Electrical and plasma characteristics of a quasi-steady sliding discharge

SOSA R.; KELLY, H. GRONDONA, D. MÁRQUEZ, A.; LAGO V.; ARTANA, G,

JOURNAL OF PHYSICS - D (APPLIED PHYSICS)

IOP PUBLISHING LTD

Año: 2008 vol. 41 p. 35202 - 35202

0022-3727

A quasi-steady sliding discharge at atmospheric pressure is generated by combining a surface dielectric barrier together with a DC corona discharge in a three-electrode geometry. The discharge extends along the whole side-length of the electrodes (150 mm) and covers the full inter-electrode gap (30 mm). It is found that this discharge is composed of repetitive streamers that are uniformly distributed along the whole electrode length and that propagate along the inter-electrode gap with an average velocity of ¡­2 ¡¿ 107 cm s−1, and with an average electric field of ¡­120 kV cm−1 and a total particle number of ¡­5 ¡¿ 108 at the streamer head. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. field of ¡­120 kV cm−1 and a total particle number of ¡­5 ¡¿ 108 at the streamer head. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. field of ¡­120 kV cm−1 and a total particle number of ¡­5 ¡¿ 108 at the streamer head. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. ¡­2 ¡¿ 107 cm s−1, and with an average electric field of ¡­120 kV cm−1 and a total particle number of ¡­5 ¡¿ 108 at the streamer head. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. ¡­120 kV cm−1 and a total particle number of ¡­5 ¡¿ 108 at the streamer head. Assuming that the electron distribution function reaches an equilibrium value with the electric field, an electron temperature of 9 eV at the streamer head is obtained. The streamer frequency is around 5 ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. electron density amounts to 1.5 ¡¿ 107 cm−3. ¡¿ 104 Hz for a well-developed sliding discharge regime, and the time-averaged electron density amounts to 1.5 ¡¿ 107 cm−3..5 ¡¿ 107 cm−3.