus searching new effective and environment-friendlier light sources. The ceramic metal-halide high intensity lamps (C-MHL) are one of the options for illuminating very high area. The new C-MHL lamps contain additives species that reduce mercury inside and lead to a richer spectrum in specific spectral intervals, a better colour temperature or colour rendering index. This work is particularly focused on the power radiated by these lamps, estimated using the net emission coefficient, and depending on several additives (calcium, sodium, tungsten, dysprosium, and thallium or strontium iodides). The results show the strong influence of the additives on the power radiated despite of their small quantity in the mixtures and the increase of visible radiation portion in presence of dysprosium.

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Basic knowledge on radiative and transport properties to begin in thermal plasmas modelling

Cited by 18 publications

References 107 publications

Nonequilibrium Phenomena in (Quasi-)thermal Plasma Flows

Nonequilibrium Phenomena in (Quasi-)thermal Plasma Flows

State of Art and Challenges for the Calculation of Radiative and Transport Properties of Thermal Plasmas in HVCB

Radiative properties of ceramic metal-halide high intensity discharge lamps containing additives in argon plasma

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