Efficiency of earthquake forecast models based on earth tidal correlation with background seismicity along the Tonga–Kermadec trench

The correlation between Earth’s tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However, previous studies have only retrospectively analyzed this correlation after individual large earthquakes; it thus remains vague (i) whether such va...

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Published inEarth, planets, and space Vol. 74; no. 1; pp. 1 - 11
Main Authors Hirose, Fuyuki, Maeda, Kenji, Kamigaichi, Osamu
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 05.01.2022
Springer
Springer Nature B.V
SpringerOpen
Subjects
4. Seismology
Correlation
Earth and Environmental Science
Earth Sciences
Earth tides
Earthquake forecasting
Earthquake prediction
Earthquakes
Geology
Geophysics/Geodesy
Mathematical models
Molchan’s error diagram
p-value
Probability gain
Schuster test
Seismic activity
Seismicity
Seismological research
Tidal power
Tonga–Kermadec trench
Japan
Tonga
Tonga–Kermadec trench
Probability gain
Schuster test
Molchan’s error diagram
value
Earth tides
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Abstract The correlation between Earth’s tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However, previous studies have only retrospectively analyzed this correlation after individual large earthquakes; it thus remains vague (i) whether such variations might be expected preceding future large earthquakes, and (ii) the strength of the tidal correlation during interseismic periods. Therefore, we retrospectively investigated whether significant temporal variations of the tidal correlation precede large interplate earthquakes along the Tonga–Kermadec trench, where M w 7-class earthquakes frequently occurred from 1977 to 31 December 2020. We evaluated a forecast model based on the temporal variations of the tidal correlation via Molchan’s error diagram, using the tidal correlation value itself as well as its rate of change as threshold values. For M w  ≥ 7.0 earthquakes, this model was as ineffective as random guessing. For M w  ≥ 6.5, 6.0, or 5.5 earthquakes, the forecast model performed better than random guessing in some cases, but even the best forecast only had a probability gain of about 1.7. Therefore, the practicality of this model alone is poor, at least in this region. These results suggest that changes of the tidal correlation are not reliable indicators of large earthquakes along the Tonga–Kermadec trench. Graphical Abstract
AbstractList The correlation between Earth’s tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However, previous studies have only retrospectively analyzed this correlation after individual large earthquakes; it thus remains vague (i) whether such variations might be expected preceding future large earthquakes, and (ii) the strength of the tidal correlation during interseismic periods. Therefore, we retrospectively investigated whether significant temporal variations of the tidal correlation precede large interplate earthquakes along the Tonga–Kermadec trench, where M w 7-class earthquakes frequently occurred from 1977 to 31 December 2020. We evaluated a forecast model based on the temporal variations of the tidal correlation via Molchan’s error diagram, using the tidal correlation value itself as well as its rate of change as threshold values. For M w  ≥ 7.0 earthquakes, this model was as ineffective as random guessing. For M w  ≥ 6.5, 6.0, or 5.5 earthquakes, the forecast model performed better than random guessing in some cases, but even the best forecast only had a probability gain of about 1.7. Therefore, the practicality of this model alone is poor, at least in this region. These results suggest that changes of the tidal correlation are not reliable indicators of large earthquakes along the Tonga–Kermadec trench. Graphical Abstract
The correlation between Earth's tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However, previous studies have only retrospectively analyzed this correlation after individual large earthquakes; it thus remains vague (i) whether such variations might be expected preceding future large earthquakes, and (ii) the strength of the tidal correlation during interseismic periods. Therefore, we retrospectively investigated whether significant temporal variations of the tidal correlation precede large interplate earthquakes along the Tonga-Kermadec trench, where M.sub.w 7-class earthquakes frequently occurred from 1977 to 31 December 2020. We evaluated a forecast model based on the temporal variations of the tidal correlation via Molchan's error diagram, using the tidal correlation value itself as well as its rate of change as threshold values. For M.sub.w [greater than or equal to] 7.0 earthquakes, this model was as ineffective as random guessing. For M.sub.w [greater than or equal to] 6.5, 6.0, or 5.5 earthquakes, the forecast model performed better than random guessing in some cases, but even the best forecast only had a probability gain of about 1.7. Therefore, the practicality of this model alone is poor, at least in this region. These results suggest that changes of the tidal correlation are not reliable indicators of large earthquakes along the Tonga-Kermadec trench.
Abstract The correlation between Earth’s tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However, previous studies have only retrospectively analyzed this correlation after individual large earthquakes; it thus remains vague (i) whether such variations might be expected preceding future large earthquakes, and (ii) the strength of the tidal correlation during interseismic periods. Therefore, we retrospectively investigated whether significant temporal variations of the tidal correlation precede large interplate earthquakes along the Tonga–Kermadec trench, where M w 7-class earthquakes frequently occurred from 1977 to 31 December 2020. We evaluated a forecast model based on the temporal variations of the tidal correlation via Molchan’s error diagram, using the tidal correlation value itself as well as its rate of change as threshold values. For M w ≥ 7.0 earthquakes, this model was as ineffective as random guessing. For M w ≥ 6.5, 6.0, or 5.5 earthquakes, the forecast model performed better than random guessing in some cases, but even the best forecast only had a probability gain of about 1.7. Therefore, the practicality of this model alone is poor, at least in this region. These results suggest that changes of the tidal correlation are not reliable indicators of large earthquakes along the Tonga–Kermadec trench. Graphical Abstract
The correlation between Earth's tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However, previous studies have only retrospectively analyzed this correlation after individual large earthquakes; it thus remains vague (i) whether such variations might be expected preceding future large earthquakes, and (ii) the strength of the tidal correlation during interseismic periods. Therefore, we retrospectively investigated whether significant temporal variations of the tidal correlation precede large interplate earthquakes along the Tonga-Kermadec trench, where M.sub.w 7-class earthquakes frequently occurred from 1977 to 31 December 2020. We evaluated a forecast model based on the temporal variations of the tidal correlation via Molchan's error diagram, using the tidal correlation value itself as well as its rate of change as threshold values. For M.sub.w [greater than or equal to] 7.0 earthquakes, this model was as ineffective as random guessing. For M.sub.w [greater than or equal to] 6.5, 6.0, or 5.5 earthquakes, the forecast model performed better than random guessing in some cases, but even the best forecast only had a probability gain of about 1.7. Therefore, the practicality of this model alone is poor, at least in this region. These results suggest that changes of the tidal correlation are not reliable indicators of large earthquakes along the Tonga-Kermadec trench. Graphical
The correlation between Earth’s tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However, previous studies have only retrospectively analyzed this correlation after individual large earthquakes; it thus remains vague (i) whether such variations might be expected preceding future large earthquakes, and (ii) the strength of the tidal correlation during interseismic periods. Therefore, we retrospectively investigated whether significant temporal variations of the tidal correlation precede large interplate earthquakes along the Tonga–Kermadec trench, where Mw 7-class earthquakes frequently occurred from 1977 to 31 December 2020. We evaluated a forecast model based on the temporal variations of the tidal correlation via Molchan’s error diagram, using the tidal correlation value itself as well as its rate of change as threshold values. For Mw ≥ 7.0 earthquakes, this model was as ineffective as random guessing. For Mw ≥ 6.5, 6.0, or 5.5 earthquakes, the forecast model performed better than random guessing in some cases, but even the best forecast only had a probability gain of about 1.7. Therefore, the practicality of this model alone is poor, at least in this region. These results suggest that changes of the tidal correlation are not reliable indicators of large earthquakes along the Tonga–Kermadec trench.
ArticleNumber 10
Audience Academic
Author Hirose, Fuyuki
Maeda, Kenji
Kamigaichi, Osamu
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  givenname: Osamu
  surname: Kamigaichi
  fullname: Kamigaichi, Osamu
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crossref_primary_10_1038_s41598_022_25276_1
Cites_doi 10.1029/ME004p0566
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Keywords Tonga–Kermadec trench
Probability gain
Schuster test
Molchan’s error diagram
value
Earth tides
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– reference: WesselPSmithWHFScharrooRLuisJWobbeFGeneric mapping tools: improved version releasedEos Trans AGU20139440941010.1002/2013EO450001
– reference: MolchanGMEarthquake prediction as a decision-making problemPure Appl Geophys199714923324710.1007/BF00945169
– reference: TalbiANanjoKZhuangJSatakeKHamdacheMInterevent times in a new alarm-based earthquake forecasting modelGeophys J Int20131941823183510.1093/gji/ggt194
– reference: MatsumotoKTakanezawaTOoeMOcean tide models developed by assimilating TOPEX/POSEIDON altimeter data into hydrodynamical model: a global model and a regional model around JapanJ Oceanogr20005656758110.1023/A:1011157212596
– reference: TanakaSOhtakeMSatoHSpatio-temporal variation of the tidal triggering effect on earthquake occurrence associated with the 1982 South Tonga earthquake of Mw7.5Geophys Res Lett2002293-1-3-410.1029/2002GL015386
– reference: TanakaSOhtakeMSatoHEvidence for tidal triggering of earthquakes as revealed from statistical analysis of global dataJ Geophys Res2002107B10221110.1029/2001JB001577
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Snippet The correlation between Earth’s tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However,...
The correlation between Earth's tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after. However,...
Abstract The correlation between Earth’s tides and background seismicity has been suggested to become stronger before great earthquakes and weaker after....
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springer
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StartPage 1
SubjectTerms 4. Seismology
Correlation
Earth and Environmental Science
Earth Sciences
Earth tides
Earthquake forecasting
Earthquake prediction
Earthquakes
Geology
Geophysics/Geodesy
Mathematical models
Molchan’s error diagram
p-value
Probability gain
Schuster test
Seismic activity
Seismicity
Seismological research
Tidal power
Tonga–Kermadec trench
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Title Efficiency of earthquake forecast models based on earth tidal correlation with background seismicity along the Tonga–Kermadec trench
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