Unveiling the influence of various vacancies on the mechanical properties of Ti4C3O2

Abstract

Two-dimensional transition metal carbides and nitrides are widely recognized as potential candidates in areas such as energy storage and sensors. In this work, we explore the mechanical properties of Ti4C3O2 with a perfect cell and Ti4C3O2 with vacancies by a first-principles method. The results indicate that the loss of C in the outer layer of Ti4C3O2 is more likely to occur due to the smaller formation energy of C-vacancy. By considering the charge contribution, the removed atom changes the valence electron equilibrium concentration between that atom and its neighbors, which in turn affects the mechanical properties of Ti4C3O2. The presence of various vacancies affects the strength of the TiO bonds on the shear plane, causing Ti4C3O2 to exhibit changes towards brittleness or ductility. It is noteworthy that the elastic modulus, critical strain, and ideal stress of Ti4C3O2 with different concentrations of O vacancies are all approximately the same, suggesting that the variations in their mechanical properties are not significant for Ti4C3O2 with different degrees of O functional group coverage. Our findings offer valuable insights for the development of MXene-based nanoflexible energy storage devices, gas-sensitive sensors, high-temperature environmental applications, and beyond.