Morning sector drift-bounce resonance driven ULF waves observed in artificially-induced HF radar backscatter

International audience HF radar backscatter, which has been artificially-induced by a high power RF facility such as the EISCAT heater at Tromsø, has provided coherent radar ionospheric electric field data of unprecedented temporal resolution and accuracy. Here such data are used to investigate ULF...

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Bibliographic Details
Main Authors: Baddeley, L. J., Yeoman, T. K., Wright, D. M., Davies, J. A., Trattner, K. J., Roeder, J. L.
Other Authors: Department of Physics and Astronomy Leicester, University of Leicester, Lockheed Martin Advanced Technology Laboratories (ATL), Lockheed Martin Advanced Technology Laboratories, Enteric Neuroscience Program, Miles and Shirley Fiterman, Mayo Clinic
Format: Article in Journal/Newspaper
Language:English
Published: HAL CCSD 2002
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Online Access:https://hal.science/hal-00317159
https://hal.science/hal-00317159/document
https://hal.science/hal-00317159/file/angeo-20-1487-2002.pdf
Description
Summary:International audience HF radar backscatter, which has been artificially-induced by a high power RF facility such as the EISCAT heater at Tromsø, has provided coherent radar ionospheric electric field data of unprecedented temporal resolution and accuracy. Here such data are used to investigate ULF wave processes observed by both the CUTLASS HF radars and the EISCAT UHF radar. Data from the SP-UK-OUCH experiment have revealed small-scale (high azimuthal wave number, m -45) waves, predominantly in the morning sector, thought to be brought about by the drift-bounce resonance processes. Conjugate observations from the Polar CAM-MICE instrument indicate the presence of a non-Maxwellian ion distribution function. Further statistical analysis has been undertaken, using the Polar TIMAS instrument, to reveal the prevalence and magnitude of the non-Maxwellian energetic particle populations thought to be responsible for generating these wave types.