Deformation-induced phase transition of Form Ⅱ to Form Ⅰ in polybutene-1 (PB-1) has been investigated by time-resolved Fourier transform infrared (FTIR) spectroscopy over a wide temperature range from 25 ℃ to 105 ℃.The initial film sample containing orientated lamellae is prepared by pre-stretching of PB-1 melt followed by solidification.This is to realize a homogeneity of subsequent deformation at the mesoscale of lamellar stacks by avoiding large-scale spherulites.The deformation induced phase transition is recognized to occur with two stages:first,Form Ⅱ undergoes the lamellar fragmentation,slipping or local melting after yielding to activate its transition to Form Ⅰ,which may be realized by releasing the restrictions on chains translational movements in crystalline phase;second,the phase transition proceeds with a continuous dissipation of extal work and determines the tensile mechanical response of film.To quantify the relationship between crystalline transition of Form Ⅱ to Form Ⅰ and extal tensile field,a simple kinetic equation is well established based on FTIR measurement.The equation can describe not only the dependence of crystal transitional degree on applied specific work,but also the retardation effect of elevating temperature on phase transition.