Tensile behaviors of Ti3C2Tx (MXene) films

As the most representative member of a new emerging family of 2D material, titanium carbides or nitrides (MXenes), Ti3C2Tx and its 2D assembly format, Ti3C2Tx film, have displayed outstanding performance in a broad range of practical applications. However the mechanical behavior of Ti3C2Tx films are rarely reported. We report a systematic study of the tensile behavior of Ti3C2Tx films. Ti3C2Tx films with various thicknesses (2-17 µm) were prepared by vacuum filtration method. Quasi-static tension and cyclic tension tests were performed to investigate deformation and fracture mechanism of Ti3C2Tx films. It is found that: (1) the relative sliding between Ti3C2Tx flakes is the dominant deformation mechanism of Ti3C2Tx films. Cyclic loading-releasing in tension suppresses the inter-layer sliding of Ti3C2Tx flakes effectively and thus the tensile strength of thicker Ti3C2Tx film (5 µm) film is improved from 57 MPa to 67 MPa. (2) The mechanical properties of Ti3C2Tx films are found to be thickness dependent. With the film thickness increases from 2.3 µm to 17 µm, tensile strength and elastic modulus drop from 61 MPa to 36 MPa, and from 17 GPa to 8 GPa, respectively. This is interpreted as more structural defects presented in the through-the-thickness direction as film thickness is increased. (3) Moderate ultrasonication pretreatment (30 min) reduces the Ti3C2Tx flake size significantly while improves the compactness of the Ti3C2Tx film; and the resulting Ti3C2Tx film shows linear stress-strain relationship without plastic-like deformation. As a result, the tensile strength of 5 µm-thick Ti3C2Tx film is enhanced to 85 MPa; (4) Structural defects of the Ti3C2Tx film have significant effects on both the brittle-like fracture behavior and the distribution of tensile strength.