The hot deformation characteristics of 1.4462 duplex stainless steel(DSS)were analyzed by considering strain partitioning between austenite and ferrite constituents.The individual behavior of ferrite and austenite in microstructure was studied in an iso-stress condition.Hot compression tests were performed at temperatures of 800-1100 C and strain rates of 0.001-1 s 1.The flow stress was modeled by a hyperbolic sine constitutive equation,the corresponding constants and apparent activation energies were determined for the studied alloys.The constitutive equation and law of mixture were used to measure the contribution factor of each phase at any given strain.It is found that the contribution factor of ferrite exponentially declines as the Zener-Hollomon parameter(Z)increases.On the contrary,the austenite contribution polynomially increases with the increase of Z.At low Z values below 2.6.×1015(lnZ=35.5),a negative contribution factor is determined for austenite that is attributed to dynamic recrystallization.At high Z values,the contribution factor of austenite is about two orders of magnitude greater than that of ferrite,and therefore,austenite can accommodate more strain.Microstructural characterization via electron back-scattered difraction(EBSD)confirms the mechanical results and shows that austenite recrystallization is possible only at high temperature and low strain rate. The hot deformation characteristics of 1.4462 duplex stainless steel (DSS) were analyzed by considering strain partitioning between austenite and ferrite constituents. The individual behavior of ferrite and austenite in microstructure was studied in an iso-stress condition. Hot compression tests were performed at temperatures of 800-1100 C and strain rates of 0.001-1 s 1. The flow stress was modeled by a hyperbolic sine constitutive equation, the corresponding constants and apparent activation energies were determined for the studied alloys. The constitutive equation and law of mixture were used to measure the contribution factor of each phase at any given strain. It is found that the contribution factor of ferrite exponentially declines as the Zener-Hollomon parameter (Z) increases. On the contrary, the austenite contribution polynomially increases with the increase of Z.At low Z values ​​below 2.6. × 1015 (lnZ = 35.5), a negative contribution factor is determined for austenite that is attributed to dyn amic recrystallization. At high Z values, the contribution factor of austenite is about two orders of magnitude greater than that of ferrite, and therefore, austenite can accommodate more strains. Microstructural characterization via electron back-scattered difraction (EBSD) confirms the mechanical results and shows that austenite recrystallization is possible only at high temperature and low strain rate.