Klein tunneling in deformed $\alpha-T_3$ lattice

By applying a compressive uniaxial deformation on the $\alpha-T_3$ lattice, which interpolates between honeycomb lattice ($\alpha=0$) and dice lattice ($\alpha=1$), the Dirac cones move toward each other along a given direction, merge and a gap opens while the flat band remains unchanged. Therefore, the low-energy spectrum, along this merging direction, exhibits a transition from a linear dispersion in the Dirac phase to a quadratic dispersion in the gapped phase. However, along the perpendicular direction the spectrum remains linear. Here we theoretically study the tunneling properties of particles through a $\mathit{np}$ junction in deformed $\alpha-T_3$ lattice. In the Dirac phase, we find that the tunneling properties are similar to those of undeformed $\alpha-T_3$ lattice such as the perfect Klein tunneling at normal incidence for all values of $\alpha$ and the total transparency of the junction, i.e. the super-Klein tunneling, for $\alpha=1$ when the energy is equal to half of the junction height. In the gapped phase, we obtain an opposite behavior when the junction is oriented perpendicular to the deformation direction where the perfect Klein tunneling turns into the anti-Klein tunneling effect for all parameters $\alpha$ and the super-Klein tunneling effect transits to the anti-super Klein tunneling effect, i.e. the junction is totally opaque.