Annals n.6/2003 ok 23/04


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ANNALS  OF  GEOPHYSICS, VOL.  46, N.  6, December  2003

Key  words volcanic eruption – lower ionosphere –
atmospheric waves – radio wave absorption

1. Introduction

The Mt. Pinatubo volcano erupted in June
1991. This eruption was accompanied by the
largest injection of volcanic aerosols into the
stratosphere observed in the 20th century. The
cloud of erupted aerosols reached altitudes
around 30 km. After the Mt. Pinatubo eruption
the stratosphere warmed due to the absorption
of radiation by the new aerosols produced by
the eruption, particularly at low latitudes (e.g.,
Labitzke, 1994). The absorbed radiation was
missing in the troposphere and, therefore, the
troposphere cooled. At middle and higher lati-
tudes, the enhanced concentration of volcanic

aerosols resulted (with some delay) in a reduc-
tion of ozone concentration in the (lower) strat-
osphere (e.g., McGee et al., 1994). Some 1-2
years after the eruption the ozone reduction-re-
lated cooling overwhelmed the original aerosol
heating and a mild cooling of the stratosphere
appeared (e.g., Randell et al., 1995).

The pronounced volcano-related changes in
the troposphere and stratosphere allow us as-
sume the possibility of changes in the lower
ionosphere due to:

– Changes in tropospheric sources of upward
propagating waves (gravity and planetary).

– Changes in filtering properties of the stra-
tosphere to the upward propagating waves.

Here such possible changes in the lower
ionosphere are studied with the use of radio
wave absorption measurements (monitoring) in
the lower ionosphere over Central Europe. Pos-
sible effects on gravity and planetary wave ac-
tivity inferred from absorption measurements
and on absorption itself are investigated. The
existence of the effect of Mt. Pinatubo on the
gravity wave activity inferred from absorption
was demonstrated by Laštovička et al. (1998).

Impact of the Mt. Pinatubo volcanic
eruption on the lower ionosphere and

atmospheric waves over Central Europe

Jan Laštovička
Institute of Atmospheric Physics, Academy of Sciences of Czech Republic, Prague, Czech Republic

Abstract
The very strong volcanic eruption of Mt. Pinatubo in June 1991 directly affected the troposphere and lower and
middle stratosphere. Here we look at its effects in the mesopause region as revealed by the radio wave absorp-
tion measurements in the lower ionosphere over Central Europe and inferred planetary and gravity wave activi-
ty. The gravity wave activity inferred from the nighttime LF radio wave absorption displays an evident en-
hancement for waves of periods of about 2-3 h coinciding with regional measurements of the optical depth of
(volcanic) aerosols, while there is no detectable effect for short period waves (T < 1 h). There is no detectable
effect in the planetary wave activity inferred from the daytime HF radio wave absorption. As for the absorption
itself, the results on the impact of the Mt. Pinatubo eruption do not provide an observable effect.

Mailing address: Dr. Jan Laštovička, Institute of At-
mospheric Physics, Academy of Sciences of Czech Repu-
blic, Boční II, 14131 Prague 4, Czech Republic; e-mail:
jla@ufa.cas.cz



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Jan Laštovička

Section 2 describes data and methods. Sec-
tion 3 illustrates effects in gravity wave activity.
Section 4 deals with possible effects in planetary
wave activity and Section 5 in the absorption it-
self. The paper ends with brief conclusions.

2. Data and methods

The radio wave absorption in the lower ion-
osphere was measured by the A3 method,
which consists in receiving a continuous sky
wave transmitted usually by a commercial
transmitter with an oblique incidence on the
ionosphere. The A3 method exists in two ver-
sions, Low Frequency (LF) version and Medi-
um/High Frequency (MF/HF) version, which
differ by the method of calibration and by an-
tenna systems. The LF version in digital modi-
fication used by us was described by Laštovička
et al. (1993). The HF A3 measurements used in
the paper were described by Laštovička and
Jiskra (1978) in the older analog version, which
was operating till the early 1990s.

The LF absorption was measured at Pruhon-
ice on 270 kHz (reflection point 49.45oN,
16.05oE; transmitter-receiver distance 236 km;
nighttime reflection height ~ 95 km). The grav-
ity wave activity (in terms of average gravity
wave amplitude) was inferred from well night-
time data ( χ > 100o) by the correloperiodogram
method applied to each individual night (for de-
tails see Laštovička  et al., 1993). The well-night-
time data are used to exclude the effect of
strong daytime variation of reflection height,
i.e. of substantial changes in the height region
where the absorption is created, on the derived
gravity wave activity. Moreover, well in day-
time there is no measurable signal on the given
frequency due to total absorption.

The HF absorption was measured at Panska
Ves on 6090 kHz (reflection point 50.07oN,
10.30oE; transmitter-receiver distance 610 km;
daytime reflection height ~ 97-98 km). Daytime
absorption data at solar zenith angle χ = 75o (av-
erage from morning and afternoon data) are used
for inferring the planetary wave activity (in terms
of average planetary wave amplitude) from con-
secutive 2 month planetary wave oscillation spec-
tra by the correloperiodogram method (for details

see, e.g., Pancheva et al., 1989). At night and high
solar zenith angles close to sunrise and sunset, ra-
dio waves for this radio path are reflected in the F
region, i.e. we cannot measure a pure absorption
in the lower ionosphere. Therefore, only well-
daytime data may be used.

The aerosol optical depth is considered as a
measure of volcanic aerosols. We use data
measured at relatively nearby station Geest-
hacht, Germany, 53.4oN, 10.4oE (Ansman et al.,
1997). They published data for August 1991-
March 1995. The pre-Pinatubo level of aerosols
was taken to be equal to the essentially undis-
turbed level of January-March 1995. A possible
error in estimating the pre-Pinatubo level does
not play a role with respect to the large
Pinatubo-related increase of concentration of
volcanic aerosols in the stratosphere, which
peaked at Geesthacht in 1992 and winter/early
spring 1993 (see fig. 1).

3. Gravity waves

The effect of the Mt. Pinatubo volcanic
eruption on the gravity wave activity was stud-
ied in Central Europe based on the nighttime
absorption at 270 kHz by Laštovička et al.
(1998) and Laštovička (1999). Figure 1 shows
the development of gravity wave activity in six
period ranges between 10-180 min in the win-
ter half of the year (October-March) for winters
1988/1989-1994/1995 (the last two winters Oc-
tober-December only). The measurements be-
came unreliable after 1 January 1995 due to
changes of transmitter regime. They were ter-
minated a couple of years ago. All available
wintertime data are shown in fig. 1.

An evident increase in gravity wave activity
after the Mt. Pinatubo eruption is revealed at
long periods (T > 120 min, top curves) in very
good coincidence with the large increase in the
volcanic aerosol optical depth. This increase in
gravity wave activity is well pronounced de-
spite the decreasing solar activity (Laštovička
(1999) found an increase in gravity wave activ-
ity with increasing solar activity). However, no
detectable Pinatubo-related change of the grav-
ity wave activity at short periods (T < 60 min,
bottom curves) can be observed. 



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Impact of the Mt. Pinatubo volcanic eruption on the lower ionosphere and atmospheric waves over Central Europe

What might be the origin of the longer-period
(2-3 h) gravity wave activity response to the Mt.
Pinatubo eruption? The seasonal variation pattern
of the gravity wave activity and its change with
altitude in the middle atmosphere is significantly
affected by the background wind and temperature
fields, which affect propagation and dissipation
of gravity waves (e.g., Gavrilov and Fukao,
1999). On the other hand, the solar cycle depend-
ence of the seasonal variation pattern of the grav-
ity wave activity inferred from the 270 kHz night-
time radio wave absorption measurements seems
to be substantially affected by a shift of the aver-
age storm tracks in the Northern Atlantic region,
i.e. by changes in the gravity wave source (Boš-
ková and Laštovička, 2001). Background temper-

ature fields in the troposphere and stratosphere
were affected by the Mt. Pinatubo eruption. As
concerns other parameters, sufficient information
is not available. Nevertheless, some changes in
the wind field and maybe tropospheric storm
tracks can be expected, which would mean that
both the changes in gravity wave sources and fil-
tering properties of the stratosphere could play a
role. However, it is not clear at all why the
longer period gravity waves are affected, where-
as this is not the case for the short period gravi-
ty waves.

Unfortunately, the available data do not en-
able us to analyze effect of another strong vol-
canic eruption, that of El Chichon in 1982. As
far as I know, the impact of volcanic eruptions

Fig. 1. Gravity wave activity (relative amplitude in %) inferred from the nighttime 270 kHz absorption meas-
ured in Central Europe, winters of 1988/1989-1994/1995 (after Laštovička, 1999). R - sunspot number. Winter
data points – October-December and January-March averages. Gravity wave periods (from bottom to top of the
figure): ∆ for 10-30 min, + for 31-60 min, for 61-90 min, + for 91-120 min, for 121-150 min, + for 151-
180 min.



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Jan Laštovička

on the gravity wave activity in the upper
mesopause region has not been studied by any
other author.

4. Planetary waves

The daytime 6090 kHz absorption is used to
investigate the potential effect of the Mt. Pina-
tubo eruption on the planetary wave activity in
the lower ionosphere in Central Europe. Figure
2 displays the development of the planetary
wave activity for the period 1971-1996. Each
data point is taken from a spectrum computed
from a two-month interval.

We do not see any observable effect of the
Mt. Pinatubo volcanic eruption on the plane-
tary wave activity as deduced from daytime
radio wave absorption in Central Europe. In

the 1990s, the only evident change is a de-
creasing variability of the planetary wave ac-
tivity towards the end of the period. On the
other hand, the planetary wave activity is very
noisy, so a small effect of Pinatubo would be
undetectable. Nevertheless such a clear effect
like that in the gravity wave activity evidently
has not been observed. If the main reason of
the effect of Pinatubo in the gravity wave ac-
tivity is a shift in storm tracks, then we should
expect rather no effect of Pinatubo on the
planetary wave activity, which is not affected
significantly by shifts of storm tracks.

5. Radio wave absorption

The 270 kHz measurements are reliable till
the end of 1993. Since January 1994 they are

Fig. 2. Planetary wave activity (amplitude) inferred from the daytime 6090 kHz radio wave absorption meas-
ured in Central Europe at the solar zenith angle of 75o, October 1971-August 1996. 



1343

Impact of the Mt. Pinatubo volcanic eruption on the lower ionosphere and atmospheric waves over Central Europe

mostly unreliable due to transmitter problems
except for a few months (fortunately those al-
lowing construct fig. 1). Therefore only the
6090 kHz data are used to examine the effect of
the Mt. Pinatubo eruption in radio wave ab-
sorption itself. To find the possible effect, ma-
trices of correlation coefficients and partial cor-
relation coefficients are computed and the prin-
cipal component analysis without and with ro-
tated axes is applied. Monthly mean values of
the aerosol optical depth, sunspot number (solar

activity), aa index (geomagnetic activity) and
absorption are used. The results are presented in
tables I-IV.

Tables I and II show that neither correlation
coefficients, nor partial correlation coefficients
reveal an effect of the Mt. Pinatubo eruption on
radio wave absorption. The correlations point
to the well-known positive relation between
absorption and solar activity (via changes of
intensity of ionizing radiation). The correlation
between volcanic aerosol and sunspots is acci-
dental due to the occurrence of aerosol recov-
ery at the decay branch of the solar cycle.

Neither standard (table III), nor rotated
(table IV) principal component analysis pro-
vides an effect of Mt. Pinatubo eruption on ra-
dio wave absorption. This corresponds to the
results based on correlations shown in tables I
and II. Table IV again points to some relation
between absorption and solar activity (sun-
spots) and displays the above-explained acci-
dental correlation of aerosol and sunspot cycle.
Thus we can say that there is no observable ef-
fect of the Mt. Pinatubo volcanic aerosols on
daytime radio wave absorption in the lower ion-
osphere above about 90 km.

6. Conclusions

All conclusions are based on the radio wave
absorption measurements in the lower iono-
sphere over central Europe.

i)  No observable effects of the Mt. Pina-
tubo volcanic eruption were found in the day-
time HF radio wave absorption itself and in
the planetary wave activity inferred from this
absorption.

ii)  In the gravity wave activity derived
from the nighttime LF radio wave absorption,
no effect of Mt. Pinatubo was found for short-
period gravity waves (T < 1 h). However, a
substantial intensification of the longer-peri-
od gravity wave activity (T = 2-3 h) was ob-
served.

iii) The origin of the gravity wave activity
enhancement may be due to both changes in
properties of the middle atmosphere and in
gravity wave sources. The real origin of this en-
hancement and an answer to the question while

Table I. Matrix of correlation coefficients.

Aerosol Sunspot aa Absorption

Aerosol 1 0.61 0.09 0.07  
Sunspot 0.61 1 0.35 0.51
aa 0.09 0.35 1 0.19
Absorption 0.07 0.51 0.19 1

Table II. Matrix of partial correlation coefficients. 

Aerosol Sunspot aa Absorption

Aerosol 1 0.68 – 0.18 – 0.36
Sunspot 0.68 1 0.33 0.57
aa – 0.18 0.33 1 – 0.04
Absorption – 0.36 0.57 – 0.04 1

Table III. Principal component analysis (f 1 + f 2 +
+ f 3 = 95%).

Factor f 1 f 2 f 3

% 50% 25% 20%
Aerosol 0.67 – 0.69 – 0.12
Sunspot 0.93 – 0.11 0.06
aa 0.51 0.52 – 0.67
Absorption 0.63 0.48 0.58

Table IV. Varimax rotated principal component
analysis.

Factor f 1 f 2 f 3 f 4

Aerosol 0.96 0 0.02 0.26
Sunspot 0.40 0.32 0.20 0.83
aa – 0.04 0.08 0.99 0.13
Absorption 0.01 0.97 0.08 0.21



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Jan Laštovička

only longer-period gravity waves are enhanced
is not clear at present and will be the subject of
further investigations.

Acknowledgements

This study was supported by the Academy
of Sciences of the Czech Republic, projects
Z3042911 and K3012102.

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(received June 27, 2003;
accepted October 15, 2003)