The kinetic,morphological,crystallographic,and magnetic characteristics of thermally induced martensites in Fe-13.4wt% Mn-5.2wt%Mo alloy were investigated by scanning electron microscopy(SEM),transmission electron microscopy(TEM),and M(o|¨)ssbauer spectroscopy.The experimental results reveal that two types of thermal-induced martensites,e(hcp) andα’(bcc) martensites,are formed in the as-quenched condition,and these transformations have athermal characters.Mo addition to the Fe-Mn alloy does not change the coexistence ofεandα’ martensites with the Mn content between 10wt%and 15wt%.Besides,M(o|¨)ssbauer spectra reveal a paramagnetic character with a singlet for theγ(fcc) austenite andεmartensite phases and a ferromagnetic character with a broad sextet for theα’ martensite phase. The volume fraction ofα’ martensite forming in the quenched alloy is much more than that of theεmartensite. The kinetic, morphological, crystallographic, and magnetic characteristics of thermally induced martensites in Fe-13.4 wt% Mn-5.2 wt% Mo alloy were investigated by scanning electron microscopy (SEM), transmission electron microscopy (TEM), and M (o | ) ssbauer spectroscopy. The experimental results reveal that two types of thermal-induced martensites, e (hcp) and α ’(bcc) martensites, are formed in the as-quenched condition, and these transformations have athermal characters. Mo addition to the Fe- Mn alloys does not change the coexistence ofεandα’martensites with the Mn content between 10wt% and 15wt% .Besides, M (o | ¨) ssbauer spectra reveal a paramagnetic character with a singlet for theγ (fcc) austenite andεmartensite phases and a ferromagnetic character with a broad sextet for theα ’martensite phase. The volume fraction ofα’ martensite forming in the quenched alloy is much more than that of theεmartensite.