Evolution from topological nodal points to nodal line: realized in fused carbon allotrope

In the present investigation, via first‐principle calculations and theoretical analysis, we systematically investigated a new Dirac semimetal carbon system called C32, which is composed of pentagonal, hexagonal, heptagonal, and octagonal carbon rings. We verified the stability of C32 by calculating the phonon dispersion, elastic constants, etc., and proposed an appropriate pathway for experimental synthesis. Besides, it is discovered that the system holds the quadruple rotation and inversion symmetry, resulting in the emergence of eight twisted Dirac cones (D 1 and D 2 ) with a highly anisotropic Fermi velocity from 3.83×10 5 to 8.96×10 5 m/s along different k directions. To substantiate the semimetallic nature of C32, we confirm its non‐trivial topological properties through the presence of topologically protected edge states and the nonzero ℤ 2 topological invariant. More importantly, by introducing biaxial strain, we uncovered that Dirac cones can gradually evolve into a nodal line, and the perfect nodal line can be obtained when the biaxial strain is 13.3%. Furthermore, by constructing the tight‐binding model, we perfectly repeated the appearance of the Dirac cone and explained its evolution into the nodal line under biaxial strain. This article is protected by copyright. All rights reserved.