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A hardening model considering grain size effect for ion-irradiated polycrystals under nanoindentation

Kai Liu, Xiangyun Long, Bochuan Li, Xiazi Xiao, Chao Jiang

2021Nuclear Engineering and Technology21 citationsDOIOpen Access PDF

Abstract

In this work, a new hardening model is proposed for the depth-dependent hardness of ion-irradiated polycrystals with obvious grain size effect. Dominant hardening mechanisms are addressed in the model, including the contribution of dislocations, irradiation-induced defects and grain boundaries. Two versions of the hardening model are compared, including the linear and square superposition models. A succinct parameter calibration method is modified to parametrize the models based on experimentally obtained hardness vs. indentation depth curves. It is noticed that both models can well characterize the experimental data of unirradiated polycrystals ; whereas, the square superposition model performs better for ion-irradiated materials, therefore, the square superposition model is recommended. In addition, the new model separates the grain size effect from the dislocation hardening contribution, which makes the physical meaning of fitted parameters more rational when compared with existing hardness analysis models.

Topics & Concepts

NanoindentationSuperposition principleMaterials scienceHardening (computing)IrradiationGrain sizeDislocationIndentationIndentation hardnessComposite materialMicrostructurePhysicsMathematicsNuclear physicsMathematical analysisLayer (electronics)Metal and Thin Film MechanicsFusion materials and technologiesAdvanced materials and composites
A hardening model considering grain size effect for ion-irradiated polycrystals under nanoindentation | Litcius