Abstract
Abstract. We present results of simulated radar observations of meteor trails in an effort to show how non-specular meteor trails are expected to vary as a function of a number of key atmospheric, ionospheric and meteoroid parameters. This paper identifies which geophysical sources effect the variability in non-specular trail radar observations, and provides an approach that uses some of these parameter dependencies to determine meteoroid and atmospheric properties based upon the radar meteor observations. The numerical model used follows meteor evolution from ablation and ionization to head echo plasma generation and through formation of field aligned irregularities (FAI). Our main finding is that non-specular meteor trail duration is highly sensitive to the presence of lower thermospheric winds or electric fields and the background ionospheric electron density. In an effort to make key predictions we present the first results of how the same meteoroid is expected to produce dramatically different meteor trails as a function of location and local time. For example, we show that mid-latitude trail durations are often shorter lasting than equatorial trail observations because of the difference in mid-latitude wind speed and equatorial drift speed. The simulated trails also account for observations showing that equatorial nighttime non-specular meteor trails last significantly longer and are observed more often than daytime trails.
Highlights
The daily occurrence of billions of meteor trails in the Earth’s upper atmosphere present a powerful opportunity to use remote sensing tools to better understand the meteoroids that produced them and the atmosphere and ionosphere in which their trails occur
Because these echoes occur simultaneously over multiple radar range gates, the term non-specular echoes has been adopted by many authors in order to differentiate them from the meteor echoes from specular meteor radars, which require a trail to align perpendicular to the radar beam (Ceplecha et al, 1998; Cervera and Elford, 2004)
The focus of this paper is to provide a theoretical model that predicts and describes the essential variation of non-specular trail observations, including when and where
Summary
Urbina2 1Center for Remote Sensing, Inc., Fairfax, VA, USA 2Communications and Space, Sciences Laboratory, Pennsylvania State University, University Park, PA, USA. Received: 1 October 2008 – Revised: 3 March 2009 – Accepted: 3 March 2009 – Published: 4 May 2009
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