Ideal Weyl fermions and double Kagome bands in a series of distorted armchair-type all-sp2 carbon networks

Abstract

The study of the Weyl fermions and Kagome bands has recently attracted significant attention in condensed matter physics. However, realizing of perfect Weyl semimetals and double Kagome bands remains challenging. Here, we report a new class of distorted armchair-type fully sp2-hybridized carbon networks, termed DACN-n. The DACN-n family is characterized by only six pairs of Weyl points on the kz=0 plane near the Fermi level. We calculated the chirality of these Weyl points and found that each carries a topological charge of 1. Notably, DACN-5 exhibits a double Kagome band, where the Weyl points arise from the intersection between Dirac-type bands in the two sets of Kagome bands. The structural stability of DACN-n is confirmed by phonon spectra, ab initio molecular dynamics simulations, and elastic constant calculations. Additionally, we investigated the surface states of the (001) surface and found that its nontrivial topological properties are attributed to the Fermi arcs connecting a pair of Weyl points with opposite chirality. We also simulated x-ray diffraction patterns to guide experimental synthesis. Our findings not only present a new family of three-dimensional carbon allotropes, but also provide a unique opportunity for exploring ideal Weyl fermions and double Kagome bands.

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