We have statistically investigated the electron density n(e,M) and temperature T(e,M) in the near-Earth plasma sheet in terms of the magnetosphere-ionosphere coupling process, as measured by the electrostatic analyzer (ESA) on board the Time History of Events and Macroscale Interactions during Substorms (THEMIS-D) satellite from November 2007 to January 2010. To find out when and where an aurora can occur, either with or without electron acceleration, the thermal current j(parallel to)(th) and the conductivity K along the magnetic field line were also estimated from observations of the magnetospheric electrons with pitch angle information inside 12 R(E). The thermal current, j(parallel to)(th)(proportional to n(e,M) T(e,M)(1/2)), represents the upper limit of the field-aligned current that can be carried by magnetospheric electrons without a field-aligned potential difference. The conductivity, K(proportional to n(e,M) T(e,M)(-1/2)), relates the upward field-aligned current, j(parallel to), to the field-aligned potential difference, V(parallel to), assuming adiabatic electron transport. The thermal current is estimated by two methods: (1) from the relation by using n(e,M) and T(e,M) and (2) from the total downward electron number flux. We find that in the dawnside inner magnetosphere, the thermal currents estimated by both methods are sufficient to carry typical region 2 upward field-aligned current. On the other hand, in the duskside outer magnetosphere, a field-aligned potential difference is necessary on the region 1 current since the estimated thermal current is smaller than the typical region 1 current. By using the relationship, j(parallel to) = KV(parallel to), where K is the conductivity estimated from Knight's relation and j. is the typical auroral current, we conclude that a field-aligned potential difference of V(parallel to) = 2-5 kV is necessary on the duskside region 1 upward field-aligned current.

• 出版日期2011-12-2