RU2390807C2 - Method of detection of z-shaped twenty-four hour variations of ionospheric indicators in many-years section of f-layer of ionosphere - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: there is measured magnitude and time indicators of earthquakes and also electron density of ionosphere and critical frequency at various time of twenty-four hours. Time variations of measured parametres are evaluated. There is observed velocity of Earth twenty-four hours rotation. Obtained results are averaged to year average. There are determined solar activity, coordinate indicators of Moon deflection on orbit of revolution around the Earth in a heliocentric system of coordinates, and the index of magnitude of tidal zone earthquakes, including those at the moment of the strongest shock in a seismic active zone of Earth crust. On base of obtained data there is drawn a conclusion on possibility of Z-shaped twenty-four-hour variations of ionosphere indicators in many-years section of ionosphere F-layer.

EFFECT: increased reliability of method.

2 cl, 10 dwg

Description

The invention relates to the physics of the ionosphere, and more specifically to methods for predicting extreme changes in the ionosphere that precede local and global climatic (droughts, rainy seasons), seismic and other phenomena on Earth. Their appearance depends on periodically occurring differences in gravitational and electromagnetic effects in spaces of different dimensions. Their manifestations are associated with Z-shaped diurnal variations in a long-term section of ionospheric indicators, and it is most effective for use in agriculture, in regions with seismically active zones - for predicting the geodynamic and ecological situation, as well as for predicting the development of climatic and ecosystem changes.

There are a large number of publications on the study of periodic changes in the ionosphere and seismic activity of the lithosphere over time and the mechanisms of the possible spatial connection of seismically active phases of the Earth. It was found that the effects in the ionosphere are closely related to processes in the earth's crust and the preparation of strong earthquakes. Given the fact that until now the reasons for such changes were not yet known, and there was no theory capable of accurately predicting the duration of cycles of changes in the ionosphere parameters. The development of methods for predicting these processes was carried out on the basis of different, often unrelated approaches.

Due to the fact that the gravitational and radiation effects of the Sun and the Moon on the Earth, as well as the formation of nutation waves in the atmosphere, oceans, and the Earth’s solid shell, earthquake prediction methods based on the gravimetric determination of the Earth’s gravity fluctuations in the zone are known alleged earthquake. See Earthquake Prediction Method. MKI G01V 9/00, a.s. USSR No. 499543. They suggest the establishment of short-term delays in the estimated start of earthquakes.

The disadvantages of the known methods for predicting earthquakes are the specific limitations of the forecast and the low lead time, not exceeding one or two days.

Of the known methods for predicting the duration of the solar activity cycle (SA), the long-term forecast method includes determining the longitudes of the planets of the solar system for the duration of the forecast. See Pat. Russia №2010266, MKI G01W 1/12, 1/00. A method for long-term prediction of the duration of solar activity. Bukharov MV, March 10, 1992 priority. For each predicted planet longitude, the amplitude of the variable component of the solar oscillation velocity is determined under the influence of the time-dependent resulting gravitational extension of the planets, and the duration of the solar activity cycle is determined by the timing at which the velocity amplitude turns to zero.

A slight increase in the lead time of the forecast when taking into account the variable component of the speed of oscillation of the Sun slightly increases the possibility of forecasting in general.

On the way to the gravitational and electromagnetic interaction of the near-Earth medium by experimental methods of remote sensing (terrestrial and satellite vertical), a strong earthquake (magnitude> 6) was associated with a modification of the ionospheric plasma. According to this, a known method for diagnosing the inhomogeneous structure of the region of the ionosphere F-layer after earthquakes comprises measuring ionospheric parameters: critical frequency f ₀ F2, effective height h ′ F, maximum electron concentration N _m F2, effective heights h ₁ , at fixed frequencies f = 4 ... 6 MHz F-layer of the ionosphere after earthquakes. When determining the intra-annual change in these indicators, conclusions are drawn about the possibility of subsequent changes in the performance of the ionosphere F-layer. See the article by Fatkulin M.N. High-frequency diagnostics of the heterogeneous structure of region F after the 1984 Gazli earthquakes Sat. Solar plasma research. Ashgabat. 1989. S. 386.

A certain extension of the list of measured parameters and analysis of the sequence of their changes somewhat increase the possibility of predicting modifications of the ionospheric plasma.

However, a very limited set of indicators of the external influence of the near-Earth environment in the total response of the upper layers of the lithosphere and their separation from taking into account periodic changes in the Earth’s asteroid trace at the heights of the ionosphere F-layer limit the possibilities of synthesizing daily variations of the noted variables. This limits the depth and reliability of the forecast.

The closest in essence and the achieved result (prototype) is a method for detecting the dependence of seismic and ionospheric indicators at the maximum of the F-layer of the ionosphere. See the article Pulinets S.A., Legenkaya A.D., Zelenaya T.I. Dependence of seismic-ionospheric indices at the maximum of the F layer on local time. Geomagnetism and aeronomy. 1998. 38. No. 3. S.178. Priority March 1, 1998. This method includes measuring seismic: magnitude and time, as well as ionospheric indicators (IP): electron density N _m F2, at the maximum of the F-layer of the ionosphere, critical frequency, f ₀ F2, F2-layer of the ionosphere - at different times of the day, and determining their variations in time.

A certain extension of the set-off of temporal variations in the range of seismic and ionospheric indicators somewhat approximates the possibility of taking into account the gravitational and electromagnetic interactions of the near-Earth medium and the geosphere, which in turn somewhat increases the accuracy of the forecast.

However, the limited composition of the indicators forming the forecast, their low level of significance, limited by the onset of earthquakes and the observation period does not allow us to determine the Z-shaped diurnal variations in the long-term IP section in the F-layer of the ionosphere, which will limit the depth and reliability of the forecast method as a whole.

The set of essential features of the claimed invention is sufficient to achieve a technical result - to increase the reliability of the method, increase its lead time and provide conditions for making and obtaining systematic forecasts of changes in the near-Earth environment, that is, the proposed method is aimed at eliminating the noted drawbacks.

This goal is achieved by the fact that they additionally control over a long-term section of the monthly averaged over five days monthly averages of the daily values of the Earth’s daily rotation speed, V, daily variations of the IP by one or multiple during the day in the interval from midnight (23 h LT) summer time until early morning (06 h LT) on magnetically calm Q-days of daily measurement for at least one summer month, followed by averaging to average annual values: critical frequency, f ₀ , F2, electron density, N _m F2 in ma F-maxima ionospheric layer; effective altitude, h′F, and effective altitudes, h ₁ , at fixed frequencies f = 4 ... 6 MHz of the ionosphere F-layer, and also determine solar activity (SA), which is measured by Wolf numbers, W, coordinate indices of the deviations of the Moon, m (′ ′), In orbit around the Earth in a heliocentric coordinate system, the magnitude of tidal zonal earthquakes, M _s , seismically active zones of the earth's crust, including at the time of the greatest shock of earthquakes. In seismically active zones of the earth's crust, at the stages of preparation and implementation of tidal zonal earthquakes of magnitude M _s not less than 6.0 at least five times a year, gravity measurements are carried out with an error of not more than 50 μGal.

The conclusion about the possibility of detecting in a long-term section Z-shaped diurnal variations of at least one of the PIs at the height of the ionosphere F-layer is made, judging by at least a five-year decrease in the Earth’s daily velocity V at the stage of growth of the W CA index, and / or judging by each NS junction, the coordinates m (′ ′) of the deviations of the Moon in the SN direction in the orbit of movement around the Earth relative to the maximum line of the semidiurnal tide at the time of the largest shock of tidal zonal earthquakes, each of which exceeds the magnitude of M a high level of 6.0, and / or judging by each return NS transition, the coordinates m (′ ′) of the deviations of the Moon in the NS direction in the orbit of movement around the Earth relative to the line of maximum daily tide at the time of the largest shock of tidal earthquakes, which follows an extremum with an annual delay at the maximum of the index W CA, and / or judging by each NS return junction, the coordinates m (′ ′) of the deviations of the Moon in the NS direction in the orbit of movement around the Earth through the line of the maximum of the semidiurnal tide at the moment of the largest tidal earthquakes, each of which, in terms of magnitude M, exceeds a threshold level of 7.2, and / or judging by variations in gravity by more than a two-month decrease in the level of gravity beyond the threshold mark of decline, which is at least 300 μGal, and / or the transition of more than a two-month decrease in gravity during the period of action of tidal zonal earthquakes from the stage of preparation and implementation to the preparatory stage of tidal zonal earthquakes.

Joint accounting in a long-term slice of the values of the Earth’s average monthly averaged over five days monthly values of the Earth’s rotation speed, W CA indicator, coordinates of the Moon’s deviations relative to the line of the maximum of the semidiurnal tide in the orbit of the Moon’s movement around the Earth at the time of the largest shock of tidal earthquakes, excesses in magnitude rise the level of tidal zonal earthquakes and variations of gravity at the stage of preparation and implementation of tidal zonal earthquakes, the change of which is supposed to to make a forecast of the marked Z-shaped diurnal variations of the IP, it is easily controlled by commercially available equipment, which are equipped with ground-based and surface-based observatories, ionospheric sounding stations, seismic monitoring, geo-and heliophysical observation stations. A particular advantage of the method is that for its implementation, you can use the existing network of ground, surface observatories and space stations, which covers almost the entire territory of the globe. This makes it possible to carry out local control of changes in these indicators according to previously carried out systematic measurements of the geosphere, SA, gravity, coordinates of the deviations of the moon in the heliocentric coordinate system.

The possibility of proactive detection of marked Z-shaped diurnal variations in the interaction of the Sun, Moon and Earth's geospheres is justified as follows. The complex of high-precision observations and their analysis made it possible to detect, in the process of gravitational and electromagnetic influence of the Sun, the Moon, and the geosphere, the interaction of all types of geophysical fields and the middle space and upper layers of the lithosphere close to resonance. Due to the noted gravitational and electromagnetic interactions in spaces of different dimensions, including the space of time gradients, Z-shaped diurnal variations of the IP are periodically prepared and implemented in a long-term section of the Earth’s asteroid wake at the height of the ionosphere F-layer. This explains the unprovoked changes in gravity, the rise in the magnitude of tidal zonal earthquakes and changes in the coordinate deviations of the moon relative to the maximum line of the semidiurnal tide.

This is due to the fact that the synergetic solar system performs self-organized control of signal transmission processes. By long-distance connections, it reaches a system that affects the Earth’s rotation speed around its own axis, and the response changes in the Earth – Moon system affect gravity variations, deviations of the moon’s coordinate m (′ ′), the indicated Z-shaped diurnal variations of the Earth's IP, and other changes in the geosphere and near-earth environment.

It was found that the beginning of the preparatory period of the Z-shaped diurnal variations of the PI is preceded by a no less than five-year decrease in the Earth’s diurnal velocity at the stage of the growth of the W CA index, a change in the coordinate m (″) of the Moon deviations in the SN direction relative to the maximum semidiurnal tide variations in gravity for a more than two-month decrease in gravity beyond the threshold drop mark, which is at least 300 μGal. This is equally indicated by each extremum at the maximum of W CA synchronous with a lag gap of one year to the transition of the coordinate m (″) of the Moon deviations in the SN direction relative to the maximum line of the semidiurnal tide and each return transition of the coordinate m (″) deviations positions of the Moon in the NS direction relative to the maximum line of the semidiurnal tide, which are synchronous with the transition through the levels of magnitude M of tidal zonal earthquakes equal to 6.0, 7.2.

A characteristic feature of the observed changes in the Earth’s asteroid trail at the altitudes of the ionosphere F is the successive changes in the length of the day in the form of at least a five-year decrease in the Earth’s daily velocity, the position of the Moon at the time of the largest push of tidal zonal earthquakes and the transition of tidal zonal earthquakes through the achieved the magnitude of earthquake magnitudes following synchronously to the extremum at the maximum of W CA, variations in gravity at less than a two-month decrease in the level of gravity beyond the threshold mark of decline, which is at least 300 μGal. In the development of this process, a periodically occurring difference in the gravitational and electromagnetic effects in spaces of different dimensions is traced. In the course of the interaction of the geosphere and the near-earth medium, tidal zonal seismically dangerous earthquakes of the noted magnitudes do not always occur. This leads to a number of external factors of gravitational and electromagnetic origin, noted above. This explains why nothing seemed to be provoked by changes in the long-term section of the Earth’s asteroid wake in the form of Z-shaped diurnal variations of the IP in the long-term section at the height of the ionosphere F-layer.

The proposed method is illustrated by graphical materials, in which Fig. 1 shows a graph of the monthly averaged over five days monthly values of the Earth's rotation speed; figure 2 shows a graph of the hourly positions of the moon from 00 h PT (Beijing time) to 11 h PT and the position of the moon marked with a circle here at the time of the largest shock of the tidal zonal earthquake in Lunyao of magnitude M _s = 6.8 March 8, 1966 relative to the maximum line of the semidiurnal tide here and in the subsequent drawings, the marked OW line separating S and N half-planes; figure 3 shows a graph of the hourly positions of the moon from 12 hours PT to 23 hours PT and the position of the moon at the time of the largest shock of the tidal zonal earthquake in Ninjiang of magnitude M _s = 7.2 March 22, 1966 relative to the maximum line of the semi-daily tide ; figure 4 presents a graph of the hourly positions of the moon from 12 hours PT to 23 hours PT, including the position of the moon at the time of the largest shock of the tidal zonal earthquake in Hetzian of magnitude M _s = 6.3 on March 27, 1967 relative to the maximum daily line the tide; figure 5 shows a graph of the hourly positions of the moon from 11 hours PT to 23 hours PT and the position of the moon at the time of the largest shock of the tidal zonal earthquake in the city of Bokhei of magnitude M _s = 7.4 July 18, 1969 relative to the maximum line of the semi-daily tide ; figure 6 presents a graph of the hourly positions of the moon from 12 hours PT to 23 hours PT and the position of the moon at the time of the largest shock of the tidal zonal earthquake in the city of Khaichen of magnitude M _s = 7.3 February 4, 1975 relative to the maximum line of the semi-daily tide ; Fig. 7 shows a graph of the hourly positions of the Moon from 00:00 PT to 11:00 PT the position of the Moon at the time of the largest shock of the tidal zonal earthquake in Tanshan of magnitude M _s = 7.8 July 28, 1976 relative to the maximum line of the semi-daily tide; on figa and 9 presents the chronological course of diurnal variations in a long-term slice of average annual IP: effective altitude h′F and critical frequency f ₀ F2 of the F2 layer of the ionosphere for the evening (20 h LT, curves 1 and 1 ′), near midnight (23 h LT, curves 2 and 2 ′) and early morning (2 h LT, curves 3 and 3 ′) hours; on figb - indicator W CA; and FIG. 10 is a diagram of NS deviations of the coordinate m (″) of the Moon in SN and NS directions at the time of the greatest push of the marked tidal zonal earthquakes.

The practical implementation of the proposed method does not present any particular difficulties. At observation stations located in various regions of the Earth, including sea-based stations and stations located in outer space equipped with special equipment, they monitor geophysical, seismic, ionospheric and other indicators. Observations are carried out by standard methods, while using a network of observation stations, including astronomical observation stations of the bodies of the solar system, including the sun and moon.

Example 1

Studies of the gravitational and electromagnetic interactions of the Moon, the Sun and the Earth's geosphere were carried out during the rise of the allocated seismic energy in 1964 ... 1981. The beginning of measurements of ordinary geophysical indicators on the territory of the Russian Federation and China coincided with a decrease in the monthly average of five days averaged monthly values of the Earth's rotation speed V 1962 ... 1972. (figure 1) at the stage of growth rate W CA 1963 ... 1968 (figb) and strong tidal zonal earthquakes in the seismically active zone of magnitude M _s zonal earthquakes of more than 4.5, including Hebei province (China). The measured parameters included time measurements, multiple measurements of the magnitude M _{s of} tidal zonal earthquakes, including at the moment of the largest shock of tidal zonal earthquakes, IP at the latitude of the IZMIRAN ionospheric sounding station: effective altitude, h′F, and critical frequency, f ₀ F2, F2 layer of the ionosphere for evening (20 h LT, curves 1 and 1 ′), near midnight (23 h LT, curves 2 and 2 ′) and early morning (2 h LT, curves 3 and 3 ′) hours (Fig. 8a and 9) on magnetically calm Q-days in the summer (June-July); CA 19 ... 21 solar cycles by Wolf numbers, W. At the same time, the coordinates m (′ ′) of the deviations of the Moon were determined in the heliocentric coordinate system in orbit around the Earth.

The beginning of the preparatory stage of the Z-shaped diurnal variations of the FE 1966 was marked by a five-year decrease in the 4 Earth’s daily rotation speed V 1962 ... 1973. (figure 1) at the stage of growth of 5 indicator W CA 1963 ... 1968 (figb). At the same time, from 1966 to 1967, strong tidal zonal earthquakes of magnitude M _s not less than 6.0 in the cities of Lunyao, Ninjiang and Hejiang were noted in Hebei province. During this period, a systematic one-time transition in the SN direction, that is, in the N-half-plane (Figs. 2, 3, 4) was also observed in a change in the coordinate m (″) of the deviations of the Moon.

The subsequent excess of the threshold level of magnitude M _s = 7.2 in 1969 at the time of the largest shock of the tidal zonal earthquake in Bokhei, the level of magnitude M _s = 7.4 (Fig. 5) and the transition with this coordinate m (′ ′) deviations Moon in NS

direction, that is, in the S-half-plane, at the extremum stage 6 at a maximum of 7 of W CA 1963 with one year of delay (Fig. 8b) by Z-shaped diurnal variations in the synchronous change of the ordinates 8 of the effective height h′F of the ionosphere F2 layer 1968 ... 1969 (figa). The observed five-year decrease in the Earth's rotation speed, the transition in the NS direction in the deviations of the Moon: from the N-half-plane to the S-half-plane and the increase in the level of magnitude M _{s of} tidal zonal earthquakes at the moment of the greatest shock, recorded subsequent earthquakes in the cities of Khaichen, Tanshan 1975 and 1976. (6, 7 and 10), which preceded the final Z-shaped diurnal variations of the ordinates 9 of the effective height h′F of the F2 layer of the ionosphere 1978 ... 1979 (figa).

Thus, based on a consideration of the chronological changes in the lithosphere and near-Earth environment, a statistical relationship has been established between the onset of Z-shaped diurnal IP variations at the height of the ionosphere F-layer and the complex of signs preceding it. Long-term decrease in the angular velocity of the Earth’s rotation V at the stage of growth of the W CA indicator, transitions of the coordinate m (′ ′) of the Moon deviations in SN and NS directions, exceeding threshold levels of magnitude M _{s of} tidal zonal earthquakes, using the example of one seismically active zone of the earth's crust, at the stages the preparation and implementation of Z-shaped diurnal variations in the long-term section of the F-layer of the ionosphere IP is preceded by marked Z-shaped changes in the long-term section of the IP of the Earth’s asteroid wake at the height of the F-layer of the ionosphere.

Example 2

In the Russian Federation and China in 1963 ... 1981 Geosphere and near-Earth space indicators were measured, which formed the basis for the search for gravitational-electromagnetic precursors of the interaction of the geosphere, including Z-shaped diurnal variations in the IP in a long-term section of the F-layer of the ionosphere and near-Earth medium.

A search for the marked gravitational-electromagnetic precursors preceding and accompanying the Z-shaped diurnal variations of the IS was carried out by simultaneously measuring the IS at the IZMIRAN ionospheric sounding station in Troitsk in 1963 ... 1981. and changes in gravity in the East China reef system of the seismically active zone of China during the period of tidal zonal earthquakes of magnitude M _s more than 6.0 in 1972 ... 1976.

Within a radius of 250 km from Khaicheng, measurements of gravity were carried out in five repetitions with an error of not more than 40 μGal in the previous period and the period of the implementation of the tidal zonal earthquakes of 1975 (Fig.6) and 1976 (Fig.7) in Haicheng and Tanshan.

In the many-month interval: June 1972 ... May 1973, a marked decrease in gravity was noted in the city of Heichen by 352 μGal, which preceded the Z-shaped diurnal variations of the ordinate 10 of the critical frequency f ₀ F2 of the F2 ionosphere layer 1973 ... 1974. (Fig.9). After a tidal zonal earthquake of 1975 with a magnitude of M _s = 7.3 in this city, the magnitude of gravity returned to almost its original level.

In 1973 ... 1974 changes in the form of many-month variations in decreasing gravity by 350 μGal in Tanshan are noted, synchronous with the indicated Z-shaped daily variations of ordinates 10 of the critical frequency f ₀ F2 of the ionosphere F-layer (Fig. 8). The marked changes in gravity in Tanshan from December 1973 to November 1974 at the beginning did not differ from the first case. However, subsequent variations in gravity directly affected the moment of the onset of the tidal earthquake in Tanshan: the magnitude of gravity increased to its initial level immediately before the tidal zonal earthquake of 1976, i.e., at the preparatory stage. The completion of the Z-shaped daily variations of the ordinates 11 of the critical frequency f ₀ F2 of the F-layer of the ionosphere 1978 ... 1979 (Fig. 9) are synchronous to similar changes of the ordinates 9 of the effective height h′F of the F-layer of the ionosphere (Fig. 8a).

These changes in gravity contain variations of more than a two-month decrease in gravity beyond the threshold level exceeding 300 μGal, and the transition of more than two months of a decrease in gravity from the stages of preparation and implementation to the preparatory stage of the noted tidal zonal earthquakes of 1975 and 1976. According to the noted signs of tidal zonal earthquakes of magnitude M _s greater than 6.0, one can judge the possibility of detecting in a long-term section Z-shaped diurnal variations of the critical frequency f ₀ F2 of the F-layer of the ionosphere, which agrees with Z-shaped diurnal variations of ordinates 10 1973 ... 1974 . (Fig.9).

Claims (2)

1. A method for detecting in a long-term section of the F-layer of the ionosphere Z-shaped daily variations of ionospheric indicators (IP), comprising measuring seismic: magnitude and time indicators of earthquakes, and IP: electron density N _m F2 at the maximum of the F-layer of the ionosphere, critical frequency f ₀ F2 of the F2 layer of the ionosphere at different times of the day, and judging them over time, characterized in that they additionally monitor the interannual section of the monthly averaged over five days monthly average values of the daily velocity of rotation Z Earth V, daily diurnal variation of PI by one / multiple multiple times during the day from midnight (23 h LT) summer time to early morning (06 h LT) summer time on magnetically calm Q-days of daily measurements for at least one summer months, with subsequent averaging to annual average values: critical frequency f ₀ F2, electron density N _m F2 at the maximum of the ionosphere F-layer, effective altitude h'F, and effective altitudes h ' ₁ at fixed frequencies f = 4 ... 6 MHz F-layer ionosphere, and determine solar activity (SA), measured the number of Wolf’s numbers W, the coordinate indices m ('') of the deviations of the Moon in the orbit of movement around the Earth in the heliocentric coordinate system, the magnitude index M _{s of} tidal zonal earthquakes, including at the moment of the greatest shock in the seismically active zone of the earth's crust, and the conclusion about the possibility The Z-shaped diurnal variations in the IP in a long-term section at the height of the ionosphere F-layer are made on the basis of the gravitational and electromagnetic interactions of the Sun, the Moon and the geosphere, judging by at least a five-year decrease in the Earth's rotation speed V at di- growth W SA indicator, and / or appearances for each NS transition coordinates m ( '') of the moon deviations in SN direction relative to the semi-diurnal tide line maximum orbit motion around the earth at the moment of maximum thrust tidal zone earthquakes, each of which level magnitude M _s exceeds the threshold level of 6.0, and / or judging by each return NS transition, the coordinates m (') of the deviations of the Moon in the NS direction relative to the maximum line of the semidiurnal tide in orbit around the Earth at the moment of the greatest shock at of zonal earthquakes, each of which follows with an annual delay following an extremum at the maximum of W CA, and / or judging by each return NS transition of the coordinate m ('') of the deviations of the Moon in the NS direction through the maximum line of the semidiurnal tide in orbit around the Earth in the moment of the greatest shock of tidal zonal earthquakes, each of which exceeds the threshold level of 7.2 by the level of magnitude M _s . 2. The method of detecting in a long-term section of the F-layer of the ionosphere Z-shaped diurnal variations of ionospheric indicators (IP) according to claim 1, characterized in that in seismically active zones of the earth’s crust, additionally, at the stages of preparation and implementation of tidal zonal earthquakes of magnitude M _s not less than 6.0 at least five times a year, measurements of gravity are carried out with an error not exceeding 50 μGal, and the conclusion about the possibility of noted daily variations in PI is made, judging by the variations of gravity for more than two months voltage threshold for gravity fall mark which is not less than 300 microGal and / or judging the transition over a two-month reduction in the action of gravity earthquakes tidal zone between stages of preparing and implementing the preparatory step tidal zone earthquakes.

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