Repeating earthquakes (RE) identified by nearly identical waveforms, location, and size represent repeated ruptures driven by aseismic slip in the surrounding. Given that their magnitude and recurrence interval are sensitive to the loading condition of fault, RE serves as a powerful tool to study the spatiotemporal distribution of aseismic slip behavior at depth. Here we build the M2+ repeating earthquakes catalog and investigate spatiotemporal distribution of aseismic slip behavior around Taiwan. During 2000-2011, about 1.3% of M2+ earthquakes (out of 134,731 events) in Taiwan were detected as repeating events. The 329 RE sequences composed of 1853 events are mainly located in six seismogenic regions: Longitudinal Valley, the north of Central Range, Miaoli area, Nantou area, south of Central Range area, and southeastern offshore area. The regional slip rates in most of the areas range from 3.5 to 4.2 cm/yr. In the six areas, only the events in the Longitudinal Valley region reveal linear trend, coinciding with the orientation of Longitudinal Valley and Central Range faults. Taking advantage of highly similar path effect of RE in a sequence, we obtained the empirical relation between magnitude and distance for individual RE. Various empirical relation obtained for different RE sequences indicates the strong variation in attenuation structure in Taiwan. These magnitude vs. distance relations provide a constraint for attenuation structure especially in where the RE are concentrated, eastern Taiwan.