ABSTRACT This study shows evidence based on observations of near-fault ground motions and surface offset that regions with larger-than-average surface offset exhibit weaker ground motions at frequencies 0.5 Hz. This negative correlation of surface offset and high-frequency ground motion is inconsistent with current scaling in kinematic rupture generators. Using rupture dynamic simulations with a linear slip-weakening rheology model combined with observed data enables us to define an input parameter space that is consistent with the observations. Given the multiparameter nature of rupture dynamics, we focus on two parameters: static stress drop and the slip-weakening distance. Under this framework, the observed scaling can be explained if the static stress drop is positively correlated with the slip-weakening distance. We explore the implications of our findings for kinematic source modeling constrained by our rupture-dynamic simulations. We conclude that the ratio between the time of positive acceleration and the total rise time (TRT) is negatively correlated with the TRT, which contrasts with the current assumption of keeping this percentage fixed. Moreover, this study shows that regions with larger-than-average static stress drops tend to radiate weaker high-frequency energy and stronger low-frequency energy.
Pinilla-Ramos et al. (Thu,) studied this question.