We use the solar wind data measured

We use the solar wind data measured by the ACE
satellite to derive the interplanetary electric field by
assuming that the plasma motion is determined by
E  B drift. The time shift of the solar wind data is
determined as follows. We first use the satellite
position and solar wind velocity to calculate the
possible propagation delay, and then compare the
changes in the interplanetary and ionospheric
electric fields. There are two different methods to
calculate the solar wind propagation time. One is
the X propagation time with a constant solar wind velocity, and the other is the new method recently
developed by Weimer et al. (2002, 2003) with better
accuracy for large IMF clock angle. In this paper,
the X propagation delay of the solar wind is
calculated. We take the case in Fig. 1a as an
example. During the period of interest, the ACE
satellite was located at 232 RE upstream in the solar
wind, and the solar wind velocity was 500 kms1.
The solar wind would take 46 min to propagate
from the position of ACE to the bow shock and an
additional 10 min to travel through the magnetosheath,
so the total propagation delay was
56 min. Then we compare whether the calculated
propagation delay is consistent with the sudden
changes in the measured electric fields. In Fig. 1a,
the IMF/IEF data are shifted by 56 min. After being
shifted, the minimum IEF Ey is at 1457 UT and
exactly at the time of the minimum equatorial
ionospheric electric field. Although the X propagation
delay alone may have some uncertainty, the
matching of the shifted minimum IEF Ey with the
minimum ionospheric electric field provides an
accurate determination of the solar wind propagation
time. This method is used for all cases. In the
following, we will only present the shifted solar