TY - JOUR TI - A mechanics-informed deep learning constitutive model for sequential prediction of strain rate-dependent behavior and microstructural evolution JO - Microstructures PY - 2026 VL - 6 IS - 4 SP - EP - 2026081 SN - ISSN 2770-2995 (Online) AB -

Classical constitutive models explicitly couple macroscopic mechanical responses with underlying microstructural evolution, which is crucial for capturing complex deformation mechanisms across varying strain rates. However, current deep learning (DL) constitutive models predominantly focus on macroscopic stress-strain mapping, often neglecting these critical microstructural transitions. To bridge this gap, this work proposes a mechanics-informed deep learning constitutive model (MIDLCM) that integrates gated recurrent units and multi-head attention with a mechanics-informed layer and a mechanics-informed loss, enabling simultaneous prediction of stress response and microstructural descriptors. Trained on a CrFeNi FCC alloy dataset spanning strain rates from 10-4 to 5,000 s-1, MIDLCM accurately reproduces strain-rate-dependent stress-strain behavior and captures the associated evolution of dislocation density and twin volume fraction. Crucially, the model successfully represents the distinct dislocation accumulation regimes and the dynamic transition of plasticity mechanisms - from dislocation-dominated to twinning-assisted - across extreme dynamic loading, consistent with experimental trends and crystal-plasticity-based references. Ablation studies show that attention-based temporal encoding and mechanics-informed constraints contribute complementary improvements while preserving inference efficiency. By explicitly tracking these internal state variables, the proposed framework provides a mechanism-level interpretable and computationally efficient microstructure-mechanics coupled alternative for rate-dependent constitutive modeling and is readily extendable to other alloy systems and loading paths.

KW - Deep learning constitutive model KW - strain rate sensitivity KW - mechanics-informed design KW - multi-element alloys DO - 10.20517/microstructures.2026.17 UR - https://dx.doi.org/10.20517/microstructures.2026.17