Emissionspectroscopic Investigation of Bci<sub>3</sub> Discharges

Breitbarth, F. W.; Ducke, E.

doi:10.1002/ctpp.2150300514

Cited by 6 publications

(5 citation statements)

References 8 publications

(7 reference statements)

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“…Its main advantages in comparison to later methods [52,53,55,56] are: (i) the possibility of taking into account various secondary excitation (stepwise excitation, dissociative recombination, etc) and deactivation processes (collisional quenching, stepwise ionization, etc) [51,57]; and (ii) its ability to work with arbitrary shapes of the EEDF, which is known to be far from Maxwellian in hydrogen-containing discharge plasmas (see, e.g. [7]). The necessity for absolute spectroscopic and Langmuir probe measurements is its main disadvantage.…”

Section: Methodsmentioning

confidence: 99%

“…Only a limited number of studies using the spectroscopic approach for boron containing plasmas can be found in the literature. Breitbarth and Ducke used optical emission spectroscopy (OES) to study excitation channels using intensity-time functions of selected emissions in the active phase and the afterglow of the pulsed RF discharge in BCl 3 and BCl 3 -Ar [7]. Schaffnit et al [14] utilized a RF discharge in BCl 3 -N 2 -H 2 -Ar mixtures for BN coating by PECVD.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

On the spectroscopic detection of neutral species in a low-pressure plasma containing boron and hydrogen

Lavrov

Osiac²,

Pipa

et al. 2003

Plasma Sources Sci. Technol.

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Spectroscopic studies of microwave discharges in H 2 -Ar-B 2 H 6 gas mixtures (f = 2.45 GHz, P = 1.2-3.5 kW, p = 1-8 mbar) have been performed to improve the possibilities of diagnostics of non-equilibrium, low-pressure plasmas containing boron and hydrogen. For this purpose, UV-VIS optical emission spectroscopy and infrared absorption spectroscopy with tunable diode lasers (TDLAS) have been applied. It is shown that information about neutral species and the gas temperature may be obtained by means of new and modified spectroscopic methods. A method for the determination of the absolute number density of boron atoms from measured relative intensities of the components of the boron resonance doublet (distorted by reabsorption) is proposed and tested for validity. The maximum of the density was found to be 3.8 × 10 11 atoms cm −3 at an admixture of diborane of about 2%. The gas temperature was determined from the intensity distributions in the rotational structure of the emission bands of BH and H 2 and from Doppler broadening of the absorption line profiles of the BH molecule. It was observed that values of the gas temperature obtained from the rotational intensity distributions are in good agreement with those obtained from Doppler widths (T g = 700-1070 K). Based on measurements of the relative line intensities of atomic and molecular hydrogen and the gas temperature, and using a simple excitation-deactivation model, the density of molecular hydrogen was found to be about 40 times higher than the density of atomic hydrogen. It is shown that some absorption lines of boron hydrides (B 2 H 6 , BH 3 and BH) detected by TDLAS may be used for plasma diagnostics.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

On the spectroscopic detection of neutral species in a low-pressure plasma containing boron and hydrogen

Lavrov

Osiac²,

Pipa

et al. 2003

Plasma Sources Sci. Technol.

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“…The spectroscopic determination of the degree of dissociation of hydrogen in non-equilibrium plasmas was first reported in [9][10][11] and further developed in [12][13][14][15][16]. Recently it was shown that an account of the fine structure in balance equations is very important for the calculation of emission rate coefficients of direct and dissociative excitation of H α and H β lines [17].…”

Section: Methodsmentioning

confidence: 99%

On the Reaction Kinetics of Chemically Active Molecular Microwave Plasmas

Stancu

Pipa

Lombardi

et al. 2005

Contrib. Plasma Phys.

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Key words Microwave plasmas, reaction kinetics, degree of dissociation, hydrogen, methyl radical, quantum cascade laser, boron monoxide. PACS 52. 20, 52.25, 52.75, 52.80 Recent studies of phenomena in molecular non-equilibrium microwave plasmas, which have been performed within the framework of the DFG-Sonderforschungsbereich 198, project A12, are presented in this review article. Special attention is devoted to the properties and kinetics of transient molecular species. The experimental methods used were optical emission and absorption spectroscopy. The main objectives of this contribution were threefold: (i) the determination of the degree of dissociation of hydrogen in plasmas, (ii) the quantitative detection of the methyl radical, and (iii) plasma process monitoring using quantum cascade lasers.

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“…This process was found to be very efficient in low-pressure (10-40 Pa) r.f. discharges where BCl 3 degree of decomposition is low [13].…”

Section: Production Of Radiative Species In Ar-bcl 3 Dischargementioning

confidence: 99%

“…A discussion on B 2 band emission is reported in [5] with new observed transitions from this molecule. Atomic boron lines (λ = 208.9 and 249.7 nm) which are currently used to characterize BCl 3 plasma [11][12][13][14] cannot be detected with our OES arrangement. As concerns the three unidentified transitions (λ = 563.5 nm, 581.9 nm and 582.2 nm) reported in our previous study of this Ar-BCl 3 microwave plasma [5], the line at λ = 563.5 nm is now assigned to the 4p 2 P 0 → 3s 2 S transition of atomic boron.…”

Section: The Ar-bcl 3 Plasma Emissionmentioning

confidence: 99%

Kinetics of boron atoms in Ar- flowing microwave discharges

Pierson¹,

Czerwiec²,

Belmonte³

et al. 1998

Plasma Sources Sci. Technol.

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Production of boron atoms has been investigated in Ar-BCl 3 flowing microwave discharges (2450 MHz) for two different configurations at 700 Pa. In the first one, an Ar-1.5% BCl 3 gas mixture is introduced in the discharge condition, while the same gas mixture is introduced downstream of a pure argon plasma in the second one. Optical emission spectroscopy (OES) has been used to follow the spatial variations of line and band intensities for various excited species (Ar, B, B + , B 2 , BO, Si, Cl and BCl). Variations of electron density along the plasma column, deduced from OES observations, are attributed to electron attachment reactions involving boron trichloride. Excitation processes leading to formation of excited species are discussed by analysing the OES results acquired in the two discharge configurations. For B, B + , B 2 and BCl species, excitation proceeds from electronic collisions with ground states, whereas a complex kinetic process is found for chlorine atom excitation.It is also shown that information on boron atoms could be gained by using the chimiluminescent reaction produced between boron atoms and molecular oxygen. A boron atom lifetime of about 10 −3 s is obtained by introducing an Ar-O 2 gas mixture in Ar-BCl 3 post-discharges.

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Emissionspectroscopic Investigation of Bci₃ Discharges

Cited by 6 publications

References 8 publications

On the spectroscopic detection of neutral species in a low-pressure plasma containing boron and hydrogen

On the spectroscopic detection of neutral species in a low-pressure plasma containing boron and hydrogen

On the Reaction Kinetics of Chemically Active Molecular Microwave Plasmas

Kinetics of boron atoms in Ar- flowing microwave discharges

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Emissionspectroscopic Investigation of Bci3 Discharges

Cited by 6 publications

References 8 publications

On the spectroscopic detection of neutral species in a low-pressure plasma containing boron and hydrogen

On the spectroscopic detection of neutral species in a low-pressure plasma containing boron and hydrogen

On the Reaction Kinetics of Chemically Active Molecular Microwave Plasmas

Kinetics of boron atoms in Ar- flowing microwave discharges

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Product

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About

Emissionspectroscopic Investigation of Bci₃ Discharges