Scattering of plasmons at the intersection of two metallic nanotubes: Implications for tunnelling

Abstract

We study theoretically the plasmon scattering at the intersection of two metallic carbon nanotubes. We demonstrate that for a small angle of crossing, θ 1, the transmission coefficient is an oscillatory function of λ/θ, where λ is the interaction parameter of the Luttinger liquid in an individual nanotube. We calculate the tunnel density of states, (ω,x), as a function of energy, ω, and distance, x, from the intersection. In contrast to a single nanotube, we find that, in the geometry of crossed nanotubes, conventional "rapid" oscillations in (ω,x) due to the plasmon scattering acquire an aperiodic "slow-breathing" envelope which has λ/θ nodes.