Solar wind variations and geomagnetic storms: A study of individual storms based on a high time resolution ISEE-3 data
We employ two independent methods to determine the relationship between the epsilon parameter and the total energy dissipation rate of the magnetosphere by selecting disturbed periods from the same data set used by Baker et al. (1983). Specifically, four storms are examined in detail, since the accuracy of estimating U/sub T/ is significantly improved during disturbed periods. The first method assumes U/sub T/ = M/sub A//sup 2alpha/epsilon, where M/sub A/ is the Alfven Mach number and ..cap alpha.. varies with time. The second method considers a linear, time-invariant dynamic system with epsilon as input and U/sub T/ as output. This means U/sub T/ = W*epsilon, where * is convolution and W is a transfer function characteristic of the system. It is found that ..cap alpha.. values fluctuate mainly between 0 and -0.25. The transfer function analysis indicates that W often resembles a delta-function or a narrow rectangular impulse. Both results give the same implication (namely, U/sub T/ approx.epsilon) and thus are consistent with the view that the magnetosphere is primarily a directly driven system during disturbed periods.
- Research Organization:
- Geophysical Institute, University of Alaska, Fairbanks
- OSTI ID:
- 5772524
- Journal Information:
- J. Geophys. Res.; (United States), Vol. 90:A1
- Country of Publication:
- United States
- Language:
- English
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