&lt;title&gt;Pulsed HF chemical laser using a VUV phototriggered discharge&lt;/title&gt;

Brunet, H.; Mabru, Michel; Serra, J.; Vannier, C.

doi:10.1117/12.25955

Cited by 5 publications

(14 citation statements)

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“…HF lasers energized by electrical discharges have been the subject of many studies [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15]. The best laser performances, namely the maximum output energy and electrical efficiency, have been achieved using pre-ionized pulsed discharges between flat electrodes and reactive gas mixtures which contain H 2 and F 2 molecules [6,7].…”

Section: Introductionmentioning

confidence: 99%

The influence of and molecules on discharge equilibrium and F-atom production in a phototriggered HF laser using

Richeboeuf¹,

Pasquiers²,

Legentil³

et al. 1998

J. Phys. D: Appl. Phys.

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The discharge equilibrium and the F-atom production kinetics in a phototriggered HF laser using gas mixtures containing Ne and with hydrogen or ethane have been investigated. Coupled experimental and theoretical studies have been carried out, through a 0D discharge modelling and measurements of the current, of the voltage and of the extracted laser energy, together with emission spectroscopy on F 3p excited states. A quantitative comparison of the total F-atom density produced in mixtures of with or is performed and the results are compared with the discharge pumped HF laser performance achieved with these molecules. An overall validation of the model has been obtained, both for the energy transfer to the active media and for the kinetics of F and its excited states. It is shown that the transmitted energy and electrical charge, as well as the discharge electric field, weakly depend on the type and on the concentration of the RH molecule, or , in the gas mixtures. Moreover, the F-atom production depends very slightly on the nature of RH. Therefore the fact that the laser performance achieved with hydrogen is lower than the performance achieved with ethane is not due to differences in the energy transfer and in the F-atom production kinetics in mixtures of with or .

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Section: Introductionmentioning

confidence: 99%

The influence of and molecules on discharge equilibrium and F-atom production in a phototriggered HF laser using

Richeboeuf¹,

Pasquiers²,

Legentil³

et al. 1998

J. Phys. D: Appl. Phys.

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“…Therefore in the given case it is expedient to initiate SIVD, for example, by a low-current spark located either outside the discharge gap or in a hole on the cathode [5]. In principle, this regime is similar to a "photo triggered discharge" mode [15,17,28]. However in classical "photo triggered discharge" schemes applied to excimer lasers, a powerful illumination of the gap is necessary since this illumination serves the dual function of initiating breakdown and producing the necessary primary electron number density in a gas medium.…”

Section: Nonchain Hf(df) Lasers Excited By Sivdmentioning

confidence: 96%

“…(Regardless of lasers, SSVD can in principle be obtained in a highly nonuniform field, for instance, in the rod-plane gap.) Clearly the first condition cannot be practically met in such strongly electronegative gas as SF6 [5,7] because of great losses of primary electrons due to electron attachment except for the special "photo triggered discharge" mode [15], which, however, is ineffective for energy input into molecular gases owing to low over-voltages at the gap and, in the case of large discharge gaps and active medium volumes (large-sized electrodes), is not realized at all. On increase of the laser aperture and discharge volume, the problem also arises as to how to meet the second condition because of both technical difficulties in fabrication of large-sized intricate shape electrodes and in connection with rise of the discharge circuit inductance caused by a useless growth in the transverse sizes ofthe electrodes [3,4].…”

Section: Dischargementioning

confidence: 98%

High-power pulse and pulse-periodic nonchain HF (DF) lasers

et al. 2002

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This paper reports on the physics of a self-sustained volume discharge without preionization, self-initiated volume discharge (SIVD), in working mixtures of nonchain HF(DF) lasers. Dynamics of SIVD in discharge gaps of different geometry is thoroughly described. The mechanisms of restricting current density in a diffuse channel in electric discharges in SF6 and SF6 based mixtures determining the possibility of the existence of SIVD were suggested and analyzed using simple models. It is shown that the most probable mechanisms are the electron impact dissociation of SF6 and other mixture components, electron-ion recombination and electron attachment to vibrationally excited SF6 molecules. Starting from a comparison analysis of the rate coefficients of these processes, it was found that the electron-ion recombination is capable of compensating for electron detachment from negative ions by electron impact. It is established that SIVD can be observed not only in SF6, but in other strongly electronegative gases, e. g., in C3F8 and C3HC13. Analysis is given of the factors determining uniformity of active medium in nonchain HF(DF) lasers. Some special features of operating nonchain HF(DF) lasers with small, 2÷6cm, apertures are carefully examined and the results of measuring the nonchain HF(DF) laser divergence are presented. Consideration is given to the problem increasing the aperture and discharge volume of nonchain HF(DF) lasers and, based from the experimental results, the possibility is shown of increasing their energy to a level of lkJ and above.

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“…Clearly, the irst condition cannot be observed in such a strongly electronegative gas as SF 6 [5,7] because of the great primary electron losses from electron attachment, except for in the special 'photo triggered discharge' mode [15], which, however, is ineffective for energy input into molecular gases because of the low over-voltages at the gap and, in the case of large discharge gaps and active medium volumes, it is not realized at all. With increasing laser aperture and discharge volume, the problem of how to meet the second condition also arises-there are tech nical dif iculties regarding the fabrication of large-sized intricate-shaped electrodes and the rise of the discharge circuit inductance caused by a useless growth in the trans verse size of the electrodes [3,4].…”

Section: A New Form Of Ssvdmentioning

confidence: 99%

“…Therefore, in the given case, it is expedient to initiate SIVD by, for example, a low-current spark located either outside the discharge gap or in a hole on the cathode [5]. In principle, this regime is similar to a 'photo triggered discharge' mode [15,17,27]. However, in classical photo trig gered discharge schemes being applied to excimer lasers, a powerful illumination of the gap is necessary, since this illu mination serves the dual function of initiating the breakdown and producing the necessary primary electron number density in a gas medium.…”

Section: Non-chain Hf (Df) Lasers Pumped By Sivdmentioning

confidence: 99%

High energy HF (DF) lasers

Аполлонов¹

2018

J Phys Res Appl

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<title>Pulsed HF chemical laser using a VUV phototriggered discharge</title>

Cited by 5 publications

References 0 publications

The influence of and molecules on discharge equilibrium and F-atom production in a phototriggered HF laser using

The influence of and molecules on discharge equilibrium and F-atom production in a phototriggered HF laser using

High-power pulse and pulse-periodic nonchain HF (DF) lasers

High energy HF (DF) lasers

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