Repeating earthquakes with nearly identical waveforms are regarded as useful tool for measuring the temporal changes of wave propagation in Earth’s crust. They have a common source and path such that changes in their waveforms can be attributed to variation in material properties. By searching for ML>4 repeating earthquakes in Taiwan using 1991 to 2011 short-period seismic data, we have found 27 repeating earthquake sequences composed of 3 to 7 events. Among the 27 sequences, 17 are short-lived (i.e., lifetime shorter than 3 yrs) while 10 are continual-type (lifetime longer than 3 yrs). Most of the continunal-type repeating sequences are distributed along the east coast of Taiwan with the derived fault slip rates ranging from 3.45 to 7.85 cm/year, which can be used to monitor the change in crustal properties. Among the 10 continual-type sequences, a ML4.6 repeating sequence in Hualien is characterized by largest event number and therefore, regarded as a target sequence for further analysis. We have observed remarkable delayed arrivals in repeating events that occurred after the 1999 M7.6 Chi-Chi mainshock, suggesting a sudden change of seismic wave propagation properties. The effects of near-surface damage and fault zone damage can be roughly separated by the hanging wall and footwall stations based on distinct travel path (not-across vs. across fault). Using spectral coherence derived time-lag between the pre- and post-1999 repeating events, we have identified 4-6 % delay of S-wave velocity for fault zone damage, which is 3-4 fold greater than near surface damage. The reduced velocity in S waves gradually increase to ~1% in 2007 but has not recovered to the pre-Chi-Chi level.