Tension–compression asymmetry in amorphous silicon
PDF] Weibull analysis of fracture strength for Zr_55Ti_2Co_28Al_15 bulk metallic glass: Tension–compression asymmetry and porosity effect
OpenKIM · EDIP JustoBazantKaxiras 1998 Si MO_958932894036_002 MO_958932894036 · Interatomic Potentials and Force Fields
A self-aligning microtensile setup: Application to single-crystal GaAs microscale tension–compression asymmetry, Journal of Materials Research
Plastic anisotropy and tension-compression asymmetry in nanotwinned Al–Fe alloys: An in-situ micromechanical investigation - ScienceDirect
Microstructure evolution and mechanical behavior of additively manufactured CoCrFeNi high-entropy alloy fabricated via cold spraying and post-annealing - ScienceDirect
Anomalous tension–compression asymmetry in amorphous silicon: insights from atomistic simulations and elastoplastic constitutive modeling - ScienceDirect
Microelectromechanical system for in situ quantitative testing of tension–compression asymmetry in nanostructures - Nanoscale Horizons (RSC Publishing) DOI:10.1039/D3NH00407D
Characterization of the deformation behaviors under uniaxial stress for bicontinuous nanoporous amorphous alloys - Physical Chemistry Chemical Physics (RSC Publishing) DOI:10.1039/D1CP04970D
Microscopic mechanisms of pressure-induced amorphous-amorphous transitions and crystallisation in silicon
Tension–compression asymmetry in amorphous silicon
Microscopic mechanisms of pressure-induced amorphous-amorphous transitions and crystallisation in silicon
Tension–Compression Flow Asymmetry as a Function of Alloy Composition in the Al-Si System
Tension–Compression Flow Asymmetry as a Function of Alloy Composition in the Al-Si System
PDF) Significant “smaller is softer” in amorphous silicon via irradiation-mediated surface modification