In this dissertation, we used time-resolved femtosecond spectroscopy to study the ultrafast dynamics of FeSexTe1-x single crystals, i.e. 11 type iron-based superconductors. The transient reflectivity (ΔR/R) of FeSe0.760, FeSe0.166Te0.666, and FeTe0.875 single crystals has been performed by 400 nm pump-800 nm probe at various temperatures. In general, the typical ΔR/R of 11 type iron-based superconductors includes two significant components. One is the relaxation of photoinduced quasiparticles. The other is the oscillation component due to the acoustic phonon. Interestingly, these characteristics in ΔR/R are strongly changed by the content of Te in FeSe single crystals. For FeSe0.760 and FeSe0.166Te0.666 single crystals, the abnormal changes in the amplitude of ΔR/R are clearly observed at Tc and around 100 K where the structure-phase transition occurred. Also, the electron-phonon(A1g mode) coupling constant can be estimated to be 0.129 and 0.080, respectively, from the relaxation time ΔR/R. Moreover, the acoustic phonon energy estimated from the period of oscillation in ΔR/R markedly shrinks at Tc and around 100 K, which is the so-called phonon softening. However, above phenomena are not observed in the non-superconducting FeTe0.875 single crystals. Therefore, these results imply that the phonon softening occurred in normal state may be intimately correlated to the superconductivity of 11 type iron-based superconductors.