Layout 6


Anomaly disturbances of the magnetic fields before the strong earthquake
in Japan on March 11, 2011

Yuri A. Kopytenko1, Valery S. Ismaguilov1, Katsumi Hattori2, Masashi Hayakawa3

1 SPbF IZMIRAN, St-Petersburg Department of  IZMIRAN, St-Petersburg, Russia
2 Graduate School of  Science, Chiba University, Chiba, Japan
3 University of  Electro-Communications, Chofu, Tokyo, Japan

ANNALS OF GEOPHYSICS, 55, 1, 2012; doi: 10.4401/ag-5260

ABSTRACT

One of  the strongest earthquakes, with magnitude M 8.9, occurred at the
sea bottom near to the east coast of  Japan on March 11, 2011. This study
is devoted to the investigation of  anomaly disturbances in the main
magnetic field of  the Earth and in ultra-low frequency magnetic variations
(F <10 Hz) observed before this earthquake. Secular variations of  the main
geomagnetic field were investigated using three-component 1-h data from
three magnetic observatories over the 11-year period of  January 1, 2000, to
January 31, 2011. The Esashi and Mizusawa magnetic stations are
situated northwest of  the earthquake epicenter, at distances of  around 170
km to 200 km, and the Kakioka observatory is situated southwest of  the
earthquake epicenter, at a distance of  about 300 km. During this period,
there were four local anomalies in the secular variations. The last anomaly
was the biggest, which began around 3 years prior to the earthquake
moment. All of  the anomalies can be most distinctly recognized, in the form
of  differences in the corresponding magnetic components at these remote
magnetic stations. For investigations of  the ultra-low frequency magnetic
field disturbances, three-component 1-s data at two magnetic stations
(Kakioka and Uchiura) were used. The Uchiura station is situated 119 km
south of  Kakioka, at a distance of  about 420 km from the earthquake
epicenter. Data from the time interval of  February 18, 2011 to March 10,
2011 (only at night-time: 01:00 to 04:00 local time) were investigated in a
wide frequency range. In the frequency range of  0.033 Hz to 0.01 Hz, there
was the clearest anomaly, seen as a decrease in the correlation coefficients
of  the corresponding magnetic components at these two stations, from
February 22, 2011. Differences in the Z components showed an increase,
and became positive after this date. This might suggest that the ultra-low
frequency lithospheric source appeared north of  the Kakioka station.
Outside this specified frequency range, the anomalies were not well defined. 

1. Introduction
One of the strongest earthquakes, with a magnitude Mw

8.9 (Japan Meteorological Agency classification), occurred at
the sea bottom near the east coast of Japan on March 11,
2011. This earthquake triggered a devastating tsunami that

killed over 15,000 people. We have studied the precursors of
this earthquake in the secular variations of the main
geomagnetic field and in the ultra-low frequency (ULF)
magnetic disturbances. 

It is now evident that during the preparation period
prior to a strong earthquake, ULF (F <10 Hz) lithospheric
magnetic emissions with a noise-like character originate
from around the site of the forthcoming earthquake
[Kopytenko et al. 1990, 1993, 2001, 2003, 2007, 2009, Bernardi
et al. 1991, Molchanov et al. 1992, Hayakawa et al. 1996,
Kawate et al. 1998, Molchanov and Hayakawa 1998, 2008,
Ismaguilov et al. 2001, 2002, Hattori 2004, Fraser-Smith
2009]. The intensities of the lithospheric ULF disturbances
are very weak (usually <0.1 nT), but when we can observe
these emissions, the epicentral distances can extend up to 100
km or more [Fraser-Smith 2009, Hayakawa et al. 2007] before
strong earthquakes (M >6). Modern high-sensitivity
magnetometers can detect these weak signals from the
lithospheric sources, although there is a problem with strong
artificial electromagnetic noise, especially in the industrial
areas of Japan. Additionally, there are ULF geomagnetic
pulses of ionospheric origin that can have high amplitudes
during disturbed geomagnetic periods. Therefore, before an
earthquake moment, we can usually observe a superposition
of ULF emissions from different sources at the Earth surface. 

The natural ULF geomagnetic variations have
ionospheric sources. At the Earth surface, the recording points
are usually at large distances from the ionospheric sources
(many hundreds of kilometers), and the ULF disturbance
gradients along the Earth surface are very small and depend
on the distance from the sources [Ismaguilov et al. 1992,
Kopytenko et al. 2000, 2003]. On the other hand, the local
lithospheric ULF sources are situated much closer to the
recording point, and their gradients are greater than those of
the natural pulses [Kopytenko et al. 2000, 2003]. Therefore,
differential methods of data processing are particularly

Special Issue: EARTHQUAKE PRECURSORS

101

Article history
Received June 21, 2011; accepted October 11, 2011.
Subject classification:
Earthquake precursor, Magnetic field, ULF magnetic field, 2011 Japan earthquake.



appropriate to detect these lithospheric signals. The phase-
gradient method [Kopytenko et al. 2000, 2001, 2003, 2007,
2009, Ismaguilov et al. 2001, 2002] is based on the data at three
remote magnetic stations (ULF magnetic gradientometers).
These allow us to find local anomalies in the ULF magnetic
field gradients and phase velocities before the earthquake
moment, and to estimate the direction to a strong earthquake
epicenter during the ‘earthquake preparation phase’.

2. Experimental results

2.1. Secular variations of  the main geomagnetic field
Figure 1 shows a schematic representation of the

epicenter of this earthquake (Figure 1, largest yellow star).
The white triangles in Figure 1 indicate the magnetic stations
at Kakioka (KAK; z = 36.23˚, m = 140.19˚), Esashi (ESA; z =
39.112˚, m = 141.204˚), Mizusawa (MIZ; z = 39.237˚, m = 
= 141.355˚), and Uchiura (UCU; z = 35.16˚, m = 140.20˚).
The ESA and MIZ observatories are situated northwest of
the earthquake epicenter, at distances of 170 km to 200 km
from it. The distance between ESA and MIZ is 19 km, and

the distance between ESA and KAK is 332 km. The epicentral
distance to the KAK station is about 300 km.

Three components (H, D, Z) of the secular variations
of the constant magnetic field at the ESA and KAK
magnetic stations over an 11-year period (January 1, 2000,
to January 31, 2011) are plotted in Figure 2, as the 1-h data.
These data were received from the World Data Centre
(http://swdcwww.kugi.kyoto-u.ac.jp/index.html). The
data were averaged using a 24-point window, to delete SQ
daily variations. The secular variations in Figure 2 are very
similar at KAK and ESA at the scales shown in Figure 2. It can
be seen from Figure 2 that the Z components at these
magnetic stations increased after 2006, the D components
decreased, and the H components slowly decreases during
the whole of this 11-year period. The vertical line to the right
in Figure 2 marks the earthquake moment. In Figure 2 (top
panel), the daily sum of the Kp indices reflects the magnetic

102

KOPYTENKO ET AL.

Figure 1. Location of the magnetic stations (white triangles) and the areas
of strong seismic activity (yellow stars) during the period of January 1,
2000, to January, 2011.

Figure 2. Daily sum of the Kp indices (top panel) and secular variations of
the three components of the main geomagnetic field during the period of
January 1, 2000 to January 31, 2011. The vertical line marks the earthquake
moment.



103

activity. The Kp index is usually calculated using the level of
the ‘magnetic quiet days’ as the ‘zero’ level. However, the
magnetic quiet days level is the level of the secular variation,
so that Kp reflects the activity of the ionosphere-
magnetosphere sources, and these are not connected with the
lithospheric sources. Evidently, the secular time variations in
the six lower curves in Figure 2 are not connected with the
ionosphere-magnetosphere magnetic activity. 

It is very difficult to find any precursors of earthquakes
using the source data presented in Figure 2. We will use
differential values for this purpose. The differences in the
corresponding magnetic components of the two pairs of the
remote magnetic stations (ESA-MIZ, ESA-KAK) are plotted
in Figure 3. The bottom curve of Figure 3 is the difference
dZ(EM) = Zesa – Zmiz. The second curve from the bottom
in Figure 3 is dZ(EK) = Zesa – Zkak, and so on. The
magnitudes of earthquakes (as the US Geological Survey
classification) are indicated at the top of Figure 3. Only
earthquakes with M >4 and with epicentral distances <150
km from the ESA station were taken into account. Anomaly
variations with durations of 1 year to 3 years and of 1 nT to
5 nT amplitude are distinctly seen on the six lower curves.
More exactly, the anomalies are seen in the second panel
from the top of Figure 3, which shows the ratio of the
vertical component difference to the horizontal component
difference: dZ(EM)/dH(EM) = (Zesa – Zmiz)/(Hesa –
Hmiz). The black arrows under this curve mark the
moments of the anomalies, and the red arrows above the
curve mark the moments of seismic shocks with M ≥6. It is
apparent that the shocks have a delay of 1 year to 3-years
relative to the start of the magnetic anomalies. The latest and
the most distinct anomaly shows the longest time interval,
and it increased before the strongest earthquake. The seismic
activity areas during the 11-year period are shown in Figure
1 with the yellow stars, with their magnitudes indicated
inside the stars. After the anomaly of 2002, there was an
earthquake epicenter about 100 km south of the ESA station,
near Sendai city. In 2005 to 2007, the earthquake sites were
situated at the sea bottom at a distance of about 150 km to
200 km southeast of the ESA station. In 2008, an earthquake
epicenter was situated very close to the ESA and MIZ
stations (about 50 km southwest of the ESA station). After
2009, seismic activity was seen at the sea bottom,
approximately as in 2005 to 2007.

2.2. ULF magnetic disturbances
In previous studies, anomaly manifestations in

amplitudes, gradients and phase velocities of the ULF
magnetic disturbances have been found for 1 month to 3
months before strong earthquakes [Kopytenko et al. 2001,
2003, 2007, 2009, Ismaguilov et al. 2001, 2002]. In these
studies we used the data from three magnetic stations
situated at the top of a triangle at the Earth surface, spaced
at distances of 4 km to 6 km (ULF magnetic
gradientometer). The gradient vectors were directed to the
local lithospheric source of the ULF variations, and the phase
velocity vectors were directed to the opposite side. 

In the present study we used the 1-s data from the
Uchiura magnetic station (UCU), which is situated at a
distance of about 420 km from the earthquake epicenter and
from the KAK observatory (KAK station epicenter distance,

ULF DISTURBANCE OF THE JAPAN EARTHQUAKE

Figure 3. Magnitudes (M ≥ 4) of earthquakes (top panel) during the period
of January 1, 2000 to January 31, 2011. The differences (dH, dD, dZ) of
the corresponding magnetic components of pairs of remote magnetic
stations (Esashi-Mizusawa – EM and Esashi-Kakioka – EK) (six lower
curves). Ratio dZ/dH for the Esashi and Mizusawa magnetic stations
(second from top). Black arrows mark moments of the anomalies, and red
arrows indicate the moments of seismic shocks with M ≥ 6.



about 300 km). The distance between UCU and KAK is 119
km, as seen in Figure 1. The data from a time interval of

February 18, 2011 to March 10, 2011 were used (for the last
three weeks before the earthquake). As during the day-time
the man-made noise in Japan is very high, only the night-time
data were used (01:00 to 04:00 local time). The data were
initially filtered using a band-pass filter for different period
ranges of the ULF variations: 10 s to 30 s, 30 s to 100 s, and
100 s to 300 s. The results of this data processing are
presented in Figure 4, where the filled blue squares represent
the H magnetic component, the black crosses, the D
component, and the filled red circles, the Z component. The
following values are plotted in Figure 4, from top to bottom: 

– The root mean square (RMS) of the magnetic
components at the KAK station; 

– The differences dH = Hkak – Hucu, dD = Dkak –
Ducu, dZ = Zkak – Zucu; 

– The ratios Z/h (blue squares) and Z/d (black crosses),
as the vertical component divided by the horizontal one for
the KAK station;

– Cor(H,D,Z), as the correlation coefficients of the
corresponding magnetic components of these remote
stations. 

The period range of 30 s to 100 s in Figure 4 is more
interesting than the other period ranges shown. The
correlation coefficients of the Z components of the KAK and
UCU magnetic stations sharply decreased 18 days before the
earthquake moment (March 11, 2011). The differences in the
Z components increased and became positive. Outside this
specified frequency range, the anomalies are not so well
defined. Ratios Z/h, Z/d $ Z/H, Z/D decrease towards the
earthquake moment, and the RMS values changed according
to the variations in the magnetic activity throughout the
entire period range.

3. Discussion and summary
Two geomagnetic poles in the secular variations closest

to Japan are situated in eastern Siberia and in the Pacific
Ocean, as based on the computations by Demina et al. [2008]
using a dynamic model of sources of the main geomagnetic
field. A long period displacement of these poles leads to
large-space changes in the secular magnetic variations in the
Japan area. When we compare the six curves shown in Figure
2, we can conclude that the space scale of the variations is
very large. In addition, the global geomagnetic activity has
no influence on the secular variations (see Figure 2).
Therefore, the anomalies observed in Figure 3 should be
local, and they have to be situated close to the ESA and MIZ
magnetic stations. The black arrows under the second curve
from the top in Figure 3 (ratio of the vertical component
difference and the horizontal component difference for ESA
and MIZ) mark four anomalies that were discovered. The red
arrows indicate the moments of the earthquakes with M ≥6
(USGS classification). Apparently, the shocks have a 1 year to
3 year delay relative to the starts of the magnetic anomalies.

KOPYTENKO ET AL.

104

Figure 4. RMS of the three magnetic components (Kakioka observatory)
during the period of February 18, 2011 to March 10, 2011 (top curves).
Differences (dH, dD, dZ) of the corresponding magnetic components of
a pair of remote magnetic stations (Kakioka-Uchiura, second from top).
Cor(H,D,Z), as the correlation coefficients of the corresponding magnetic
components of the Kakioka and Uchiura stations. Blue squares, H; black
crosses, D; and red circles, Z component. Ratios Z/h (blue squares) and
Z/d (black crosses), vertical component divided by the horizontal one
(Kakioka, second from bottom).



105

Moreover, these earthquakes were located in different zones
of seismic activity (Figure 1, yellow stars). The seismic zone
(M = 7.0) appeared after the magnetic anomaly in 2002. This
was located about 100 km south of the ESA station, near to
Sendai city. The average depth of the seismic hypocenter was
about 37 km (we considered shocks with M ≥ 4). The
magnetic anomaly of 2005 showed before the beginning of
the seismic activity at the sea bottom, at a distance about 150
km to 200 km southeast of the ESA station (M = 6.9). The
average depth of the seismic hypocenters was about 54 km.
During 2008, the earthquake (M = 6.0) epicenter was
situated very close to the ESA and MIZ stations, and the
average depth of the seismic hypocenter was about 18 km.
After 2009, the seismic activity was at the sea bottom in a
location more eastern than in 2005 to 2007, and the average
depth of the seismic hypocenter was 36 km. The seismic
activity in 2005 to 2007 and after 2009 was located in the
subduction area, and it was probably connected with
movement of the Pacific Plate [Simon 2011]. Seismic activity
at greater depths usually has a tendency to appear earlier in
almost all of the subduction zones [Molchanov 2011]. We
considered only earthquakes with M ≥4, and found that there
was no seismic activity in the subduction zone from 2007 to
2009. 

The start of the anomalies in the total magnetic field
vector before the earthquakes was observed earlier [Sasai and
Ishikawa 1980, Mogi 1985]. These authors interpreted the
effect as a local change in the conductivity in the Earth crust.
Actually, the tectonic movements lead to the generation of
an increased temperature and consequently to higher
conductivity in the earthquake site region. Telluric currents
reallocate near to the local high conductivity region and
create a magnetic anomaly at the Earth surface. The signs of
the anomaly depend on the location of the magnetic stations
relative to an active seismic area [Sasai and Ishikawa 1980].
Additionally, during the earthquake preparation period, a
surface slope can change due to the tectonic processes. A
change in the magnetic sensor orientation is another possible
reason for the generation of the anomaly. For instance, a
tilting of the sensor at 0.01˚ leads to a 6.6 nT change in the
horizontal magnetic component. 

Molchanov and Hayakawa [1998] assumed that the
generation of the ULF seismogenic electromagnetic
emissions is a natural consequence of a microfracturing
process. According to this theory, the intensity of the ULF
emissions increases exponentially with the frequency of the
emissions. From the other side, attenuation of the emissions
in the Earth crust depends on distance and conductivity, and
is inversely proportional to the square root of the emission
frequency. The KAK and UCU magnetic stations are situated
at large distances from the earthquake site (about 300 km
and 420 km, respectively), and therefore mainly long period
disturbances are expected to be observed at these stations.

Industrial noise is very high in the higher frequency regions
of the ULF emissions.

The lowest curves in Figure 4 show the correlation
coefficients of the corresponding magnetic components of the
KAK and UCU magnetic stations for the period ranges of 3 s
to 10 s, 30 s to 100 s, and 100 s to 300 s. The values used are the
mean values for the night-time interval of 01:00 to 04:00 local
time. We observe a sharp decrease in the coefficients before
the earthquake moment of March 11, 2011. Kopytenko et al.
[2009] found an increase in the correlation coefficients before
the moment of an earthquake at the Boso peninsula in 2002.
Nevertheless, the situation was different in that case. The
magnetometers at the Boso peninsula were spaced at a small
distance (about 5 km). The lithospheric emissions thus arrived
at the magnetic stations with very close phases, because the
phase velocity of the ULF disturbance propagation was very
high (tens of km/s), and the correlation coefficients have to
increase when we expect an increase in the intensity of the
lithospheric emissions. In the present case, the distance
between the UCU and KAK stations is 119 km, so that the
lithospheric source was around 300 km distant [Simon et al.
2011]. Therefore, the lithospheric emissions arrived at the
magnetic stations of KAK and UCU with different phases and
the correlation coefficients must decrease when the intensity
of the lithosphere emissions increases. The H and D magnetic
components of the ULF emissions are mostly connected with
ionospheric sources. The Earth crust has a greater influence
on the Z component than on the horizontal ones [Kovtun
1980]. It can be seen from Figure 4 that the clearest anomaly
is in the period range of T = 30 s to 100 s, as a decrease in the
correlation coefficients that was seen from February 22, 2011.

The top parts of Figure 4 show the RMS of the three
magnetic components recorded at the KAK observatory.
Geomagnetic disturbances took place on February 18, 2011,
and on March 1-7, 2011, and the RMS values reflect the
magnetic activity of the magnetosphere-ionosphere origin,
as is seen in Figure 4. The differential values (BKAK – BUCU)
must be proportional to the RMS values if we assume that
sources of the ULF magnetic variations are in the ionosphere
(dB = B1 – B2 = B1(1-k), here B2 = kB1). The amplitudes of the
natural magnetic variations is usually higher than those of
the magnetic emissions of lithospheric origin, but the
gradients are very small because of the very long
wavelength. The differences in Figure 4 (the second curves
from the top) have to be proportional to the RMS (for the
case of natural variations). However, we observe a more
complicated picture, especially in the period range of 30 s to
100 s. It is thus likely that besides the natural sources, there
are additional ULF disturbance sources. The positive
differences in the Z component (Z and D components for
the period range 10 s to 30 s) signify that the ULF magnetic
disturbance sources are situated north of the KAK
observatory. Ratios Z/h and Z/d decreased toward the

ULF DISTURBANCE OF THE JAPAN EARTHQUAKE



earthquake moment (Figure 4, second curves from the
bottom). Similar time variations of the ratios were observed
previously [Yanagihara 1972, Hayakawa et al. 1996]. Outside
the specified frequency ranges, the anomalies are not so well
defined (for F >0.1 Hz, due to a high level of industrial noise,
for F < 0.0033 Hz, due to the high amplitudes of the natural
disturbances). 

In summarizing these results, we can conclude the
following:

– During the period of 2000 to 2011, there were four
local anomalies in the secular variations. The last of these
anomalies was the biggest one, and it began about 3 years
prior to the earthquake moment. All of these anomalies are
most distinctly seen in the form of the differences of the
corresponding magnetic components at these remote
magnetic stations. The distinctive form of the anomalies in
the second curve from the top in Figure 3 can be explained
by a tilting of the magnetic sensors situated at the ESA and
MIZ observatories during the development of the tectonic
processes, or by a change in the conductivity of the anomaly
zone before the earthquake. At the first stage, tectonic
pressure in the subduction zone leads to an increase in the
temperature and conductivity in the area of the forthcoming
earthquake hypocenter. At the second stage, the increases in
the numbers and sizes of microfractures lead to a decrease in
the anomaly conductivity to the initial level, if there is no
water at such great depths. In this case, the ratio
dZ(EM)/dH(EM) will increase or decrease (depending on
the anomaly disposition relative to the magnetic stations),
and then the ratio will return to its initial level. 

– In a frequency range of 0.033 Hz to 0.01 Hz, there was
the clearest anomaly, which is seen as a decrease in the
correlation coefficients of the corresponding magnetic
components of the two remote stations from February 22,
2011. The differences in the Z components increased and
became positive after this date. It appears that the ULF
lithospheric source was north of the Kakioka station.
Outside the specified frequency ranges, the anomalies are
not well defined. To determine the epicenter position of a
forthcoming earthquake, ULF magnetic gradientometers
need to be used [Kopytenko et al. 2001, 2003, 2007, 2009,
Ismaguilov et al. 2001, 2002].

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*Corresponding author: Masashi Hayakawa,
University of Electro-Communications, Chofu Tokyo, Japan; 
email: hayakawa@whistler.ee.uec.ac.jp.

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