Molecular dynamics simulation of primary irradiation damage in Ti-6Al-4V alloys

Displacement cascade behaviors of Ti-6Al-4V alloys are investigated using molecular dynamics (MD) simulation. The embedded atom method (EAM) potential including Ti, Al and V elements is modified by adding Ziegler-Biersack-Littmark (ZBL) potential to describe the short-range interaction among different atoms. The time evolution of displacement cascades at the atomic scale is quantitatively evaluated with the energy of primary knock-on atom (PKA) ranging from 0.5 keV to 15 keV, and that for pure Ti is also computed as a comparison. The effects of temperature and incident direction of PKA are studied in detail. The results show that the temperature reduces the number of surviving Frenkel pairs (FPs), and the incident direction of PKA shows little correlation with them. Furthermore, the increasing temperature promotes the point defects to form clusters but reduces the number of defects due to the accelerated recombination of vacancies and interstitial atoms at relatively high temperature. The cluster fractions of interstitials and vacancies both increase with the PKA energy, whereas the increase of interstitial cluster is slightly larger due to their higher mobility. Compared to pure Ti, the presence of Al and V is beneficial to the formation of interstitial clusters and indirectly hinders the production of vacancy clusters

Influence of grain boundary sliding near a nanovoid on crack growth in deformed nanocrystalline materials

A theoretical model is developed that examines the effect of grain boundary (GB) sliding near a nanovoid on crack growth in deformed nanocrystalline materials. By combining complex variable method of Muskhelishvili, superposition principle of elasticity and distributed dislocation technique, the singular integral equations are solved numerically and then the stress intensity factors (SIFs) near the left crack tip are obtained. The influences of the location of the disclination dipole, the dipole arm, the orientation and the relative crack length on the SIFs near the left crack tip are evaluated in detail. The results indicate that the wedge disclination dipole produced by the GB sliding shields mode I crack tip, but anti-shields mode II crack tip. At the same time, surface stresses of the nanovoid characterized by positive surface elasticity and negative surface elasticity both show shielding effect to mode I SIFs of the crack tip, yet have negligible effect on mode II SIFs of the crack tip. Meanwhile, the mode I crack tip is more significantly shielded by the negative residual surface stresses than that of the positive residual surface stresses

Basalt Fiber-Based Electrical Insulating Paper: Fabrication, Characterization, and Performance

Basalt fiber is a famous sound and thermal insulating material. In this study, a novel basalt fiber-based electrical insulating paper was successfully prepared, and its physical strength, dielectric properties, thermal stability, and glue permeability of the composite paper were systematically investigated. The results showed that the introduction of mica could make basalt fiber/mica composite paper (B-M paper). Meanwhile, the introduction of aramid fibrids into B-M paper could greatly increase the physical strength and dielectric performance (1–26 times). In addition, silicone adhesive bonding could further enhance physical strength and electrical properties, which were 1–45 times higher than those of pure composite paper. Thus, basalt fiber-based paper is a potential electrical insulating material