Scaling relationships between sizes of nucleation regions and eventual sizes of microearthquakes

Hiramatsu, Yoshihiro; Furumoto, Muneyoshi

doi:10.1016/j.tecto.2007.01.016

Cited by 2 publications

References 28 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

Empirical Laws of Location and Rupture Time of Asperities for Strong Ground Motion Prediction

Oshima

2024

Preprint

View full text Add to dashboard Cite

The location of asperities on a fault plane, together with rupture times, has a significant influence on strong ground motion. If these positions for predicting strong ground motions of future earthquakes could be set empirically based on data from actual earthquakes, it would be possible to predict ground motions with better accuracy and greater adherence to reality. For some earthquakes, data and dynamic rupture simulations have shown that the time from the beginning of the seismic waveform until the amplitude increases scales with the earthquake magnitude. In this study, the author extracted asperities from fault slip data inferred by waveform inversion and showed that asperity rupture times and distances between asperities (or maximum slip subfault)and hypocenters are proportional to the cube root of the seismic moment. It was also confirmed that this relationship is not merely attributed to an increase in fault area with the increase in magnitude of the earthquake. Scaling laws were also obtained for each earthquake type (inland, inter-plate, and intra-plate) and focal mechanism. The distance from the hypocenter to the asperities (or maximum slip subfault) is the greatest for the strike-slip and inland earthquakes. Furthermore, in 71.1% of the strike-slip earthquakes and 71.8% of the inland earthquakes, the maximum slip point was found to be located shallower than the hypocenter. In addition, 70.5% of the asperities closest to the hypocenter are the largest asperities on the fault plane. The percentages of maximum slip points located at the asperities closest to the hypocenter and at the largest asperity on the fault plane are 73.5% and 86.8%, respectively. The empirical rules presented in this study are useful for improving the accuracy of prediction results by setting the location of asperities and rupture times in the models used for strong ground motion prediction to match those of actual earthquakes.

show abstract

Empirical Laws of Location and Rupture Time of Asperities for Strong Ground Motion Prediction

Oshima

2024

Preprint

View full text Add to dashboard Cite

show abstract

Scaling Relations for Earthquake Source Process

Ide¹

2009

JSSJ

View full text Add to dashboard Cite

This paper reviews recent progress on the scaling studies for earthquakes, including some slow earthquakes. While a standard scaling law for macroscopic parameters with geometrical similarity is valid for most cases, several studies suggest its limits and exceptions. The scaling of seismic energy has been a hot topic in this decade. We review new kinds of scaling studies on seismic source complexity, focusing on three aspects of earthquake evolution. Finally we compare the scaling law for slow earthquakes along the Nankai subduction zone with various similar phenomena worldwide.

show abstract

Scaling relationships between sizes of nucleation regions and eventual sizes of microearthquakes

Cited by 2 publications

References 28 publications

Empirical Laws of Location and Rupture Time of Asperities for Strong Ground Motion Prediction

Empirical Laws of Location and Rupture Time of Asperities for Strong Ground Motion Prediction

Scaling Relations for Earthquake Source Process

Contact Info

Product

Resources

About