Abstract
Abstract. Flux transfer events (FTEs) are signatures of transient reconnection at the dayside magnetopause, transporting flux from the dayside of the magnetosphere into the magnetotail lobes. They have previously been observed to contain a combination of magnetosheath and magnetospheric plasma. On 12 February 2007, the four Cluster spacecraft were widely separated across the magnetopause and observed a crater-like FTE as they crossed the Earth's dayside magnetopause through its low-latitude boundary layer. The particle instruments on the Cluster spacecraft were in burst mode and returning data providing 3-D velocity distribution functions (VDFs) at 4 s resolution during the observation of this FTE. Moreover, the magnetic field observed during the event remained closely aligned with the spacecraft spin axis and thus we have been able to use these 3-D data to reconstruct nearly full pitch angle distributions of electrons and ions at high time resolution (up to 32 times faster than available from the normal mode data stream). These observations within the boundary layer and inside the core of the FTE show that both the interior and the surrounding structure of the FTE consist of multiple individual layers of plasma, in greater number than previously identified. Our observations show a cold plasma inside the core, a thin layer of antiparallel-moving electrons at the edge of FTE itself, and field-aligned ions with Alfvénic speeds at the trailing edge of the FTE. We discuss the plasma characteristics in these FTE layers, their possible relevance to the magnetopause reconnection processes and attempt to distinguish which of the various different FTE models may be relevant in this case. These data are particularly relevant given the impending launch of NASA's MMS mission, for which similar observations are expected to be more routine.
Highlights
Half a century has passed since the general relevance of the magnetic reconnection process to the terrestrial magnetosphere was proposed for the first time by Dungey (1961)
Given that the full sky is sampled by each sensor only once per spin, the Plasma Electron and Current Experiment (PEACE) instrument flight software is utilized to determine, with reference to the magnetic field unit vector provided by Fluxgate Magnetometers (FGM), a pitch angle distribution (PAD) of the electrons which can be transmitted to the ground more frequently that the full 3-D measurements while the spacecraft is in normal mode (NM) of operation
Based on the method used by Khotyaintsev et al (2006) and Schwartz et al (2011), when the magnetic field vector is closely aligned with the spacecraft spin axis, as is the case for most of the events presented in this paper, these 3-D velocity distributions are equivalent to 16 or 32 2-D pitch angle distributions, effectively increasing the available temporal resolution for these data products to 0.250 s for the ions and 0.125 s for the electrons
Summary
Half a century has passed since the general relevance of the magnetic reconnection process to the terrestrial magnetosphere was proposed for the first time by Dungey (1961). The elbow-shaped flux-bundle FTEs (Russell and Elphic, 1978), which are postulated to be formed by a short burst of reconnection and occur in pairs which propagate northward and southward away from the reconnection site towards the magnetic poles These reconnected flux tubes are initially aligned with magnetospheric and magnetosheath magnetic fields on either side of the magnetopause, and are connected, forming the elbow at the reconnection site, providing a route through the magnetopause for plasma to enter and exit. Multiple X-line FTEs (Lee and Fu, 1985) can be formed between two (or more) reconnection lines, where magnetosheath and magnetospheric magnetic fields create a helical magnetic field structure that can extend azimuthally over long distances In this model the bipolar BN signature is observed inside the flux tube or in the draping fields outside. We utilize the high-time-resolution pitch angle distributions of electrons from PEACE instrument along with the high-time-resolution electric (EFW) and magnetic (FGM) field data and ion distributions (CIS) to study these structures in unprecedented detail
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