Catalogue of topological electrons and phonons in all allotropes of carbon

TL;DR

This study systematically explores all allotropes of carbon, identifying numerous topological electronic and phononic materials, revealing diverse topological features and providing platforms for future topological studies.

Contribution

It is the first comprehensive survey of topological electrons and phonons across all carbon allotropes, discovering hundreds of ideal topological materials and their unique features.

Findings

Identified 315 topological phononic materials and 32 electronic topological materials.

Discovered coexistence of Weyl phonons and nodal surfaces in specific allotropes.

Found clear surface states associated with topological features in selected structures.

Abstract

Carbon, as one of the most common element in the earth, constructs hundreds of allotropic phases to present rich physical nature. In this work, by combining the ab inito calculations and symmetry analyses method, we systematically study a large number of allotropes of carbon (703), and discovered 315 ideal topological phononic materials and 32 topological electronic materials. The ideal topological phononic nature includes single, charge-two, three, four Weyl honons, the Dirac or Weyl nodal lines phonons, and nodal surfaces phonons. And the topological electron nature ncludes topological insulator, (Type-II) Dirac points, triple nodal points, the Dirac (Weyl) nodal lines, quadratic nodal lines and so on. For convenience, we take the uni in SG 178 and pbg in SG 230 as the examples to describe the topological features in the main. We find that it is the coexistence of single pair Weyl phonons and one-nodal surfaces phonons in the uni in SG 178, which can form the single surface arc in the (100) surface BZ and isolated double-helix surface states (IDHSSs)in the (110) surface BZ. In topological semimetal pbg in SG 230, we find that the perfect triple degenerate nodal point can be found in the near Fermi level, and it can form the clear surface states in the (001) and (110) surface BZ. Our work not only greatly expands the topological features in all allotropes of carbon, but also provide many ideal platforms to study the topological electrons and phonons.