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A gravity network with 302 observation points has been established in the western Sichuan Foreland Basin(SFB) to explore Bouguer gravity anomalies(BGAs). Our observational results reveal that the BGAs are negative as a whole, with a maximum value of-220 m Gal(10-5m s-2)at the northwest region of the study area. The real Moho depths beneath the SFB revealed by BGA data change smoothly from 39.5 km in the southeast to 43.7 km in the northwest of the monitoring region. However, the isostatic ones deduced from Airy isostatic model and topographical data vary approximately 39.5–42.0 km. The maximum differences of 2.7 km between the real and isostatic Moho depths are found near the seismic gap between the M8.0Wenchuan and M7.0 Lushan earthquakes, where the crust is in the greatest isostatic imbalance of the monitoring region. Analysis of the isostatic state indicates that the deep dynamic environment near the seismic gap between these two earthquakes indicates an M C 7.0 earthquake in the future. This study indicates that we can use isostasy as a potential approach to study the dynamic process of crustalmaterial movement and to analyze regional potential seismic risks.
A gravity network with 302 observation points has been established in the western Sichuan Foreland Basin (SFB) to explore Bouguer gravity anomalies (BGAs). Our observational results that the BGAs are negative as a whole, with a maximum value of-220 m Gal (10-5 m s-2) at the northwest region of the study area. The real Moho depths beneath the SFB revealed by BGA data change smoothly from 39.5 km in the southeast to 43.7 km in the northwest of the monitoring region. However, the isostatic ones deduced from Airy isostatic model and topographical data vary approximately 39.5-42.0 km. The maximum difference of 2.7 km between the real and isostatic Moho depths are found near the seismic gap between the M8.0 Wenchuan and M7.0 Lushan earthquakes, where the crust is in the greatest isostatic imbalance of the monitoring region. analysis of the isostatic state of the deep dynamic environment near the seismic gap between these two earthquakes indicates an MC 7.0 earthquake in the This study indicates that we can use isostasy as a potential approach to study the dynamic process of crustalmaterial movement and to analyze regional potential seismic risks.