STREAMER DYNAMICS IN A MEDIA CONTAINING DUST PARTICLES* Natalia Yu. Babaeva and Mark J. Kushner

1. STREAMER DYNAMICS IN A MEDIA CONTAINING DUST PARTICLES* Natalia Yu. Babaeva and Mark J. Kushner Iowa State University Department of Electrical and Computer Engineering Ames, IA 50011, USA natalie5@iastate.edu mjk@iastate.edu http://uigelz.ece.iastate.edu July 2005 * Work supported by the National Science Foundation and Air Force Research Lab ICPIG2005_01

2. AGENDA • Streamer dynamics through aerosols and dust particles • Description of the model • Effect of dust particles on streamer dynamics • Dynamics before and after particles • Multiple particles • Summary Iowa State University Optical and Discharge Physics ICPIG2005_02

3. STREAMER DYNAMICS • Streamers are ionization waves having a high electric field at the avalanche front. • Air or other gases can be contaminated with particles or aerosols having sizes of 10s to 100s μm. • The intersection of propagating streamers with particles can significantly perturb streamer dynamics. •Streamer in atmospheric pressure gases. Iowa State University Optical and Discharge Physics ICPIG2005_03

4. DESCRIPTION OF THE MODEL: GEOMETRY • Positive corona is sustained between between a rod (rc= 0.07 cm) at 15 kV and a grounded surface separated by 0.2 cm. • 2-d unstructured mesh is produced with Skymesh2. Iowa State University Optical and Discharge Physics ICPIG2005_04

5. DESCRIPTION OF THE MODEL: BASIC EQUATIONS • Poisson’s equation, continuity equations and surface charge are simultaneously solved using a Newton iteration technique. • N2/O2/H2O = 79.5/19.5/1.0 • Species: N2, N2(v), N2*, N2**, N2+, N, N*, N+, N4+, O2, O2*, O2+, O2-, O-, O, O*, O+, O3, H2O, H2O+, H2, H, OH, e Iowa State University Optical and Discharge Physics ICPIG2005_05

6. MINMAX TYPICAL STREAMER PARAMETERS: POTENTIAL 15000 V, 0 – 6 ns • Potential is compressed in front of the streamer head. • Potential drop inside the streamer is small. • Streamer is analogous to the metal rod on the axis. ANIMATION SLIDE • t = 0 – 6 ns • t = 0 – 6 ns 0 - 15000 (V) Iowa State University Optical and Discharge Physics ICPIG2005_06

7. MINMAX TYPICAL STREAMER PARAMETERS: E/N 15000 V, 0 – 6 ns • Electric field is high at the streamer tip where ionization occurs. • Electric field is small in the conducting channel. ANIMATION SLIDE • t = 0 – 6 ns • t = 0 – 6 ns 100 – 1000 (Td) Log scale Iowa State University Optical and Discharge Physics ICPIG2005_07

8. MINMAX TYPICAL STREAMER PARAMETERS: [e], CHARGE, [e] Space Charge 15000 V, 0 – 6 ns • The electron density behind the streamer front is 1013-1014 cm-3 . • The plasma in the inner part of the streamer channel is quasi-neutral. • Positive space charge is concentrated at the streamer boundary. Log scale 1010 - 3 x 1014 (cm-3) 1011 - 1013 (cm-3) Iowa State University Optical and Discharge Physics t = 5.0 ns ICPIG2005_08

9. MINMAX E/N BEFORE 20, 60 and 80 m DUST PARTICLE E/N 15000 V, 0 – 6 ns • Streamer velocity and electric field increase as the streamer approaches the particle. • No particle • r =20m •r =60m• r =80m •t = 3.8 ns 100 - 1000 (Td) Log scale Iowa State University Optical and Discharge Physics ICPIG2005_09

10. MINMAX E-FIELD AFTER 80m PARTICLE E/N • The conical streamer head develops into a concave tip. • A new streamer starts from the bottom side facing the grounded electrode.The two streamers eventually merge. • If the particle has sharp features , electric field enhancement launches a secondary streamer that does not merge with the primary streamer. ANIMATION SLIDE • t = 0 – 5 ns • t = 0 – 5.2 ns 100 - 1000 (Td) Log scale Iowa State University Optical and Discharge Physics ICPIG2005_10

11. MINMAX E-FIELD AFTER 60m PARTICLE E/N • The conical streamer head develops into a concave tip. • The streamer compresses the E-field field between its tip and the particle surface facing the front. • Plasma envelopes smaller particles (20 µm, 60 µm). • t = 4.15 • t = 4.7 • t = 4.15 • t = 4.7 ns 100 - 1000 (Td) Log scale Iowa State University Optical and Discharge Physics ICPIG2005_11

12. MINMAX SURFACE AND SPACE CHARGE FOR 80m PARTICLE • Streamer delivers a substantial positive charge to top of particle. • Charging of particle occurs within 1 ns. • In a repetitively pulsed system, the charge accumulated on a particle can influence subsequent streamers. 1012 to 1013 (cm-3) Log scale • t = 4.5 ns Iowa State University Optical and Discharge Physics ICPIG2005_12

13. r E ELECTRIC FIELD NEAR SPHERE IN EXTERNAL E-FIELD • Solution of Laplace’s equation outside a conducting particle of radius a in an external electric field. • Near the particle • E = 5000 V/cm Iowa State University Optical and Discharge Physics ICPIG2005_13

14. MINMAX POTENTIAL: DIELECTRIC PARTICLES (r = 80m) ANIMATION SLIDE • t = 0 - 5.2 ns Iowa State University Optical and Discharge Physics 100 - 1000 (Td) Log scale ICPIG2005_14

15. MINMAX ELECTRIC FIELD: DIELECTRIC PARTICLES (r = 80m) ANIMATION SLIDE • t = 0 – 5.2 ns Iowa State University Optical and Discharge Physics 100 - 1000 (Td) Log scale ICPIG2005_15

16. MINMAX STREAMER INTERACTION: TWO PARTICLES (r = 80m) E/N • Streamer dynamics for the upper particle are similar to a single isolated particle. • A second streamer is launched from the bottom of the first particle. A third streamer is launched from the lower surface of the second particle. • This process is repetitive for particles of the same size and evenly spaced. • t = 0 – 5.2 ns 100 - 1000 (Td) Log Scale Iowa State University Optical and Discharge Physics ICPIG2005_16

17. MINMAX STREAMER INTERACTION: THREE PARTICLES (r = 80m) E/N • Launching of secondary and tertiary streamers with three particles is the same as for two particles. • t = 0 – 5.2 ns 100 - 1000 (Td) Log Scale Iowa State University Optical and Discharge Physics ICPIG2005_17

18. MINMAX STREAMER INTERACTION: THREE PARTICLES (r = 60m) E/N • The initial process for 60 m particle is the same as for 80 m. • The secondary streamers can merge sooner than with the larger particles. • t = 3.75• t = 4.25 • t = 4.6 • t = 3.75• t = 4.25 • t = 4.6 100 - 1000 (Td) Log Scale Iowa State University Optical and Discharge Physics ICPIG2005_18

19. MINMAX ELECTRON DENSITY FOR THREE 80 m PARTICLES • Electron flow envelopes the particles. • Plasma density is larger near the particle surfaces. • A wake of smaller electron density above the particle is due to electron flow around the particle. • t = 3.45 • t = 4.2 • t = 4.75 ns 1012 - 6 x 1014 (cm-3) Log Scale Iowa State University Optical and Discharge Physics ICPIG2005_19

20. MINMAX PHOTOIONIZATION SOURCE FOR THREE 80 m PARTICLES • Photoionization is enhanced in regions of high electric field. • For two or more particles there are bursts of photoelectrons. • A relay-like process results in which streamer is handed off between particles. • t = 2.95 • t = 3.95 • t = 4.25 • t = 4.8 ns 109 - 7x1022 (/cm3-s) Log Scale Iowa State University Optical and Discharge Physics ICPIG2005_20

21. STREAMER VELOCITY VS PARTICLE NUMBER AND SIZE • Streamer velocity increases in the presence of dust particles. • There exist an optimum for particle size and particle separation at which the streamer velocity is maximal. • Particles are separated by gaps of 3 particle diameter Iowa State University Optical and Discharge Physics ICPIG2005_21

22. CONCLUDING REMARKS • The intersection of propagating streamers with particles not only charges the particles but can also significantly perturb the streamer dynamics: • Loss of charge • Electric field enhancement • Secondary processes. • The interaction between the streamer electric field and the local (surface) electric field dominates the dynamics. • The particle size and dielectric constant (capacitance) and conductivity modify interaction due to charge accumulation and shorting of field. • Streamer–particle interactions are more complex for more random assemblies of particles having different sizes. Iowa State University Optical and Discharge Physics ICPIG2005_22