Heavy ion escape from Mars, influence from solar wind conditions and crustal magnetic fields
► Heavy ion escape from Mars is quantified using more than 4 year data. ► Average distribution functions used to improve angular coverage and statistics. ► Escaping fluxes stronger from north and dusk sectors as compared to south and dawn. ► Ion escape increase a factor of 2.5–2.9 during CIR passage...
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Veröffentlicht in: | Icarus (New York, N.Y. 1962) N.Y. 1962), 2011-10, Vol.215 (2), p.475-484 |
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Zusammenfassung: | ► Heavy ion escape from Mars is quantified using more than 4
year data. ► Average distribution functions used to improve angular coverage and statistics. ► Escaping fluxes stronger from north and dusk sectors as compared to south and dawn. ► Ion escape increase a factor of 2.5–2.9 during CIR passages. ► The net heavy ion escape from Mars is 2
±
0.2
×
10
24
s
−1.
We have used more than 4
years of Mars Express ion data to estimate the escape of heavy ions (
O
+
,
O
2
+
and
CO
2
+
) from Mars. To take the limited field of view of the instrument into account, the data has been binned into spatial bins and angular bins to create average distribution functions for different positions in the near Mars space. The net escape flux for the studied low solar activity period, between May 2007 and May 2011, is 2.0
±
0.2
×
10
24
s
−1. The escape has been calculated independently for four different quadrants in the
Y
MSO
−
Z
MSO
plane, south, dusk, north and dawn. Escape is highest from the northern and dusk quadrants, 0.6
±
0.1
×
10
24
s
−1, and smallest from the south and dawn quadrants, 0.4
±
0.1
×
10
24
s
−1. The flux ratio of molecular (
O
2
+
and
CO
2
+
) to
O
+ ions is 0.9
±
0.1, averaged over all quadrants. The flux difference between the north and south quadrants is statistically significant, and is presumed to be due to the presence of significant crustal magnetic fields in the southern hemisphere, reducing the outflow. The difference between the dawn and dusk quadrants is likely due to the magnetic tension associated with the nominal Parker angle spiral, which should lead to higher average magnetic tension on the dusk side. The escape increases during periods of high solar wind flux and during times when co-rotating interaction regions (CIR) affect Mars. In the latter case the increase is a factor 2.4–2.9 as compared to average conditions. |
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ISSN: | 0019-1035 1090-2643 1090-2643 |
DOI: | 10.1016/j.icarus.2011.08.003 |