Properties and drivers of fast interplanetary shocks near the orbit of the Earth (1995-2013)

We present a comprehensive statistical analysis spanning over a solar cycle of the properties and drivers of traveling fast forward and fast reverse interplanetary shocks. We combine statistics of 679 shocks between 1995 and 2013 identified from the near‐Earth (Wind and ACE) and STEREO‐A observation...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics 2015-06, Vol.120 (6), p.4112-4125
Main Authors: Kilpua, E. K. J., Lumme, E., Andreeova, K., Isavnin, A., Koskinen, H. E. J.
Format: Article
Language:English
Subjects:
Coronal mass ejection
coronal mass ejections
Density ratio
Earth
Economic models
interplanetary shocks
Mach number
Magnetic fields
Orbits
Phases
Solar corona
Solar cycle
Solar cycles
Solar minimum
Solar wind
Statistical analysis
Statistics
stream interaction regions
Strength
Sunspot cycle
Sunspots
Upstream
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Summary:We present a comprehensive statistical analysis spanning over a solar cycle of the properties and drivers of traveling fast forward and fast reverse interplanetary shocks. We combine statistics of 679 shocks between 1995 and 2013 identified from the near‐Earth (Wind and ACE) and STEREO‐A observations. We find that fast forward shocks dominate over fast reverse shocks in all solar cycle phases except during solar minimum. Nearly all fast reverse shocks are driven by slow‐fast stream interaction regions (SIRs), while coronal mass ejections (CMEs) are the principal drivers of fast forward shocks in all phases except at solar minimum. The occurrence rate and median speeds of CME‐driven fast forward shocks follow the sunspot cycle, while SIR‐associated shocks do not show such correspondence. The strength of the shock (characterized by the magnetosonic Mach number and by the upstream to downstream magnetic field and density ratio) shows relatively little variations over solar cycle. However, the shocks were slightly stronger during the ascending phase of a relatively weak solar cycle 24 than during the previous ascending phase. The CME‐ and SIR‐driven fast forward shocks and fast reverse shocks have distinct upstream solar wind conditions, which reflect to their relative strengths. We found that CME‐driven shocks are on average stronger and faster, and they show broader distributions of shock parameters than the shocks driven by SIRs. Key Points First study on IP shock properties and drivers spanning over a solar cycle Shock strength does not vary with solar cycle; speed and rate have a clear trend Shock strength and parameter distributions depend clearly on the driver
ISSN:2169-9380
2169-9402
DOI:10.1002/2015JA021138