Sentence examples for behavior at high strain from inspiring English sources

The metallic glass exhibited superplastic-like deformation behavior at high strain rates, resulting in an excellent workability.

Our results enable the study of syntactic foam behavior at high strain rates, for a wide range of strain rates, microballoon densities, and microballoon volume fractions.

While several models have been proposed to analyze the elastic response and failure of these composites at small strain rates, the understanding of syntactic foam behavior at high strain rates remains elusive.

This paper deals with the effect of low temperature on the compressive behavior at high strain rate of two aluminum alloys, 2024-T4 and 7075-T6 using a modified split Hopkinson pressure bar (SHPB) with a pulse shaper technique.

The results indicate that a change in the mobile dislocation density, together with thermal softening, has substantial effects on apparent work hardening behavior at high strain rates, although the change in the mobile dislocation density is transcribed at macroscopic scale in the model.

The results suggest that ECA pressing with R=90° rotation is most effective in producing a reasonably homogeneous microstructure consisting of fine intermetallic particles and equiaxed fine subgrains, and that such microstructure formation could contribute to the superplastic-like deformation behavior at high strain rate.

It is important to mention here that obtained results are solely based on the material behavior of concrete which is affected by strain rate and DIF as defined in "Material behaviors at high strain rate" and "Dynamic behavior of concrete under high strain rates" sections.

For nonlinear materials, the steel and concrete uniaxial behaviors beyond the elastic range must be defined to simulate their behavior at higher strains.

A new experimental method for testing the dynamic tensile behavior of concrete at high strain rates was designed and established.

For a better understanding of traumatic bone fractures, knowledge of the mechanical behavior of bone at high strain rates is required.

Our work demonstrates the utility of TTSP in connecting the thermo-mechanical behavior of polymers at high strain rates and high temperatures to experiments performed at much different conditions.