Abstract
In this paper, we aimed to investigate the statistical distributions of shallow earthquakes with 2 ≤ М ≤ 4, located in 13 rectangular areas (clusters) bounded by 120°E and 144°E along the northern boundary of the Amurian microplate. As a result of our study, the displacement of seismicity maxima has been determined and three recurrent spatial cycles have been observed. The clusters with similar distribution of earthquakes are suggested to alternate being equally spaced at 7.26° (360–420 km). A comparison of investigation results on the structure of seismicity in various segments of the Amurian microplate reveals the identity between the alternation pattern observed for meridional zones of large earthquakes and a distinguished spatial period. The displacement vector for seismicity in the annual cycles is determined, and the correspondence between its E-W direction and the displacement of the fronts of large earthquakes is established. The elaborated model of seismic and deformation processes is considered, in which subsequent activation of clusters of weak earthquakes (2 ≤ М ≤ 4), tending to extend from the Japanese-Sakhalin island arc to the eastern closure of the Baikal rift zone, is initiated by the displacement of the strain wave front.
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Acknowledgments
Part of this study was funded through the state task No. 5.1771.2014/K of the Ministry of Education and Science of the Russian Federation, the Russian Science Foundation, according to the Research Project No. 16-17-00015. The authors would like to express their sincere gratitude to the anonymous reviewers for their contributions, constructive and objective comments, and recommendations which helped to significantly improve the manuscript.
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Trofimenko, S.V., Bykov, V.G. & Merkulova, T.V. Space-time model for migration of weak earthquakes along the northern boundary of the Amurian microplate. J Seismol 21, 277–286 (2017). https://doi.org/10.1007/s10950-016-9600-x
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DOI: https://doi.org/10.1007/s10950-016-9600-x