163_168 adg v–l5 n01 Romano.pdf


ANNALS OF GEOPHYSICS, VOL. 45, N. 1, February 2002

163

Magnetic and solar effects on ionospheric
absorption at high latitude

Vincenzo Romano, Massimiliano Cerrone, Loredana Perrone and Marco Pietrella
      Istituto Nazionale di Geofisica e Vulcanologia, Dept. RM2-UF/FAA, Roma, Italy

Abstract
Some periods of intense solar events and of strong magnetic storms have been selected and their effects on the
ionospheric D region have been investigated on the basis of ionospheric absorption data derived from riometer
measurements made at the Italian Antarctic Base of Terra Nova Bay (geographic coordinates: 74.69 S, 164.12 E;
geomagnetic coordinates: 77.34 S, 279.41 E). It was found that sharp increases in ionospheric absorption are
mainly due to solar protons emission with an energy greater than 10 MeV. Moreover, the day to night ratios of
the ionospheric absorption are greater than 2 in the case of strong events of energetic protons emitted by the
Sun, while during magnetic storms, these ratios range between 1 and 2.

1. Introduction

The electron density below 80 km in the
ionosphere is greatly dependent on the chemistry
of this region that is in turn affected by direct
solar radiation (Ranta et al., 1984). Under
disturbed conditions, one of the principal causes
of ionization in the D region is due to the influx
of the energetic particles penetrating the
atmosphere that increase the electron density and
then the ionospheric absorption. Therefore the
ionospheric absorption is a suitable parameter
to disclose the effects on the lower ionosphere
due to the magnetic and solar activity.

During and after magnetospheric storms two
types of ionospheric absorption in the D region

can be observed (see, e.g., Ranta et al., 1984,
and references therein):

a) An ionospheric absorption increasing at
high latitude during the main phase of the
magnetospheric storms.

b) An ionospheric absorption increasing
during the recovery phase of the magnetospheric
storms, clearly separated from the first one, well
known as ‘Post-Storm Effects’ (PSE) (Bremer,
1998) at mid-latitude.

The poleward boundary of PSE has been
found to be a function of storm-time, reaching
even L = 4 (Wagner et al., 1982). As Terra Nova
Bay is a polar station located outside the PSE
poleward boundary, the first component (a) is
expected to be the main effect of magnetic
perturbations on the absorption data.

Another important type of absorption that
can occur at high latitudes, is the so-called
Polar Cap Absorption (PCA). This event is
caused by energetic protons emitted by the Sun
in connection with major solar flares. The
main effects of PCA absorption are seen at
lower altitude (60, 70 m) more than other types
of absorption due for example to magne-
tospheric storms. The chemistry of the ionized
constituents is markedly different and this

Mailing address: Dr. Vincenzo Romano, Istituto
Nazionale di Geofisica e Vulcanologia, Dept. RM2-UF/FAA,
Via di Vigna Murata 605, 00143 Roma, Italy; e-mail:
Romano@ingv.it

Key words   ionospheric absorption – solar protons
event – magnetic storm – Antarctic region



164

Vincenzo Romano, Massimiliano Cerrone, Loredana Perrone and Marco Pietrella

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165

Magnetic and solar effects on ionospheric absorption at high latitude

probably gives rise to the diurnal variation of
PCA. During a PCA the radio absorption
measured by riometers by day is typically 2 or
more times larger than by night (Ranta et al.,
1984). Therefore the day to night absorption ratio
can be used to verify that a PCA phenomenon is
occurring. The day to night ratios are calculated
on the basis of the day-time and night-time
ionospheric absorption values. The boundary
between day (sunrise) and night (sunset) is
generally determined by the  solar zenith angle
χ = 90°. Hargreaves (1993) found that at sunset
and during a PCA, a significant decay of electron
density can be observed for χ = 96°, cor-
responding to a height of about 60 km, i.e. the
lower ionospheric region here investigated. So,
in this study, the day to night ratios at solar zenith
angle ≥ 90° were carried out for some periods
of strong solar and magnetic events in 1998
(Section 2). The results are presented and
discussed in Sections 3 and 4.

2.  Data analysis

Ionospheric absorption data (UT), the time
weighted magnetic index ap (τ) (UT), and the
solar protons flux (UT) (monitored by the
NOAA GOES-8 satellite in geo-synchronous
orbit) were considered for the period 1st January -
31st December 1998.

Ionospheric absorption data (A2 method) are
derived from 1 min cosmic noise measurements
recorded at Terra Nova Bay Riometer station
(30 MHz) (Cerrone et al., 1996; De Franceschi
et al., 1997). The time-weighted accumulation index
ap (τ) (Wrenn, 1987), based on the history of the
geomagnetic index ap, is considered to represent
the magnetic activity effects on the ionosphere.
In fact, it has been shown that ap (t ≅ 0.8),
that corresponds to a 15 h time delay, is better
correlated with the ionospheric parameters, at
least in the F region (for details see Wu and
Wilkinson, 1995; Perrone and De Franceschi,
1999; Perrone et al., 2001).

Firstly, strong magnetic storms were selected
on the basis of the  daily mean of ap (τ) ≥ 30
(De Franceschi et al., 1999). Some days before
and after the onset of the storm were also taken
into account to study the behaviour of the

ionospheric absorption before and after the
storm. This procedure disclosed the following
3 periods: April 18-30 1998, August 20 -
September 03 1998 and September 19-28 1998.
Another time-interval was considered from
September 29 to October 7 1998, characterized
by a strong protons emission event without any
important magnetic activity. Figure 1a-d plots
the daily mean of the ionospheric absorption
(calculated from the absorption values at the first
minute of each hour of the day), the daily solar
protons flux with energies > 10 MeV, and the
daily mean of ap (τ) for each selected period:
high correlation between the absorption and
solar protons flux maxima can be recognized.

The hourly mean of absorption values
(calculated on the basis of 1 min cosmic noise
sampling) during sunset transition between
χ = 87° and χ = 102° both for the days of solar
protons flux and ap (τ) maxima are reported in
tables I and II. Moreover, the day to night ratios
of the ionospheric absorption obtained by
considering χ = 90° as sunrise and χ = 96° as
sunset have been calculated (table III).

3.  Results and discussion

A careful inspection of fig.1a-d leads to the
following main considerations:

– The period April 18-30 shows a ionospheric
absorption peak which occurred on 21st due to
the solar proton event (associated with a solar
flare at 20 classified as M1), that started on 20th,
reached its maximum on 21st and stopped on
24th. During this period the ionospheric
absorption remained relatively high. A moderate
magnetic storm (April 24, ap (τ) = 30) can be
observed probably due to a coronal mass ejection
which started on 21st. As on 24th, the proton
flux remained relatively high (1.1⋅106 counts ⋅
cm−2 ⋅ day−1 ⋅ sr−1), most likely both the solar
proton event and the magnetic storm affected
the ionospheric absorption value on 24th, but it
is not clear which phenomenon gave the major
contribution.

– From August 20th to September 3rd the
ionospheric absorption that maximized on
August 26th was due to the solar proton event
that started on 24th (in conjunction to a solar



166

Vincenzo Romano, Massimiliano Cerrone, Loredana Perrone and Marco Pietrella

Table  I. Hourly ionospheric absorption data as function of the solar zenith angles between 87° and 102°; the
days where the solar proton flux affects the ionospheric absorption more than the magnetic storm were considered.

          Date Solar zenith angle Ionospheric absorption (dB)
          21 April 1998 87° 3.67

90° 2.46
93° 1.59
96° 0.89
99° 0.68

                                                                     102° 0.58
          26 August 1998 87° 3.21

90° 2.46
93° 1.60
96° 1.73
99° 1.73

                                                                     102° 1.40
          27 August 1998 87° 1.08

90° 0.79
93° 0.61
96° 0.60
99° 0.60

                                                                     102° 0.41
          01 October 1998 87° 1.94

90° 0.95
93° 0.95
96° 0.62
99° 0.45

                                                                     102° 0.45

flare classified as X1/3B), reached its maximum
on 26th, and stopped on 29th. The strong
magnetic perturbation on August 27th should
also be due to the same solar flare. The
ionospheric absorption value on 27th depends
on both the solar proton event and the magnetic
storm, the proton flux being relatively high on
27th (2.8 ⋅ 106 counts ⋅ cm−2 ⋅ day−1 ⋅ sr−1) and
the magnetic activity very strong (ap (τ) = 110)
but, as in the previous case, it is difficult to assess
a priori where the main contribution came from.

– The period September 19-28 showed an
increase in ionospheric absorption starting from
24th up to 28th with two peaks on 25th and 27th.
As a magnetic storm evolved between 24th and
26th with a strong maximum on 25th, just when a

solar protons emission occurred (these two events
were probably due to the solar flare classified as
M7/3B started on 23), both the phenomena
concurred to the absorption growth. Given the rather
low level of proton flux (2.2⋅104 counts ⋅ cm−2 ⋅ day−1 ⋅
sr−1) and magnetic activity (ap (τ) = 13), the
absorption peak observed on 27th could be better
investigated by using a local geomagnetic index.

– A sudden increase in the ionospheric
absorption from September 30th with a peak
observed on October 1st was due to the solar proton
event (associated to a solar flare occurring on 30th
September of importance M2/2N.) that reached its
maximum the same day.

The hourly mean values (tables I and II) and
the day to night ratios (table III) of the absorption



167

Magnetic and solar effects on ionospheric absorption at high latitude

were considered as related to the occurring days
of proton flux and of magnetic storm maxima
in order to identify, as far as possible, which
phenomenon causes the ionospheric absorption.

Table I shows a significant decrease of the
ionospheric absorption as a function of the solar
zenith angle from = 87° to = 102°. In
particular, at = 96°, the absorption is at least
twice smaller that calculated at = 87°. With
regard to August 27th, the day to night ratio equal
to 2.0 (table III), that is the lower limit indicating
a PCA phenomenon (Ranta et al., 1994), sug-
gests a ionospheric absorption essentially due
to the solar proton event (started on 24th) rather
than the magnetic storm. This could be supported
(despite the strong magnetic activity) by the fact
that on August 27th the proton flux remains very

high (2.8 106 counts cm 2 day 1 sr 1). April 21st,
August 26th and October 1st, for which the day
to night ratios are greater than 2.0, confirm the
occurrence of  PCA phenomena.

Any significant ionospheric absorption
decrease from = 87° to = 102° can be
assessed for the days reported in table II. These
days  show  a day to night ratio smaller than 2.0
that is not typical for a PCA phenomenon as
expected (table III). This could suggest that on
April 24th and September 25th the ionospheric
absorption is more affected by the magnetic
storm rather than by the solar protons event. In
particular, for September 25th, the proton flux,
although occurring by day, remained very small
(only 3.4 .105 counts cm 2 day 1 sr 1) while the
magnetic activity was very strong (ap ( ) = 94).

Table  III. Day to night ratios for proton fluxes and magnetic storm events calculated choosing = 90°
(sunrise) and  = 96° (sunset).

    Proton fluxes events Day to night ratios Magnetic storm events Day to night ratios

         21 April 1998                          6.52                                   24 April 1998                             1.64
        26 August 1998  2.82                              25 September 1998                         1.40
        27 August 1998                        2.00
       01 October 1998                      15.79

Table  II. Hourly ionospheric absorption data as function of the solar zenith angles between 87° and 102°; the
days where the magnetic storm affects the ionospheric absorption more than the solar proton flux were considered.

Date Solar zenith angle Ionospheric absorption (dB)

24 April 1998 87° 0.67
90° 0.59
93° 0.49
96° 0.45
99° 0.51

                                                                     102° 0.51

25 September 1998 87° 0.37

90° 0.35
93° 0.35
96° 0.53
99° 0.53

                                                                     102° 0.47



168

Vincenzo Romano, Massimiliano Cerrone, Loredana Perrone and Marco Pietrella

4.  Conclusions

This investigation found that the hourly
mean ionospheric absorption calculated at

= 96° is at least two times less than that
calculated at = 87° during a PCA phe-
nomenon. This agrees with what was found
by Hargreaves et al. (1993), according to
which the electron density is down to half its
original value at  = 96°.

The hourly mean ionospheric absorption
during a PCA phenomenon is always a
decreasing function of the solar zenith angle
(table I), except for a slight increase observed
at = 96° on August 26th, probably due to
the magnetic storm effect that started on that
day (fig. 1c). A different behaviour can be
observed when the ionospheric absorption is
more affected by a magnetic storm rather than
by a solar proton event (table II).

Table III shows that when the maximum
protons flux occurs by night (21st April, 26th
and 27th August) the ionospheric absorption
day to night ratios are smaller than that oc-
curring by day (October 1st).

The ionospheric absorption day to night
ratio seems to be a suitable index to distinguish
the ionospheric absorption due to a solar
proton event from that due to a magnetic
storm. The cases analysed confirm that a day
to night ratio equal to or greater than 2.0
characterizes a PCA phenomenon (Ranta
et al., 1984).

An investigation into the absorption peak
observed on September 27th (fig. 1c) could
be carried out using a different geomagnetic
index: as ap ( ) comes from planetary index
ap, and concerns above all the F region, the
use of a local polar index such as the PC index
(Troshichev et al., 1979) could be more
suitable to characterize the magnetic storms
and hence to better disclose their possible
influence on the ionospheric absorption.

Acknowledgements

The authors would like to thank Dr. G. De
Franceschi (INGV-Rome, Italy) for helpful
discussions and comments, the Space

Environment Center (NOAA, U.S. Dept. of
Commerce, Boulder-CO, U.S.A.) for supplying
proton data from GOES satellite, and the Italian
National Program of Antarctic Researches
(PNRA) for supporting this study.

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