Borophosphene: A New Anisotropic Dirac Cone Monolayer with a High Fermi Velocity and a Unique Self-Doping Feature

Zhang, Yang; Kang, Jun; Zheng, Fan; Gao, Pengfei; Zhang, Shengli; Wang, Lin‐Wang

doi:10.1021/acs.jpclett.9b02599

Cited by 59 publications

(55 citation statements)

References 59 publications

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“…The calculated values of four constants C 11 , C 12 , C 22 , and C 44 are 311.1, 79.3, 306.6, and 34.5 N m À1 , which fulfill the requirements of mechanical stability for an orthorhombic 2D monolayer (C 11 > 0, C 22 > 0, C 44 > 0, and C 11 C 22 > C 2 12 ). [45] We can also obtain the in-plane Young's modulus and Poisson's ratio along an arbitrary direction θ (θ is the angle relative to the primitive vectorã in Figure 1a) by the following formula. [66] YðθÞ ¼…”

Section: Resultsmentioning

confidence: 99%

“…Besides hexagonal systems, the Dirac points can exist in 2D orthorhombic and tetragonal systems, including α-graphdiyne, [40] S-graphene, [41] palgraphyne, [10] and HOT graphene. [42] Further, azugraphene, [43] StoneÀWales graphene, [44] borophosphene, [45] cp-graphyne, [19] and circumcoro-graphyne [46] also exhibit linear band dispersion and associated Dirac points. However, most of the synthesized 2D carbon materials are protected by hexagonal symmetry.…”

Section: Introductionmentioning

confidence: 99%

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Dirac Semimetal Protected by Nonsymmorphic Mirror Symmetries in TPH‐Graphene

Liang

Wang

et al. 2021

Physica Rapid Research Ltrs

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Dirac cones in 2D carbon allotropes are generally protected by symmorphic symmetry operations. Herein, it is proposed that TPH-graphene has Dirac cones protected by nonsymmorphic mirror symmetries. This monolayer is composed of tetragonal, pentagonal, and heptagonal carbon rings and exhibits not only good mechanical and dynamic stability but also high energetic stability. The structure has anisotropic mechanical properties, and its Young's modulus is close to that of graphene, up to 291 N m À1 . The Dirac points on high-symmetry lines ΓÀX and XÀS are protected by the nonsymmorphic mirror operations fm 010 j0, 1=2, 0g and fm 100 j0, 1=2, 0g, respectively. The edge states obtained from semi-infinite structures confirm the nontrivial topological nature of these cones. The work reveals that TPH-graphene is an excellent candidate to study nonsymmorphicsymmetry-protected Dirac cones in 2D carbon materials.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dirac Semimetal Protected by Nonsymmorphic Mirror Symmetries in TPH‐Graphene

Liang

Wang

et al. 2021

Physica Rapid Research Ltrs

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“…Table 6 contains the cohesive energies and structural data of the groups of related monolayers BX, 131,[136][137][138][139][140][141][142] AlX, 131,142,143 GaX, 131,134,142,144,145 InX, 131,134,142,146,147 and TlX 131,148 with X = N, P, As, Sb, and Bi. As revealed in Fig.…”

Section: Group Iii-v Monolayersmentioning

confidence: 99%

Bonding, structure, and mechanical stability of 2D materials: the predictive power of the periodic table

Hess

2021

Nanoscale Horiz.

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“…Due to the periodic affinity sites and excellent surface electrochemical properties, boron-phosphide monolayers can be expected to use as anode materials for lithium-ion batteries and anchoring materials for lithium-ion batteries [14,15]. In addition, its isomer with orthorhombic symmetry was proposed using the genetic algorithm methods [16], which holds great promise in alkali metal ion battery [17,18]. Although the boron-phosphide monolayer has not been synthesized, many studies have shown its great potential in nanoelectronics.…”

Section: Introductionmentioning

confidence: 99%

Defects and Strain Engineering of Structural, Elastic, and Electronic Properties of Boron-Phosphide Monolayer: A Hybrid Density Functional Theory Study

Zhang

2021

Nanomaterials

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Defects and in-plane strain have significant effects on the electronic properties of two-dimensional nanostructures. However, due to the influence of substrate and environmental conditions, defects and strain are inevitable during the growth or processing. In this study, hybrid density functional theory was employed to systematically investigate the electronic properties of boron-phosphide monolayers tuned by the in-plane biaxial strain and defects. Four types of defects were considered: B-vacancy (B_v), P-vacancy (P_v), double vacancy (D_v), and Stone–Wales (S-W). Charge density difference and Bader charge analysis were performed to characterize the structural properties of defective monolayers. All of these defects could result in the boron-phosphide monolayer being much softer with anisotropic in-plane Young’s modulus, which is different from the isotropic modulus of the pure layer. The calculated electronic structures show that the P_v, D_v, and S-W defective monolayers are indirect band gap semiconductors, while the B_v defective system is metallic, which is different from the direct band gap of the pure boron-phosphide monolayer. In addition, the in-plane biaxial strain can monotonically tune the band gap of the boron-phosphide monolayer. The band gap increases with the increasing tension strain, while it decreases as the compression strain increases. Our results suggest that the defects and in-plane strain are effective for tuning the electronic properties of the boron-phosphide monolayer, which could motivate further studies to exploit the promising application in electronics and optoelectronics based on the boron-phosphide monolayer.

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Borophosphene: A New Anisotropic Dirac Cone Monolayer with a High Fermi Velocity and a Unique Self-Doping Feature

Cited by 59 publications

References 59 publications

Dirac Semimetal Protected by Nonsymmorphic Mirror Symmetries in TPH‐Graphene

Dirac Semimetal Protected by Nonsymmorphic Mirror Symmetries in TPH‐Graphene

Bonding, structure, and mechanical stability of 2D materials: the predictive power of the periodic table

Defects and Strain Engineering of Structural, Elastic, and Electronic Properties of Boron-Phosphide Monolayer: A Hybrid Density Functional Theory Study

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