Litcius/Paper detail

Self-consistent hardness measurements spanning eleven decades of strain rate on a single material surface

Luciano Borasi, Christopher A. Schuh

2025Nature Communications8 citationsDOIOpen Access PDF

Abstract

A comprehensive understanding of material strength across strain rates typically requires the combination of results from different methods, which often vary in loading conditions and/or sampled volumes, leading to discrepancies in material behavior. This study presents a microindentation approach to measure hardness covering eleven orders of magnitude in strain rate, from quasi-static to phonon drag-dominated rates, on a single material surface under uniform testing conditions. By engineering the geometry of impactors used in laser induced particle impact testing, we extend the breadth of accessible strain rates, including multiple distinct rates exceeding 10⁵ s⁻¹. This self-consistent approach provides clearer insights into high-rate deformation mechanisms. Our results demonstrate a gradual increase in hardness with strain rate from quasi-static up to ultra-high rates, where a sharp upturn in hardness is observed.

Topics & Concepts

Materials scienceStrain rateStrain (injury)Deformation (meteorology)Composite materialIndentation hardnessSlow strain rate testingMicrostructureStress corrosion crackingMedicineInternal medicineAlloyHigh-Velocity Impact and Material BehaviorIon-surface interactions and analysisHigh-pressure geophysics and materials