Saturn Electrostatic Discharges

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Saturn Electrostatic Discharges (also referred to as SEDs) are atmospheric lightning events in convective weather storms on Saturn that produce high frequency (HF) radio emissions (1-40 MHz). Terrestrial lighting events on Earth, in comparison, occur in the very low frequency (VLF) radio band, between 3 Hz and 30 kHz. This makes SED signals at least 10,000 times stronger.[1] While first discovered by NASA's Voyager 1 mission, the scientific community has gained further understanding through the following Voyager 2 and Cassini missions in conjunction with ground-based observation and data gathering methods.

Voyager[edit]

Saturn Electrostatic discharges were first recorded by the Voyager 1 mission as it passed near Saturn in November 1980. The term was subsequently coined by Warwick et al. in April 1981 in the Journal Planetary Radio Astronomy Observations from Voyager 1 Near Saturn.[2] It was initially uncertain whether these SEDs were associated with storms in the planet's atmosphere or if they were originating in its rings. Evans et al. hypothesized that they originated from a satellite located within Saturn's B Ring, which was also the proposed reason for a narrow feature also found.[3] This was disputed in 1983 by Kaiser et al., who argued that the occultation caused by the planet lasted too long for SEDs to originate in the rings.[4][5]

Cassini[edit]

When the Cassini mission reached Saturn in 2004, SEDs and optical storm observations were finally directly linked. This occurred when Cassini ISS imaged the Dragon Storm, which was located by the SEDs it produced and then optically verified. It and other white storm clouds were found to be brighter in conjunction with higher rates of SEDs.[6][7] The Dragon Storm can range over 2,000 miles and is located at a planetocentric latitude of 35° south. This planet region is called "storm alley" as all storm activity on Saturn was concentrated here in a 1.5° band from 2002 to 2010.[4]

During the Cassini mission, it was also discovered that SEDs could be detected over the horizon. This phenomenon, known as over-the-horizon events, was made possible by the previously mentioned combination of radio and optical observations. It is theorized that this occurs when SED radio waves are temporarily trapped under Saturn's ionosphere.

Ground Based Observations[edit]

The first reliable ground-based detections of SEDs occurred in Ukraine in January/February 2006. At this time, SED storm E lasted approximately one month. The ground team used the UTR-2 radio telescope, and the data was combined with real-time information from Cassini. These efforts were made easier by the high intensity of the SEDs occurring during the month-long SED storm E. The process was repeated in November 2007 during the eight-month-long storm F and produced a high degree of coincidence between the UTR-2 and Cassini.[8]

At this same time as storm E, amateur astronomers became engaged in observing Saturn's storms. Storm E, observed by Cassini, was the first long-lasting SED storm while Saturn was distant from solar conjunction, making it high in the sky for ground-based observers. In the images captured by amateurs, the SED storms proved easily detectable, manifesting as bright white spots.[1]

References[edit]

  1. ^ a b Fischer, G.; Dyudina, U. A.; Kurth, W. S.; Gurnett, D. A.; Zarka, P.; Barry, T.; Delcroix, M.; Go, C.; Peach, D. (2011-11-21), Overview of Saturn lightning observations, arXiv:1111.4919
  2. ^ Warwick, J. W.; Pearce, J. B.; Evans, D. R.; Carr, T. D.; Schauble, J. J.; Alexander, J. K.; Kaiser, M. L.; Desch, M. D.; Pedersen, M.; Lecacheux, A.; Daigne, G.; Boischot, A.; Barrow, C. H. (1981-04-10). "Planetary Radio Astronomy Observations from Voyager 1 Near Saturn". Science. 212 (4491): 239–243. doi:10.1126/science.212.4491.239. hdl:2060/19820006164. ISSN 0036-8075. PMID 17783837.
  3. ^ Evans, D. R.; Romig, J. H.; Hord, C. W.; Simmons, K. E.; Warwick, J. W.; Lane, A. L. (September 1982). "The source of Saturn electrostatic discharges". Nature. 299 (5880): 236–237. doi:10.1038/299236a0. ISSN 1476-4687.
  4. ^ a b Sánchez-Lavega, Agustín; Fischer, Georg; Li, Cheng; García-Melendo, Enrique; del Río-Gaztelurrutia, Teresa (2024-01-24), Moist Convective Storms on Saturn, arXiv:2401.13294, retrieved 2024-05-08
  5. ^ Kaiser, M. L.; Connerney, J. E. P.; Desch, M. D. (May 1983). "Atmospheric storm explanation of saturnian electrostatic discharges". Nature. 303 (5912): 50–53. doi:10.1038/303050a0. ISSN 1476-4687.
  6. ^ Dyudina, Ulyana A.; Ingersoll, Andrew P.; Ewald, Shawn P.; Porco, Carolyn C.; Fischer, Georg; Kurth, William; Desch, Michael; Del Genio, Anthony; Barbara, John; Ferrier, Joseph (2007-10-01). "Lightning storms on Saturn observed by Cassini ISS and RPWS during 2004–2006". Icarus. Deep Impact Mission to Comet 9P/Tempel 1, Part 2. 190 (2): 545–555. doi:10.1016/j.icarus.2007.03.035. ISSN 0019-1035.
  7. ^ Fischer, G.; Gurnett, D. A.; Lecacheux, A.; Macher, W.; Kurth, W. S. (December 2007). "Polarization measurements of Saturn Electrostatic Discharges with Cassini/RPWS below a frequency of 2 MHz". Journal of Geophysical Research: Space Physics. 112 (A12). doi:10.1029/2007JA012592. ISSN 0148-0227.
  8. ^ Zakharenko, V.; Mylostna, C.; Konovalenko, A.; Zarka, P.; Fischer, G.; Grießmeier, J. -M.; Litvinenko, G.; Rucker, H.; Sidorchuk, M.; Ryabov, B.; Vavriv, D.; Ryabov, V.; Cecconi, B.; Coffre, A.; Denis, L. (2012-02-01). "Ground-based and spacecraft observations of lightning activity on Saturn". Planetary and Space Science. Surfaces, atmospheres and magnetospheres of the outer planets and their satellites and ring systems: Part VII. 61 (1): 53–59. doi:10.1016/j.pss.2011.07.021. ISSN 0032-0633.
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