Presentation is loading. Please wait.

Presentation is loading. Please wait.

Speed-Current Relation in Lightning Return Strokes Ryan Evans, Student - Mostafa Hemmati, Advisor Department of Physical Sciences Arkansas Tech University.

Published byElfreda Holmes Modified over 8 years ago

Similar presentations

Presentation on theme: "Speed-Current Relation in Lightning Return Strokes Ryan Evans, Student - Mostafa Hemmati, Advisor Department of Physical Sciences Arkansas Tech University."— Presentation transcript:

1 Speed-Current Relation in Lightning Return Strokes Ryan Evans, Student - Mostafa Hemmati, Advisor Department of Physical Sciences Arkansas Tech University Russellville, AR 72801

2 Objectives Introduction of characteristics of breakdown waves, specifically lightning return strokes Introduction of the EFD equations for proforce and antiforce waves, as well as dimensionless sets of equations. Inclusion of a current behind the shock-front for antiforce waves Presentation of the wave profiles for solutions and speed and current relation in lightning return strokes

3 Lightning Return Strokes The lightning return strokes discussed are antiforce waves – waves propagating in the opposite direction of electric field force on electrons Electron gas pressure is much larger than the partial pressures of neutral particles and ions; therefore it is considered the driving force in propagating the wave The wave front has shown to have a strong discontinuity (shock front), followed by a thin sheath region where electron velocity and electric field reach maximum values. Electric field quickly reduces to zero and electron velocity to that of heavy particles. The sheath region is followed by an extended quasi-neutral region in which the electron gas cools due to further ionization.

4 Variables Electron number density Ion number density Electric field Electron velocity Wave velocity Electron mass Neutral particle mass Electron temperature Position Ionization potential of gas Electron charge Elastic collision frequency Ionization frequency n- N i - E- v- V- m- M- T e - x- Φ- e- K- β- Dimensionless Variables Electric field strength Electron number density Electron velocity Electron gas temperature Position within sheath Ionization rate Wave parameter η-ν-ψ-θ-η-ν-ψ-θ- ξ-μ-α-κ-ω-ξ-μ-α-κ-ω-

5 EFD Equations for Proforce Waves ( conservation of mass ) ( conservation of momentum ) ( conservation of energy ) ( Poisson’s Equation )

6 Dimensionless Variables for Proforce Waves

7 Dimensionless EFD equations for Proforce Waves ( conservation of mass ) ( conservation of momentum ) ( conservation of energy ) ( Poisson’s Equation )

8 Dimensionless Variables for Antiforce Waves

9 Dimensionless EFD Equations for Antiforce Waves ( conservation of mass ) ( conservation of momentum ) ( conservation of energy ) ( Poisson’s Equation )

10 Current Bearing Waves

11 EFD Equations for Current Bearing Antiforce Waves ( conservation of mass ) ( conservation of momentum ) ( conservation of energy ) ( Poisson’s Equation )

12 Integration of the Electron Fluid Dynamical Equations To achieve solutions for the set of EFD equations, the equation set is integrated through the sheath region, by trial and error. Wave speeds, α, and current, ι, were chosen for integration. Then electron velocity, ψ 1, electron number density, ν 1, and wave constant κ were changed in integrating the EFD equations through the sheath region until solutions agreed with expected conditions at the end of the sheath. For 4 different wave speeds, α, solutions were found for the largest current values, ι, that maintained agreement with expected conditions (η→0 as ψ→1).

13 Initial Boundary Conditions Successful solutions required the following boundary values: Waves speeds range from 3 x 10 6 m/s (α=1.0) to 9 x 10 7 m/s (α=0.001) α = 0.001, ι = 7.0, κ = 0.144, ψ 1 = 0.4721, ν 1 = 0.2161 α = 0.01, ι = 5.0, κ = 1.3, ψ 1 = 0.7, ν 1 = 0.7696 α = 0.1, ι = 1.5, κ = 0.435, ψ 1 = 0.808, ν 1 = 0.7350 α = 1.0, ι = 0.25, κ = 0.18, ψ 1 = 0.75, ν 1 = 0.6726

14 Figure 1: Electric field, η, as a function of electron velocity, Ψ, within the sheath region of lightning return strokes for current values 0.25, 1.5, 5 and 7.

15 Figure 2: Electric field, η, as a function of position, ξ, within the sheath region of lightning return strokes for current values 0.25, 1.5, 5 and 7.

16 Electric Field Figure 1 shows that for these wave speeds and current values, the solutions meet the expected conditions at the end of the sheath region (η→0 as ψ→1). Figure 2 shows that the electric field peaks early on in propagation and quickly drops to values below initial value and reduces to 0. Higher currents prove to peak earlier and even drop more rapidly than that of lower currents. This agrees with results predicted by Rakov and Dulzon as well as several models tested and measured by Uman. The electric field reducing to 0 in Figures 1 and 2 signifies the end of the sheath region and the start of the quasi neutral region, where electrons come to rest relative to heavy particles, fitting the definition of the two-region electron fluid-dynamical wave established by Shelton and Fowler [8].

17 Figure 3: Electron velocity, ψ, as a function of position, ξ, within the sheath region of lightning return strokes for current values 0.25, 1.5, 5 and 7.

18 Wave Velocity This data set shows wave velocities reaching 9 x 10 7 m/s which agrees to ranges found by Idone [4] and Wang [10]. Data gathered by Idone et al. [4] yielded speeds between 1.6 x 10 8 m/s and 9.0 × 10 7 m/s. Wang et al. [10] triggered return strokes with speeds ranging from 4 x 10 7 to 1.5 x 10 8 m/s.

19 Figure 4: Electron number density, ν, as a function of position, ξ, within the sheath region of lightning return strokes for current values 0.25, 1.5, 5 and 7.

20 Electron Number Density Our electron number densities range from 4 x 10 15 /m 3 to 2 x 10 16 /m 3, which match the values recorded by Hagelaar and Kroeson [2] as well as Graves [1]. David Graves [1] reported electron number density values ranging from 5 x 10 15 /m 3 and 2 x 10 16 /m 3, showing very high agreement with our calculated values. Hagelaar and Kroeson [2] report an average electron number density of 7 x 10 15 /m 3 within the sheath region of the wave, also falling within our range.

21 Figure 5: Ionization rate, μ, as a function of position, ξ, within the sheath region of lightning return strokes for current values 0.25 and wave speed 1.0. The ionization rates represented in Figure 5 remain considerably constant within the sheath region as predicted by Shelton and Fowler [8].

22 Figure 6: Electron temperature, θ, as a function of position, ξ, within the sheath region of lightning return strokes for current values 0.25, 1.5, 5 and 7. Figure 6 shows a noticeable relation for electron temperature as a function of position. For all currents, electron temperature increases as position within the sheath increases, as reported by Sanmann and Fowler [7]. Figure 6 also shows that higher wave speeds allow for larger currents and higher temperatures.

23 The EFD equations were able to be integrated through the sheath region of the wave for a range of current and speed values behind the wave front. For all sets of waves, our solutions showed a moderate to high level of agreement with expected conditions at the end of the sheath region. Several theoretical and experimental results show agreement with our results. These results once again confirm the validity of the EFD model of current bearing antiforce waves to describe lightning return strokes. Conclusions

24 Acknowledgements Dr. Hemmati Arkansas Space Grant Consortium

25 References 1.Graves D.B.: J. Appl. Phys. 62 (1987). 2.Hagelaar G.J.M. and Kroesen G.M.W.: Journal of Computational Physics, 159, (2000). 3.Hemmati, M., et al. "Antiforce current bearing waves." 28th International Symposium on Shock Waves. Springer Berlin Heidelberg, (2012). 4.Idone, V.P., et al., “The propagation speed of a positive lightning return stroke” Geophys. Res. Lett., col. 14, 1150-1153, (1987). 5.Norman et. al. "Ionization Rate, Temperature, and Number Density for Breakdown Waves with a Large Current Behind the Shock Front." Journal of the Arkansas Academy of Science 62 (2008). 6.Rakov, V. A., and A. A. Dulzon. "A modified transmission line model for lightning return stroke field calculations." Proc. 9th Int. Symp. Electromagn. Compat. (1991). 7.Sanmann E and RG Fowler: The Physics of Fluids. 18, 11. (1975). 8.Shelton GA and RG Fowler. “Nature of electron fluid dynamical waves.” The Physics of Fluids 11(4):740-746. (1968). 9.Uman et. al. "Comparison of lightning return‐stroke models." Journal of Geophysical Research: Atmospheres. 98.D12 (1993). 10.Wang, D., et al. "Observed leader and return‐stroke propagation characteristics in the bottom 400 m of a rocket‐triggered lightning channel." Journal of Geophysical Research: Atmospheres, 104.D12 (1999).

Download ppt "Speed-Current Relation in Lightning Return Strokes Ryan Evans, Student - Mostafa Hemmati, Advisor Department of Physical Sciences Arkansas Tech University."

Similar presentations

Plasma Medicine in Vorpal Tech-X Workshop / ICOPS 2012, Edinburgh, UK 8-12 July, 2012 Alexandre Likhanskii Tech-X Corporation.

Plasma Medicine in Vorpal Tech-X Workshop / ICOPS 2012, Edinburgh, UK 8-12 July, 2012 Alexandre Likhanskii Tech-X Corporation.
Introduction to Plasma-Surface Interactions Lecture 6 Divertors.

Introduction to Plasma-Surface Interactions Lecture 6 Divertors.
The scaling of LWFA in the ultra-relativistic blowout regime: Generation of Gev to TeV monoenergetic electron beams W.Lu, M.Tzoufras, F.S.Tsung, C. Joshi,

The scaling of LWFA in the ultra-relativistic blowout regime: Generation of Gev to TeV monoenergetic electron beams W.Lu, M.Tzoufras, F.S.Tsung, C. Joshi,
AS 4002 Star Formation & Plasma Astrophysics BACKGROUND: Maxwell’s Equations (mks) H (the magnetic field) and D (the electric displacement) to eliminate.

AS 4002 Star Formation & Plasma Astrophysics BACKGROUND: Maxwell’s Equations (mks) H (the magnetic field) and D (the electric displacement) to eliminate.
PIII for Hydrogen Storage

PIII for Hydrogen Storage
LIGHTNING PHENOMENON 1. The height of the cloud base above the surrounding ground level may vary from 160 to 9,500 m. The charged centres which are responsible.

LIGHTNING PHENOMENON 1. The height of the cloud base above the surrounding ground level may vary from 160 to 9,500 m. The charged centres which are responsible.
Effect of supra thermal electrons on particle charge in RF sheath A.A.Samarian and S.V. Vladimirov School of Physics, University of Sydney, NSW 2006, Australia.

Effect of supra thermal electrons on particle charge in RF sheath A.A.Samarian and S.V. Vladimirov School of Physics, University of Sydney, NSW 2006, Australia.
Inner Source Pickup Ions Pran Mukherjee. Outline Introduction Current theories and work Addition of new velocity components Summary Questions.

Inner Source Pickup Ions Pran Mukherjee. Outline Introduction Current theories and work Addition of new velocity components Summary Questions.
TEST GRAINS AS A NOVEL DIAGNOSTIC TOOL B.W. James, A.A. Samarian and W. Tsang School of Physics, University of Sydney NSW 2006, Australia

TEST GRAINS AS A NOVEL DIAGNOSTIC TOOL B.W. James, A.A. Samarian and W. Tsang School of Physics, University of Sydney NSW 2006, Australia
1 Introduction to Plasma Immersion Ion Implantation Technologies Emmanuel Wirth.

1 Introduction to Plasma Immersion Ion Implantation Technologies Emmanuel Wirth.
PHYS 206 Matter and Light At least 95% of the celestial information we receive is in the form of light. Therefore we need to know what light is and where.

PHYS 206 Matter and Light At least 95% of the celestial information we receive is in the form of light. Therefore we need to know what light is and where.
Modeling Generation and Nonlinear Evolution of VLF Waves for Space Applications W.A. Scales Center of Space Science and Engineering Research Virginia Tech.

Modeling Generation and Nonlinear Evolution of VLF Waves for Space Applications W.A. Scales Center of Space Science and Engineering Research Virginia Tech.
Partially ionized gas -contains IONS, ELECTRONS and neutral particles.

Partially ionized gas -contains IONS, ELECTRONS and neutral particles.
Plasma Characterisation Using Combined Mach/Triple Probe Techniques W. M. Solomon, M. G. Shats Plasma Research Laboratory Research School of Physical Sciences.

Plasma Characterisation Using Combined Mach/Triple Probe Techniques W. M. Solomon, M. G. Shats Plasma Research Laboratory Research School of Physical Sciences.
High-Mach Number Relativistic Ion Acoustic Shocks J. Fahlen and W.B. Mori University of California, Los Angeles.

High-Mach Number Relativistic Ion Acoustic Shocks J. Fahlen and W.B. Mori University of California, Los Angeles.
Collisional ionization in the beam body  Just behind the front, by continuity  →0 and the three body recombination  (T e,E) is negligible.

Collisional ionization in the beam body  Just behind the front, by continuity  →0 and the three body recombination  (T e,E) is negligible.
STREAMER DYNAMICS IN A MEDIA CONTAINING DUST PARTICLES* Natalia Yu. Babaeva and Mark J. Kushner Iowa State University Department of Electrical and Computer.

STREAMER DYNAMICS IN A MEDIA CONTAINING DUST PARTICLES* Natalia Yu. Babaeva and Mark J. Kushner Iowa State University Department of Electrical and Computer.
Physical Modeling – Fall 20061 MOMENTUM For a particle, momentum is: p = mv and.

Physical Modeling – Fall MOMENTUM For a particle, momentum is: p = mv and.
5. Simplified Transport Equations We want to derive two fundamental transport properties, diffusion and viscosity. Unable to handle the 13-moment system.

5. Simplified Transport Equations We want to derive two fundamental transport properties, diffusion and viscosity. Unable to handle the 13-moment system.
F. Cheung, A. Samarian, W. Tsang, B. James School of Physics, University of Sydney, NSW 2006, Australia.

F. Cheung, A. Samarian, W. Tsang, B. James School of Physics, University of Sydney, NSW 2006, Australia.

Similar presentations

Ads by Google