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Probabilistic seismic hazard analysis is a process that integrates over uncertainties (e. g. , future earthquake locations and magnitudes) to calculate mean annual rate of exceedance (MRE) of given ground-motion parameter values a site. These rates reflect the contributions of all the sources whose seismic activity is to affect the hazard at that site. Seismic hazard disaggregation provides insights the earthquake scenarios driving the hazard at a given ground-motion level. This presents the disaggregation at each grid point of the Italian rock ground-motion maps developed by Gruppo di Lavoro MPS (2004), Meletti and Montaldo (2007), and Montaldo and Meletti (2007). Disaggregation is used here to compute contributions to the MRE of peak ground horizontal acceleration (PGA) and 5%-damped 0. 2, 1. 0, and 2. 0 sec spectral acceleration values corresponding to different return periods (MRPs of 475 and 2475 yr) from different scenarios. These sce- are characterized by bins of magnitude, M, source-to-site distance, R, and, ε, of standard deviations that the ground-motion parameter is away from its value for that M R pair as estimated by a prediction equation. Maps showing geographical distribution of the mean and modal values of M, R, and ε are presented the first time for all of Italy. Complete joint M–R–ε distributions are also presented selected cities. Except for sites where the earthquake activity is characterized by low-magnitude events, the hazard is generally dominated by local seismicity. , as expected, the MRE of long-period spectral accelerations is generally con- by large magnitude earthquakes at long distances while smaller events at shorter dominate the PGA and short-period spectral acceleration hazard. Finally, for a site, as the MRP increases the dominant earthquakes tend to become larger and to closer to the site investigated.
Barani et al. (Wed,) studied this question.