Abstract
Using evolutionary algorithm for crystal structure prediction, we present a new stable two-dimensional (2D) carbon allotrope composed of polymerized as-indacenes (PAI) in a zigzag pattern, namely PAI-graphene whose energy is lower than most of the reported 2D allotropes of graphene. Crucially, the crystal structure realizes a nonsymmorphic layer group that enforces a nontrivial global topology of the band structure with two Dirac cones lying perfectly at the Fermi level. The absence of electron/hole pockets makes PAI-graphene a pristine crystalline topological semimetal having anisotropic Fermi velocities with a high value of 7.0×105 m/s. We show that while the semimetallic property of the allotrope is robust against the application of strain, the positions of the Dirac cone and the Fermi velocities can be modified significantly with strain. Moreover, by combining strain along both the x- and y-directions, two band inversions take place at Γ leading to the annihilation of the Dirac nodes demonstrating the possibility of strain-controlled conversion of a topological semimetal into a semiconductor. Finally we formulate the bulk-boundary correspondence of the topological nodal phase in the form of a generalized Zak-phase argument finding a perfect agreement with the topological edge states computed for different edge-terminations.
Highlights
Due to the rich diversity of hybridization forms of carbon atoms, many allotropes of carbon exist in zero-dimensional (0D) [1,2], onedimensional(1D) [3], two-dimensional (2D) [4,5], and threedimensional (3D) forms
Our evolutionary structure search has reproduced most of the reported 2D carbon allotropes with 2, 3, 4, 6, 8, 12, and 24 atoms/ unit cell
Compared to the previously reported four most stable 2D carbon allotropes, polymerized as-indacenes (PAI)-graphene is as stable as SW-graphene (À9.085 eV/atom) [31], and more favorable than phagraphene (À9.027 eV/atom) [28], Octite M1 (À9.029 eV/atom) [64], and jgraphene (À9.069 eV/atom), which were found in our structure search
Summary
Due to the rich diversity of hybridization forms of carbon atoms, many allotropes of carbon exist in zero-dimensional (0D) [1,2], onedimensional(1D) [3], two-dimensional (2D) [4,5], and threedimensional (3D) forms. Some unusual properties have been predicted for these materials, such as negative Poisson’s ratio [22,33], semimetallic properties [21,28,31], and high Li storage capacity [30] Most of these allotropes are composed of sp and sp hybridized atoms and have lower energy than experimentally synthesized graphynes and are likely to be synthesized in the future. We have performed a systematic crystal structure search using the evolutionary algorithm based code USPEX [39,45,48,49,53,54] for 2D carbon allotropes and found a new 2D carbon allotrope, PAI-graphene The energy of this allotrope is comparable to graphene and lower than most of the predicted 2D carbon allotropes. We formulate the bulk-boundary correspondence of the topological nodal phase in the form of generalized Zak-phase argument and show the stability of the topological edge states under variations of the edge termination
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