Simulations of Nanocrystalline Iron Formation under High Shear Strain

TL;DR

This study uses molecular dynamics simulations to investigate how high shear strain leads to nanocrystalline iron formation, revealing the effects of temperature, heat dissipation, strain rate, and impurities on grain size and structure.

Contribution

It provides a detailed simulation-based analysis of nanocrystalline iron formation mechanisms under high shear, highlighting the influence of various parameters.

Findings

Higher temperatures produce larger grains.

Faster heat dissipation initially increases small grains, then reduces their number.

Slower strain rates do not favor nanograin formation.

Abstract

High-shear methods have long been used in experiments to refine grain structures in metals, yet the underlying mechanisms remain elusive. We demonstrate a refinement process using molecular dynamic simulations of iron, wherein nanocrystalline structures are generated from initially perfect lattices under high-shear strain. The simulation cells undergo a highly disordered state, followed by an atomic reordering and grain coarsening, resulting in nanograins. We explore the dependence on parameters such as temperature, heat dissipation rate, shear strain rate, and carbon impurity concentration. Higher temperatures lead to the formation of larger and longer grains. The faster heat dissipation sample initially yields more small grains, but their number subsequently reduces, and is lower than the slower heat dissipation sample at approximately {\gamma} = 1.5. Slower strain rates do not promote nanograin formation. The presence of carbon impurities appears to have little effect on grain formation. This detailed analysis affords insight into the mechanisms that control the formation of nanograins under high-shear conditions.