Investigation of the neon 2p collisional excitation transfer processes via CW laser collisionally induced fluorescence

Paterson, Alex; Smith, David J.; Borthwick, I S; Stewart, R.

doi:10.1088/0953-4075/34/9/316

Cited by 6 publications

(12 citation statements)

References 18 publications

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“…Analysis of several emission lines and populations (from absorption spectroscopy) provides a range of information and enhances the reliability of the determination. We have combined these widely used optical diagnostic techniques with related methods [9][10][11][12] which provide extensive information on the kinetics between the excited states, allowing sampling of the EDF across a wide range of electron energies.…”

Section: Introductionmentioning

confidence: 99%

Complementary optical diagnostics for determination of rate coefficients and electron temperatures in noble gas discharges

Smith

Whitehead

Stewart

2002

Plasma Sources Sci. Technol.

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We utilize an array of related optical diagnostics to deliver quantitative description of each process involving the 15 lowest levels in neon, for reduced electric fields ranging from 3 × 10 −16 to 2 × 10 −16 V cm 2 (3-20 Td). Description of the kinetics between the 1s and 2p excited states (Paschen notation) has been obtained using CW laser collisionally induced fluorescence (i.e. fluorescence from a non-excited upper level). We have employed this technique in combination with the traditional optical emission and absorption spectroscopic studies to determine the rate coefficients describing electron-collisional excitation from the ground to the 1s and 2p states. These values, along with previously determined 1s-2p rate coefficients, have been used with current literature cross sections to provide information on the electron distribution function for energy bands of 2-8, 16.9-23.0 and 19.0-25.5 eV. Values of the electron temperatures obtained from our 1s coefficients were used for an extensive study of the ground state to 1s excitation functions. From 3 to 20 Td, the average values of the temperature corresponding to the 1s excitations ranged from 1.8 to 3.1 eV, while those from 2p excitation were in the range 1.6-2.9 eV. Our investigation of the bulk temperature using data for 1s-2p excitation suggests a scaling of ∼0.5 for the published theoretical excitation function, which is supported by the new experimental cross sections of Boffard et al.A quantitative description of cascade to the 1s states is also presented, showing that at the top of our reduced field range, cascade from the 2p states contributes 29-35% of the total excitation rates from the ground state.

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Section: Introductionmentioning

confidence: 99%

Complementary optical diagnostics for determination of rate coefficients and electron temperatures in noble gas discharges

Smith

Whitehead

Stewart

2002

Plasma Sources Sci. Technol.

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“…The partial differentials are obtained using the expression for I jJ , the intensity of the 2p j -1s J transition, given in equation ( 4). The theoretical modelling and evaluation of all of these terms in equation ( 6) and their relative contributions are discussed in detail in our previous publications [6][7][8] for a number of different typical cases. Equation ( 6) may be solved to obtain the final expression [6]: where β jJ is the branching ratio from 2p j to 1s J , including collisional depletion routes and δ jJ is given by…”

Section: Cw Laser Collisionally Induced Fluorescencementioning

confidence: 99%

“…The results we report here constitute part of ongoing development and application of our complementary approach to optical diagnostics of low-temperature plasmas based on the excited-state kinetics of noble gas atoms in the metastable and resonance states. In previous studies [6][7][8][9][10] we used the well-behaved neon positive column plasma to demonstrate the diagnostic power of combining two steady-state techniques (optical emission and absorption spectroscopy (OES and OAS)) with two CW laser-perturbed steady-state techniques (the optogalvanic effect (OGE) and laser collisionally induced fluorescence (LCIF)). In this work we describe our models for the argon 1s populations, emission line ratios and the CW LCIF spectra observed for laser excitation out of the 1s 5 state.…”

Section: Introductionmentioning

confidence: 99%

Complementary optical diagnostic modelling of the argon positive column

Stewart

Smith

2002

J. Phys. D: Appl. Phys.

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The argon positive column has been investigated by means of a complementary diagnostic approach, which combines the CW laser collisionally induced fluorescence (LCIF) technique with kinetic models for the excited-state populations and emission line ratios. The conditions ranged from pressures of 0.30-8.0 Torr and currents of 1-10 mA, equivalent to reduced axial electric fields of 1.7-53 Td. Fitting theory to experimental observations of the 1s densities and 2p-1s emission intensities allows determination of the electron temperatures relating to the high-energy electrons in the tail of the electron energy distribution function. The tail temperatures vary from 0.9 to 1.9 eV over the range of conditions investigated. Examination of CW LCIF for 1s5-2p2 (696.5 nm) laser excitation along with the traditional optical absorption and emission techniques provides specific information on the collisional kinetics involving the metastable states.

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“…Therefore we consider collisions of Ne(2 p 5 3 p ) with He and Ne, where Penning ionization cannot occur. Ne(2 p 5 3 p ) + Ne collisions have been studied by several investigators. − Chang and Setser found that the 3 p [1/2] 1 level is quenched (loss to levels outside of the 2 p 5 3 p manifold) with a rate constant of 1.7 × 10 –11 cm 3 s –1 , which is too fast for the proposed application. Collisions between Ne(2 p 5 3 p ) and He have also been examined, ,,− but all of the state-to-state transfer measurements have focused on the higher energy levels (in part because the 632.8 nm line of the HeNe laser terminates on the 3 p ′[3/2] 2 level).…”

Section: Introductionmentioning

confidence: 99%

Energy Transfer Kinetics of the np⁵(n + 1)p Excited States of Ne and Kr

Kabir

2011

J. Phys. Chem. A

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Energy transfer rate constants for Ne(2p(5)3p) and Kr(4p(5)5p) atoms colliding with ground state rare gas atoms (Rg) have been measured. In part, this study is motivated by the possibility of using excited rare gas atoms as the active species in optically pumped laser systems. Rg(np(5)(n + 1)s) metastable states may be produced using low-power electrical discharges. The potential then exits for optical pumping and laser action on the np(5)(n + 1)p ↔ np(5)(n + 1)s transitions. Knowledge of the rate constants for collisional energy transfer and deactivation of the np(5)(n + 1)p states is required to evaluate the laser potential for various Rg + buffer gas combinations. In the present study we have characterized energy transfer processes for Ne (2p(5)3p) + He for the six lowest energy states of the multiplet. Rate constants for state-to-state transfer have been determined. Deactivation of the lowest energy level of Kr (4p(5)5p) by He, Ne, and Kr has also been characterized. Initial results suggest that Kr (4p(5)5p) + Ne mixtures may be the best suited for optically pumped laser applications.

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Investigation of the neon 2p collisional excitation transfer processes via CW laser collisionally induced fluorescence

Cited by 6 publications

References 18 publications

Complementary optical diagnostics for determination of rate coefficients and electron temperatures in noble gas discharges

Complementary optical diagnostics for determination of rate coefficients and electron temperatures in noble gas discharges

Complementary optical diagnostic modelling of the argon positive column

Energy Transfer Kinetics of the np⁵(n + 1)p Excited States of Ne and Kr

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Investigation of the neon 2p collisional excitation transfer processes via CW laser collisionally induced fluorescence

Cited by 6 publications

References 18 publications

Complementary optical diagnostics for determination of rate coefficients and electron temperatures in noble gas discharges

Complementary optical diagnostics for determination of rate coefficients and electron temperatures in noble gas discharges

Complementary optical diagnostic modelling of the argon positive column

Energy Transfer Kinetics of the np5(n + 1)p Excited States of Ne and Kr

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Energy Transfer Kinetics of the np⁵(n + 1)p Excited States of Ne and Kr