ISSN:
1573-0840
Keywords:
active fault
;
seismotectonics
;
rupture pattern
;
seismic hazard assessment
;
Greece
Source:
Springer Online Journal Archives 1860-2000
Topics:
Energy, Environment Protection, Nuclear Power Engineering
,
Geography
,
Geosciences
Notes:
Abstract Strong seismic events once again confirm the view that great destructive earthquakes are produced by the reactivation of pre-existing faults although they have usually remained inactive for many, perhaps thousands of years. It is evident that such active seismogenic zones, with little or no seismicity, have presumably been ignored in the determination of the region's seismic hazard. At south Peloponnesus, Greece, is situated at Taygetos mountain. At its eastern front lies a large normal fault system, the southern segment being the Sparta fault. This area has been characterized by low seismicity for the last 25 centuries. However, during the 6th and 5th centuries B.C. several destructive earthquakes have been reported. That of 464 B.C., was the most destructive and devastated the city of Sparta. Detailed morphotectonic observations of this area, suggest that the earthquake of 464 B.C. could be related to the most recent reactivation of this fault. The ground accelerations that would be produced by a future activation of the Sparta fault, were calculated, by applying a method which takes into account information mainly from the seismotectonic parameters of the Sparta fault, the rupture pattern, the properties of the propagation medium and the local ground conditions. Moreover, these results were compared with those of other independent studies based mainly on the seismic data of the area. This method estimated greater expected values of ground acceleration than those computed by the conventional seismic hazard methods. The highest values correspond to the activation of the Sparta fault either in a unilateral rupture, which would start from the southernmost point of the fault, or in a circular one. Furthermore, an increase is observed of the order of 50% in the ground acceleration values in unconsolidated soft ground in relation to the corresponding values of hard ground.
Type of Medium:
Electronic Resource
URL:
http://dx.doi.org/10.1023/A:1026464415095
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