Lightning: Charge Separation Mechanisms, Detection and Applications

1. Lightning:Charge Separation Mechanisms, Detection and Applications Kaitlyn Suski May 29, 2009 SIO 209 http://blogs.trb.com/news/weather/weblog/wgnweather/20021110_lightning.jpg

2. Outline • Background • Charge Separation Mechanisms • Detection • Applications

3. Lightning Background • Occurs in cumulonimbus clouds. • Lightning is an electrical discharge. • Contained in a volume bounded by -5 to -40 C and has a radius of ~2 km. • Charge separation creates centers of charge in the cloud. When insulating ability of air is exceeded or the charge reaches it’s breakdown potential it is discharged. • Charge separation can be as large as a hundred million volts and can transfer 10 coulombs of charge to the ground. • Accompanied by thunder. • Rapid expansion and compression of heated air. http://s-tiger.photovillage.org/photosDir/2369/thumb/800-clouds-lightning-800.jpg

4. Charge Separation Mechanisms Figure 11.2, Cotton. • Two proposed mechanisms of charge separation: • Convection charging theory • Precipitation related charge separation

5. Convection Charging Theory • Pocket of positive ions in lower troposphere due to fair-weather electric field. • Convective updrafts carry the charge into the cloud. • Cosmic radiation produces ions in the ionosphere. Clouds attract negative ions to cloud tops resulting in cloud polarity. • Downdrafts carry negative ions down resulting in discharge. Figure 11.3, Cotton.

6. Precipitation Charging Theories • Induction Charging Theory • Collision of droplets and ice with precipitation particles results in a negatively charged larger particle and a positively charged smaller particle. • The positive particles are carried up in updrafts, while negative particles are carried down by gravity. • Need a high frequency of collisions and rebounds. • Speculated that charge separation is better for ice-ice collisions than water-water, however, relaxation time is long and significant charge may not be transferred.

7. Precipitation Charging Theories (2) • Charging of Graupel and Hail • Rapid charge transfer between graupel/hail and vapor grown ice crystals. • Requires a large concentration of ice crystals and large, rimed graupel or hail. Figure 11.7, Cotton.

8. Electrical Double Layer and QLL

9. Long Range Lightning Detection Network (LLDN) • Continuous, real-time data coverage over the Pacific Ocean. • PacNet • Lightning strikes emit electromagnetic waves, which are detected by magnetic direction finding or time of arrival methods with 2 or more sensors. • Sensors spaced every 100 km. Pessi Presentation Pessi Presentation

10. Applications • Can be used to track convection and tropical cyclones when high clouds block satellite coverage. • Lightning rate is correlated with convective strength. This is verified by radar reflectivity. • Can lead to more accurate intensity forecasts. • Proxy for latent heat release in deep convective clouds. • Ratio of lightning to rainfall rate is stable over Pacific Ocean. • Used to estimate a moisture profile by using a lightning-rainfall-moisture profile relationship. • Need to know the temperature because moisture has a nonlinear relationship with temperature.

11. References • Businger, Steven. “Assimilation of Long-Range Lightning Data over the Pacific.” <http://www.soest.hawaii.edu/MET/Faculty/businger/projects/pacnet/> • Cotton, William. “Chapter 11: Cloud Electrification,” Atmospheric Thermodynamics and Microphysics of Clouds, AT 620 Lecture notes, Fall 1996, revisions Summer 2005. • Pessi, Antti. Long-Range Lightning Detection over the Pacific: Applications of the Data Stream for TCS-08 Presentation, <ftp://ftp.soest.hawaii.edu/businger/outgoing/PacNet> http://www.noaanews.noaa.gov/stories2008/images/lightning3.jpg

12. Questions? http://images-3.redbubble.net/img/art/size:large/view:main/423749-7-lightning-over-adelaide.jpg