Abstract In this work, the cyclic softening/hardening characteristics of a TRIP-assisted duplex stainless steel (DSS) was studied within the strain amplitude range of 0.2 ~ 1.2 % , and the evolution of dislocation structures was characterized by TEM to clarify the cyclic deformation mechanism of both phases. At various strain amplitudes (ea), the test DSS showed different levels of cyclic softening after an initial cyclic hardening except for the case of ea=0.2%, where a direct cyclic saturation was present. Cyclic softening rate ( δ ) was sensitive to ea, and particularly, it showed a continuous decrease at eap>0.25% (ea>0.5%). In the samples approximately cycled to failure, the dislocation structure in ferrite mainly developed in the order of patch, wall and/or poor-formed cell with the increasing ea, which corresponded to the progressively enhanced rearrangement of dislocation, while the strain-induced martensitic transformation (SIMT) with a sequence of γ→stacking faults (SFs)→e→α′ was activated with increasing ea, and it was considered to be a main cause for the decreasing δ . Moreover, the cyclic response of the individual phases was further discussed by analyzing the “characteristic peak” on the second derivative curve of cyclic hysteresis loop in relation to the evolution of substructures in the two phases.

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