Power law decay of local density of states oscillations near a line defect in a system with semi-Dirac points

TL;DR

This paper analyzes how the local density of states oscillations decay near a line defect in semi-Dirac systems, revealing anisotropic power-law behaviors that depend on defect orientation and energy, aiding in identifying semi-Dirac points.

Contribution

It provides analytical decay indexes for LDOS oscillations in semi-Dirac systems, highlighting anisotropic decay behaviors and their dependence on defect orientation and energy.

Findings

Decay index -5/4 when defect is perpendicular to linear dispersion

Decay index -1/4 in gapped systems along certain directions

Decay index -1/2 when defect is perpendicular to parabolic dispersion

Abstract

We theoretically study the power-law decay behavior of the local density of states (LDOS) oscillations near a line defect in system with semi-Dirac points by using a low-energy k.p Hamiltonian. We find that the LDOS oscillations are strongly anisotropic and sensitively depend on the orientation of the line defect. We analytically obtain the decay indexes of the LDOS oscillations near a line defect running along different directions by using the stationary phase approximation. Specifically, when the line defect is perpendicular to the linear dispersion direction, the decay index is -5/4 whereas it becomes -1/4 if the system is gapped, both of which are different from the decay index -3/2 in isotropic Dirac systems. In contrast, when the line defect is perpendicular to the parabolic dispersion direction, the decay index is always -1/2 regardless of whether the system is gapped or not, which is the same as that in a conventional semimetal. In general, when the defect runs along an arbitrary direction, the decay index sensitively depends on the incident energy for a certain orientation of the line defect. It varies from -5/4 to -1/2 due to the absence of strict stationary phase point. Our results indicate that the decay index -5/4 provides a fingerprint to identify semi-Dirac points in 2D electron systems.