Startseite Three-dimensional metallic carbon allotropes with superhardness
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Three-dimensional metallic carbon allotropes with superhardness

  • Qingyang Fan EMAIL logo , Heng Liu , Li Jiang , Wei Zhang , Yanxing Song , Qun Wei EMAIL logo , Xinhai Yu und Sining Yun EMAIL logo
Veröffentlicht/Copyright: 23. September 2021
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Nanotechnology Reviews
Aus der Zeitschrift Nanotechnology Reviews Band 10 Heft 1

Abstract

Three novel three-dimensional orthorhombic carbon phases are proposed based on first-principles calculations in this work. These phases possess dynamic stability and mechanical stability and are theoretically more favorable in energy compared to most other carbon allotropes. The hardness levels of oP-C16, oP-C20, and oP-C24 are 47.5, 49.6, and 55.3 GPa, respectively, which are greater than those of T10, T18, and O12 carbon. In addition, although oP-C16, oP-C20, and oP-C24 are metals, their ideal shear strengths are also greater than those of common metals such as Cu, Fe, and Al. Due to p y electrons crossing the Fermi level, oP-C16, oP-C20, and oP-C24 show metallicity, and their charge densities of the band decomposition suggest that all the conductive directions of oP-C16, oP-C20, and oP-C24 are exhibited along the a- and b-axis, similar to C5.

Graphical abstract

The crystal structures of oP-C16, oP-C20, and oP-C24.

Keywords: metallic carbon; superhard material; electronic properties; conductive directions

1 Introduction

The rapid growth of computer performance and the abundance of various experimental data have led to the intensified exploration of new energy materials [1] and novel electronic information materials. The use of computers for scientific calculations is already the third scientific method for mankind to understand and conquer nature after theoretical science and experimental science. Due to the extensive role and important influence of metal superhard carbon materials in the fields of industry, machinery, and aerospace, there is an urgent need for metal superhard carbon materials with excellent mechanical and electronic properties. However, despite theoretical predictions that carbon allotropes emerge in an endless stream, there are not many carbon materials that simultaneously exhibit metallic and superhard properties and enjoy favorable physical properties. Obviously, there is still a long way to go in designing and discovering breakthrough carbon materials with remarkable features. In this work, three superhard metal carbon materials are theoretically predicted and the results obtained show that these three carbon phases all have superhard metal characteristics and many advantageous properties, which are of great significance for enriching the gene pool of excellent materials and providing a solid theoretical basis for future experiments. More importantly, owing to their metallic and superhard properties, oP-C16, oP-C20, and oP-C24 may possess the opportunity to play applications in industrial and electronic fields.

In recent years, a considerable number of carbon allotropes and carbon-based materials have been identified. For instance, five carbon allotropes, tP12, tP16, tP24, oP12, and oP18, with nanotubes and cage types were proposed recently [2]. There are two-dimensional (2D) TPH-I carbon and TPH-II carbon obtained from pentagraphene through Stone-Wales conversion [3]. The electronic and mechanical properties of the new superhard indirect semiconductor oP8 carbon have also been predicted [4]. Li and Xing designed a superhard semiconductor material, P2/m C 54, which is a new type of semiconductor material that can be applied to frequency-hopping absorption filters [5]. TiO2/graphite carbon nanocomposite materials, which can improve photocatalytic efficiency, are synthesized under certain temperatures and conditions [6]. In light of the synthesis of graphene with benzene as the precursor, a novel all-sp 2 hybridized 2D carbon allotrope with poly-butadiene–cyclooctatetraene framework is proposed [7]. By means of molecular dynamics simulation, the interface characteristics of carbon nanotube–polyimide nanocomposites have been systematically analyzed [8].

In particular, metallic carbon has attracted much attention due to its usefulness in electronic devices, superconductivity applications, and high-performance anode materials. By cross-linking graphene sheet with sp 3-hybridized carbon chains, Wang et al. established a new type of porous asymmetric carbon honeycomb (CHC), namely bco-C24 [9]. Using the self-assembled C8 skeleton of pentene as a building block, a series of 3D carbon allotropes (superpentalene-n family) were constructed [10]. A new type of orthogonal metal carbon phase o-C12 with high stability and hardness has been proposed, which is expected to be applied to actual electronic and mechanical equipment [11]. Zhang et al. proposed a metal superhard carbon allotrope C10, which has an sp 2 + sp 3 hybrid carbon network in the orthorhombic unit cell and has a hardness of 58.70 GPa [12]. Liu et al. proposed two carbon polymorphs Orth-C10 and Orth-C10’ with excellent superhard and conductive properties through first-principles calculations, which are more energetically stable than fullerene C60 at 0 GPa [13]. There are also paper carbon nanotubes that can replace aluminum foil as a current collector [14].

Recently, Wu et al. [15] reported a novel three-dimensional orthorhombic phase utilizing first-principles calculations. The novel three-dimensional orthorhombic phase, namely, C14-diamond, which was assembled with nanolayered sp 3 carbon in a diamond structure, was bonded with ethene-type –C═C– links and so C14-diamond is a superhard material and metallic carbon allotrope. In addition, the conductive direction of C14-diamond is also exhibited along these sp 2 carbon atoms. Additionally, Liu et al. [16] designed O-type and T-type carbon allotropes. The diamond nanostripes in O-type and T-type carbon allotropes are similar to C14-diamond and are also bonded with ethene-type –C═C– links. All the O-type and T-type carbon allotropes exhibited metallic properties, and the bulk modulus (B) and shear modulus (E) of O-type and T-type carbon allotropes exceeded 357 and 223 GPa, respectively.

In recent years, the focus of development has been to predict the properties of new materials and to design novel structures or some details in the new phases with function-oriented reverse design. However, compared with the huge demand in various fields such as modern industry, manufacturing, and aviation, carbon materials that are harder, more conductive, and lighter are still waiting for scientists to explore.

From ancient times to the present, carbon materials have been playing an increasingly important role in industrial applications, from initial heating materials to electronic materials and other functional materials. For example, supercapacitors based on carbon materials [17] have the same excellent characteristics as all-paper-based supercapacitor devices [18], such as fast charge and discharge speed, high power density, and long-term cycle stability. Complementary carbon nanotube transistors can even be used to build modern microprocessors [19]. Carbon nanomaterial-reinforced cement-based composites, which are stronger than traditional cement materials, smarter, and more durable, are also attracting attention [20]. Novel carbon materials and composite carbon materials [21] with excellent performance are closely related to modern engineering. The material gene bank is equivalent to the guiding light for the synthesis of new materials, so the theoretical importance of the exploration of new carbon structure is self-evident.

In this work, the three novel superhard metallic carbon allotropes (according to the number of carbon atoms in the conventional cell, denoted oP-C16, oP-C20, and oP-C24 below) are proposed in this work and these novel metallic carbon allotropes from the space group and graph theory (RG2) code [22]. The crystal structures of oP-C16, oP-C20, and oP-C24 are similar to C14-diamond, O-type, and T-type carbon allotropes. The process is shown in graphical abstract. It can be seen that the structures of these three carbon allotropes are related and similar, and they are all composed of six-membered rings and ten-membered rings. From the ab plane, the structure of oP-C16 is exactly identical to that of oP-C20. The difference exists in bc and ac planes, as shown in the red wireframe in graphical abstract, that is the structure of oP-C20 possesses one more six-membered ring than that of oP-C16. Interestingly, the addition of a six-membered ring to the structure of oP-C20 along the bc and ac planes converts it to the structure of oP-C24. The hardness level of oP-C24 is higher than those of C14-diamond, O12 carbon, O20 carbon, T10 carbon, T18 carbon, and T26 carbon. Additionally, the conductive directions of oP-C16, oP-C20, and oP-C24 are also investigated in this work.

2 Computational method

The crystal structures of oP-C16, oP-C20, and oP-C24 are obtained from the random sampling strategy combining space group and graph theory (RG2) [22]. For geometry optimization, ultrasoft pseudopotentials [23] are adopted in the interactions of the core electrons, and norm-conserving pseudopotentials [24] are employed for electronic band structure calculations. A generalized gradient approximation (GGA) proposed by Perdew et al. [25] and local density approximations (LDA), as developed by Ceperley and Alder and parameterized by Perdew and Zunger (CA-PZ) [26,27], is performed by utilizing the Cambridge Serial Total Energy Package [28] by means of density functional theory [29,30] calculations. The Broyden–Fletcher–Goldfarb–Shenno (BFGS) [31] minimization technique is used for geometry optimization. A plane wave basis set with an energy cut-off of 400 eV is used for oP-C16, oP-C20, and oP-C24. A high-accuracy grid spacing of lower than 2π × 0.025/Å is selected utilizing the Monkhorst–Pack scheme [32] (for oP-C16: 16 × 15 × 3, oP-C20: 16 × 16 × 2, and oP-C20: 16 × 16 × 2).

For other carbon materials (C14-diamond [15], T10 carbon, T18 carbon, T26 carbon, O12 carbon, O20 carbon, O26 carbon [16], and C14 carbon [33]) for comparison, the cutoff energy of 400 eV is also used, and the k-points of the other carbon materials (T10 carbon: 16 × 16 × 4, T18 carbon: 16 × 16 × 2, T26 carbon: 16 × 16 × 2, O12 carbon: 4 × 16 × 15, O20 carbon: 2 × 16 × 16, O26 carbon: 2 × 16 × 16, C14-diamond: 2 × 16 × 16, and C14 carbon: 16 × 4 × 11) are also used for the high-accuracy grid spacing of lower than 2π × 0.025/Å. The Heyd–Scuseria–Ernzerhof (HSE06) hybrid functional [34] is adopted to estimate the electronic properties of oP-C16, oP-C20, and oP-C24. The density functional perturbation theory [35] is employed to investigate the phonon spectra for oP-C16, oP-C20, and oP-C24. First-principles calculations are favored by many researchers in the fields of condensed matter physics and computational materials science. Regarding the study of the physical properties of metallic carbon, some references [13,15,16,33] use first-principles calculations. Thus, in this work, first-principles calculations are adopted to study the physical properties of the three proposed carbon allotropes.

3 Results and discussion

The designed constructions of oP-C16, oP-C20, and oP-C24, and their crystal structures are shown in graphical abstract. There are four sp 2 hybridization carbon atoms in all three structures, that is, there are two –C═C– bonds in the oP-C16, oP-C20, and oP-C24 crystal structures. The oP-C16, oP-C20, and oP-C24 carbon phases are established by the sp 2 + sp 3 hybrid bonding network in a three-dimensional formation. These three structures also contain different numbers of inequivalent atomic positions. oP-C16 has eight different inequivalent atomic positions, oP-C20 has ten different inequivalent atomic positions, and oP-C24 has twelve different inequivalent atomic positions. The optimal lattice parameters of oP-C16, oP-C20, and oP-C24 are presented in Table 1. Furthermore, the theoretical and experimental values of the lattice parameters for diamond are displayed in Table 1 for comparison. The estimated results obtained by using the GGA method are closer to the experimental values than those obtained by using LDA. Thus, all theoretical calculations in our article are performed at the GGA level.

Table 1

Obtained lattice constants (Å), cell volume/atom V3), and density (g/cm3) for oP-C16, oP-C20, oP-C24, c-BN, and diamond

Materials Method a b c V ρ
oP-C16 GGA 2.515 2.597 14.901 6.085 3.278
LDA 2.488 2.563 14.742 5.877 3.394
oP-C20 GGA 2.517 2.580 18.464 5.994 3.327
LDA 2.489 2.547 18.265 5.791 3.444
oP-C24 GGA 2.518 2.569 22.028 5.936 3.360
LDA 2.490 2.537 21.789 5.736 3.477
c-BN GGA 3.623 5.945 3.466
LDA 3.577 5.721 3.602
Exp.a 3.620 5.930 3.475
Diamond GGA 3.566 5.668 3.519
LDA 3.527 5.484 3.637
Exp.b 3.567 5.673 3.516

aRef. [41]; bRef. [46].

The dynamic stability for oP-C16, oP-C20, and oP-C24 can be checked using phonon spectra. The phonon spectra of oP-C16, oP-C20, and oP-C24 are shown in Figure 1(a–c). As described in ref. [15], the phonon modes greater than 40 THz chiefly originate from the vibration of sp 2 hybridization connected with the –C═C– bond, and the vibration frequency of sp 3 hybridization carbon atoms is mainly below 40 THz. In addition, most importantly, no hypothetical frequency is found in the whole Brillouin zone, demonstrating that the three predicted carbon allotropes are dynamically stable. Figure 1(d) shows the enthalpy per atom of oP-C16, oP-C20, and oP-C24, including C14-diamond [15], T26 carbon, T10 carbon, T18 carbon, O18 carbon, O12 carbon, and O20 carbon [16] in the sp 2 + sp 3 bonding network and C14 carbon [33] in all sp 3 bonding networks compared with other carbon phases reported theoretically. As shown in Figure 1(d), oP-C24 is more stable than T10 carbon, T18 carbon, O12 carbon, O20 carbon, and C14 carbon in thermodynamics; oP-C20 is thermodynamically more stable than those of T10, O12, O20, and C14 carbon; and oP-C16 is thermodynamically more stable than those of T10 carbon and O12 carbon.

Figure 1 Phonon spectra of oP-C16 (a), oP-C20 (b), and oP-C24 (c), and the related enthalpies of other metallic carbon allotropes (d).
Figure 1

Phonon spectra of oP-C16 (a), oP-C20 (b), and oP-C24 (c), and the related enthalpies of other metallic carbon allotropes (d).

For the structure of a stable orthorhombic crystal system, the elastic constants C ij should meet the mechanical elasticity criteria [36]: C 11 > 0, C 11 C 22 > C 12 2 , C 11 C 22 C 33 + 2C 12 C 13 C 23C 11 C 23 2 C 22 C 13 2 C 33 C 12 2 > 0. Table 2 shows the estimated elastic parameters for oP-C16, oP-C20, and oP-C24. All the acquired elastic parameters for oP-C16, oP-C20, and oP-C24 obey the above mechanical stability criteria. The C 22 values of oP-C16, oP-C20, and oP-C24 are slightly lower than those of diamond, C14-diamond and C14 carbon, while they are higher than that of c-BN. Furthermore, the C 11 and C 33 of oP-C16, oP-C20, and oP-C24 are slightly higher than those of C14-diamond, C14 carbon, c-BN, and diamond. Nevertheless, the higher values of C 11 and C 33 indicate the greater horizontal and vertical linear compression resistance of the crystal [15]. The values of B and G are estimated by adopting Voigt-Reuss-Hill approximations according to the obtained elastic constants, and Young’s modulus is estimated by E = 9BG/(3B + G) based on the B and G values. The B V, B R, G V and G R are calculated as follows [37]: B V = (1/9)[C 11 + C 22 + C 33 + 2(C 12 + C 13 + C 23)], G V = (1/15) [C 11 + C 22 + C 33 + 3(C 44 + C 55 + C 66)(C 12 + C 13 + C 23)], B R = Δ[C 11(C 22 + C 33-2C 23) + C 22(C 33 − 2C 13) − 2C 33 C 12 + C 12(2C 23C 12) + C 13(2C 12C 13) + C 23(2C 13C 23)]−1, G R = 15{4[C 11(C 22 + C 33 + C 23) + C 22(C 33 + C 13) + C 33 C 12C 12(C 23 + C 12)C 13(C 12 + C 13)C 23(C 13 + C 23)]/A + 3[(1/C 44) + (1/C 55) + 1/C 66]}−1, A = C 13(C 12 C 23C 13 C 22) + C 23(C 12 C 13C 23 C 11) + C 33(C 11 C 22C 2 12). Although the B, G and E values for oP-C16, oP-C20, and oP-C24 are slightly lower than those of C14-diamond, C14 carbon, and diamond, they are higher than those of O12 carbon and T10 carbon, while the bulk moduli of oP-C16, oP-C20, and oP-C24 are greater than that of c-BN.

Table 2

The elastic constants (GPa), elastic modulus (GPa), and hardness (GPa) of metallic carbon allotropes, c-BN, and diamond

Materials Method C 11 C 22 C 33 C 44 C 55 C 66 C 12 C 13 C 23 B G E H Chen H M-O H L-O
oP-C16 GGA 1,138 848 1,092 132 540 269 19 136 62 385 333 775 47.5 52.5 71.8
LDA 1,206 912 1,151 103 568 273 20 156 76 414 325 773 41.4
oP-C20 GGA 1,141 908 1,087 136 545 307 20 131 73 395 347 805 49.6 55.6 69.3
LDA 1,210 974 1,140 113 574 312 21 152 88 424 343 810 44.5
oP-C24 GGA 1,143 948 1,083 170 548 332 21 130 80 402 372 853 55.3 63.2 66.7
LDA 1,212 1,014 1,139 155 578 339 22 150 96 431 377 876 52.0
Diamond GGA 1,053 563 120 431 522 1,116 94.3
LDA 1,104 598 140 461 549 1,179 95.3
Exp.a 1,076 577 125 442

aRef. [47].

Using Chen’s model [38] to estimate hardness, the related results of their carbon materials within the GGA level are also shown in Table 2. From Table 2, the hardness values of oP-C16, oP-C20, and oP-C24 are estimated to be 47.5, 49.6, and 55.3 GPa, respectively. The hardness value of C14-diamond determined in the same way is 53.1 GPa, which is close to the previously reported hardness value (55.8 GPa [15]). In this work, the hardness values of oP-C16, oP-C20, and oP-C24 are greater than those of O12 carbon (39.9 GPa), T10 carbon (25.6 GPa), T18 carbon (34.8 GPa), and T26 carbon (43.8 GPa). Furthermore, the hardness value of oP-C20 is also higher than that of O20 carbon (48.8 GPa), and the hardness value of oP-C24 is also higher than those of C14-diamond and O28 carbon (54.3 GPa). In order to verify the superhardness of the three proposed carbon allotropes, H M-O [39] and H L-O model [40] are employed. Here, H M-O can be obtained based on Poisson’s ratio and Young’s modulus using the following equation [39]: H M-O = 0.096 E (1–8.5v + 19.5v 2)(1–7.5v + 12.2v 2 + 19.6v 3)−1. The calculated hardness levels of oP-C16, oP-C20, and oP-C24 are 52–64 and 66–72 GPa, respectively, which are all greater than 40 GPa. All these three methods prove the fact that oP-C16, oP-C20, and oP-C24 have superhard characteristics.

To have a better understanding of the potential application of these carbons structures with superhard and metal properties, the stress–strain curves of the three carbon phases proposed by us under the tensile and shear strains in the low-index directions are calculated. The shear strength and tensile strength of oP-C16, oP-C20, and oP-C24 as functions of shear strain and tensile strain within the GGA functional are plotted in Figure 2. The turning point on the stress–strain curve indicates the ideal tensile strength or the ideal shear strength. The ideal shear strengths along the different shear directions of oP-C16/oP-C20/oP-C24 are listed in Table 3. For oP-C16/oP-C20/oP-C24, the peak shear stresses are 12.0/12.5/11.5, 12.2/12.6/11.6, 16.6/17.2/16.2, 17.0/17.9/16.1, and 17.5/18.1/16.2 GPa along the (010)[001], (010)[101], (110)[001], (110)[1–11], and (111)[1–10] directions, respectively. The possible cause is also the fracture of sp 2 –C═C– bonds, similar to C14-diamond, O12 carbon, O20 carbon, O28 carbon, T10 carbon, T18 carbon, and T26 carbon. As discussed in Reference [16], although the three proposed carbon allotropes in this work are metals, their ideal shear strengths are also greater than those of common metals such as Cu (4.0 GPa) [41], Al (3.4 GPa) [41], and Fe (6.40 GPa) [42]. In addition, the three kinds of carbon allotropes proposed by us can only break when the shear strain along these directions is above 0.07, while T18 carbon and T26 carbon break when the shear strain is 0.06 and 0.04, respectively. The minimum peak shear stresses along the (001)[100], (010)[100], (100)[010], (110)[1–10], and (111) [1–12] directions of oP-C16/oP-C20/oP-C24 are 94.4 GPa, which is slightly larger than that of O28 carbon along the (100)[010] direction.

Figure 2 Calculated stress vs shear strain and the stress versus tensile strain for oP-C16 (a and b), oP-C20 (c and d), and oP-C24 (e and f) in principal symmetry directions.
Figure 2

Calculated stress vs shear strain and the stress versus tensile strain for oP-C16 (a and b), oP-C20 (c and d), and oP-C24 (e and f) in principal symmetry directions.

Table 3

Obtained ideal shear strengths for oP-C16, oP-C20, and oP-C24 with the corresponding strains that produce the maximum stress (GPa)

(001)[100] (010)[001] (010)[100] (010)[101] (100)[010]
Strain Stress Strain Stress Strain Stress Strain Stress Strain Stress
oP-C16 0.2431 99.2 0.1128 12.0 0.5537 100.2 0.1128 12.2 0.5537 100.2
oP-C20 0.2319 96.6 0.0918 12.5 0.5410 105.9 0.0918 12.6 0.5537 105.9
oP-C24 0.2319 94.4 0.0814 11.5 0.5537 109.4 0.0814 11.6 0.5537 109.4
(110)[001] (110)[1–10] (110)[1–11] (111)[1–10] (111)[1–12]
Strain Stress Strain Stress Strain Stress Strain Stress Strain Stress
oP-C16 0.0918 16.6 0.4538 130.3 0.0918 17.0 0.0918 17.5 0.3815 114.4
oP-C20 0.0814 17.2 0.4294 129.3 0.0814 17.9 0.0814 18.1 0.3696 115.8
oP-C24 0.0711 16.2 0.4053 128.5 0.0711 16.1 0.0711 16.2 0.3578 116.5

The tensile strengths of oP-C16, oP-C20, and oP-C24 as functions of tensile strain within the GGA functional are displayed in Figure 2(b), (d), and (e), respectively. The ideal tensile strengths along the different tensile directions of oP-C16/oP-C20/oP-C24 are presented in Table 4. From Figure 2(b), (d), and (e), it can be seen that the tensile stress–strain curve of oP-C16/oP-C20/oP-C24 shows a plastic deformation relationship along the [010] and [100] directions, a relationship similar to that of O20 carbon. For the [001], [100], [110], and [111] directions, the ideal tensile strength is basically greater than 100 GPa, and the maximum is 157.9 GPa, which is the [110] direction of oP-C24. Although for the [010] direction, the ideal tension strengths of oP-C16, oP-C20, and oP-C24 are the worst, reaching 75.9, 83.4, and 88.6 GPa, respectively. For the [111] direction, the ideal tensile strengths of oP-C16, oP-C20, and oP-C24 are 99.8, 109.8, and 126.2 GPa, respectively. The smallest ideal tension strength of the three carbon materials along the [111] direction is nearly 18 GPa greater than that of diamond, 30 GPa greater than that of O28 carbon, and 60 GPa larger than that of T10 carbon. The high values of B modulus, hardness, and ideal strength provide these new materials broad application prospects in wear-resistant metal coatings and cutting tools.

Table 4

Calculated ideal tensile strengths for oP-C16, oP-C20, oP-C24 with the corresponding strains that produce the maximum stress (GPa)

[001] [010] [100] [110] [111]
Strain Stress Strain Stress Strain Stress Strain Stress Strain Stress
oP-C16 0.1843 134.2 0.2202 75.9 0.2572 116.6 0.2824 134.4 0.1268 99.8
oP-C20 0.1726 131.4 0.2202 83.4 0.2447 116.3 0.2821 148.1 0.1381 109.8
oP-C24 0.1726 132.7 0.2324 88.6 0.2447 116.1 0.2953 157.9 0.1726 126.2

To analyze the electronic band structures of oP-C16, oP-C20, and oP-C24, the projected weights of each kind of orbital of oP-C16, oP-C20, and oP-C24 using the Heyd–Scuseria–Ernzerhof (HSE06) hybrid functional are plotted in Figure 3. By showing the weights of the electrons in different orbits, it is found that the conduction band minimum between the S and X points and the valence band maximum at the Γ point both cross the Fermi surface. Similar to T10 carbon, T18 carbon, T26 carbon, O12 carbon, O20 carbon, O20 carbon, and C14-diamond, oP-C16, oP-C20, and oP-C24 all have metallic properties. In addition, the Fermi level is chiefly provided by the p y electrons. In the Brillouin zone, the coordinates for oP-C16, oP-C20, and oP-C24 are taken Γ (0.0, 0.0, 0.0), Z (0.0, 0.0, 0.5), T (−0.5, 0.0, 0.5), Y (−0.5, 0.0, 0.0), S (−0.5, 0.5, 0.0), X (0.0, 0.5, 0.0), U (0.0, 0.5, 0.5), and R (−0.5, 0.5, 0.5) of the high symmetry points. To visualize the chemical bonding in oP-C16, oP-C20, and oP-C24, the electron localization function (ELF) [43,44] using an isosurface value of 0.75 is demonstrated in Figure 4(a–c). The calculated ELF of oP-C16, oP-C20, and oP-C24 further indicates the strong covalent C–C bonding feature; at the same time, it can be clearly seen that the σ bond is formed by the sp 2 hybrid carbon atom. To further analyze in which direction the three metal carbon materials conduct electricity, the charge density of the band decomposition observed along the a-axis and b-axis of oP-C16, oP-C20, and oP-C24 are shown in Figure 5(a–f), which suggests that the conductive directions of oP-C16, oP-C20, and oP-C24 are all exhibited along the a- and b-axis.

Figure 3 Band structures of oP-C16 (a), oP-C20 (b), and oP-C24 (c).
Figure 3

Band structures of oP-C16 (a), oP-C20 (b), and oP-C24 (c).

Figure 4 The electron localization function (ELF) of oP-C16 (a), oP-C20 (b), and oP-C24 (c) with an isosurface level set to 0.75.
Figure 4

The electron localization function (ELF) of oP-C16 (a), oP-C20 (b), and oP-C24 (c) with an isosurface level set to 0.75.

Figure 5 The calculated band decomposed charge density in the energy range of E F – 1 ∼ E F + 1 eV for oP-C16 (a and b), oP-C20 (c and d), and oP-C24 (e and f) along the a and b axes with an isovalue level set to 0.005.
Figure 5

The calculated band decomposed charge density in the energy range of E F – 1 ∼ E F + 1 eV for oP-C16 (a and b), oP-C20 (c and d), and oP-C24 (e and f) along the a and b axes with an isovalue level set to 0.005.

To achieve additional information for probable future experimental examination, the simulation of x-ray diffraction (XRD) patterns for oP-C16, oP-C20, and oP-C24 along with that of diamond are shown in Figure 6. Diamond possesses two diffraction peaks, which appear at 43.93 and 75.29° of (111) and (220), respectively, and in the present work, they are in good agreement with the experimental XRD spectra of 43.9 and 75.2° for (111) and (220) of diamond [45], indicating that the performed simulation method is reliable. Because of the same space groups of oP-C16, oP-C20, and oP-C24, their XRD spectra are also very close, which is reflected in the fact that all their three strong peaks appear between 35° and 48°. The peak intensities in the XRD patterns of oP-C16, oP-C20, and oP-C24 are not equivalent. The strongest peaks are (104), (105), and (106), which are located around 43.97, 43.48, and 43.55° for oP-C16, oP-C20, and oP-C24, respectively. For oP-C16 and oP-C20, their stronger peaks both contain the two peaks (013) and (105), while the stronger peaks of oP-C24 are (015), (106), and (017). Apart from these major diffraction peaks, several other weak diffraction peaks appeared in the XRD spectrum, such as, for (101) peaks, the diffraction angles are 36.19, 35.99, and 35.87° for oP-C16, oP-C20, and oP-C24, respectively; for (111) peaks, the diffraction angles are 50.86, 50.89, and 50.91° for oP-C16, oP-C20, and oP-C24, respectively. These XRD features have important significance and guidance for identifying the structures of oP-C16, oP-C20, and oP-C24 in future experiments.

Figure 6 Simulated XRD patterns of oP-C16, oP-C20, oP-C24, and diamond, using an x-ray wavelength (1.5406 Å) with a copper source for simulation in this work.
Figure 6

Simulated XRD patterns of oP-C16, oP-C20, oP-C24, and diamond, using an x-ray wavelength (1.5406 Å) with a copper source for simulation in this work.

4 Conclusion

In summary, three new carbon allotropes, oP-C16, oP-C20, and oP-C24, with metallic and superhard properties are proposed theoretically through first-principles calculations. These three new types of carbon structures possess many outstanding characteristics. oP-C16 is energetically more favorable than T10 and O12 carbon, while oP-C20 and oP-C24 are more favorable in energy than T18, O12, and O20 carbon. More importantly, oP-C16, oP-C20, and oP-C24 enjoy hardness levels of 47.5, 49.6, and 55.3 GPa, respectively. For oP-C16/oP-C20/oP-C24, the peak shear stresses are 11.5–18.1 GPa along the (010)[001], (010)[101], (110)[001], (110)[1–11], and (111)[1–10] directions, respectively. Although the three carbon allotropes proposed in this work are metals, their ideal shear strengths are also greater than those of common metals such as Cu, Fe, and Al. The p y electrons cross the Fermi level, revealing that oP-C16, oP-C20, and oP-C24 exhibit metallicity. Superhard, conductive, and other excellent physical properties make oP-C16, oP-C20, and oP-C24 have great application potential in multifunctional devices under extreme conditions, and they are also potential materials for electronic devices and mechanical tools. The theoretical research in this article is of great significance for enriching the gene pool of excellent materials and providing a solid theoretical basis for future experiments.

  1. Funding information: This work was supported by the National Natural Science Foundation of China (Nos. 61804120, 61803294, and 61901162); the China Postdoctoral Science Foundation (Nos. 2019TQ0243 and 2019M663646); key scientific research plan of Education Department of Shaanxi Provincial Government (Key Laboratory Project) (No. 20JS066); the Young Talent fund of University Association for Science and Technology in Shaanxi, China (No. 20190110); and the National Key R&D Program of China (No. 2018YFB1502902); and Key Program for International S&T Cooperation Projects of Shaanxi Province (No. 2019KWZ-03).

  2. Author contributions: All authors have accepted responsibility for the entire content of this manuscript and approved its submission.

  3. Conflict of interest: The authors state no conflict of interest.

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Received: 2021-08-02
Revised: 2021-08-28
Accepted: 2021-09-01
Published Online: 2021-09-23

© 2021 Qingyang Fan et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/ntrev-2021-0079
Schlagwörter für diesen Artikel
metallic carbon; superhard material; electronic properties; conductive directions
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BY 4.0

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  24. The experimental study of CFRP interlayer of dissimilar joint AA7075-T651/Ti-6Al-4V alloys by friction stir spot welding on mechanical and microstructural properties
  25. Vibration analysis of a sandwich cylindrical shell in hygrothermal environment
  26. Water barrier and mechanical properties of sugar palm crystalline nanocellulose reinforced thermoplastic sugar palm starch (TPS)/poly(lactic acid) (PLA) blend bionanocomposites
  27. Strong quadratic acousto-optic coupling in 1D multilayer phoxonic crystal cavity
  28. Three-dimensional shape analysis of peripapillary retinal pigment epithelium-basement membrane layer based on OCT radial images
  29. Solvent regulation synthesis of single-component white emission carbon quantum dots for white light-emitting diodes
  30. Xanthate-modified nanoTiO2 as a novel vulcanization accelerator enhancing mechanical and antibacterial properties of natural rubber
  31. Effect of steel fiber on impact resistance and durability of concrete containing nano-SiO2
  32. Ultrasound-enhanced biosynthesis of uniform ZnO nanorice using Swietenia macrophylla seed extract and its in vitro anticancer activity
  33. Temperature dependence of hardness prediction for high-temperature structural ceramics and their composites
  34. Study on the frequency of acoustic emission signal during crystal growth of salicylic acid
  35. Controllable modification of helical carbon nanotubes for high-performance microwave absorption
  36. Role of dry ozonization of basalt fibers on interfacial properties and fracture toughness of epoxy matrix composites
  37. Nanosystem’s density functional theory study of the chlorine adsorption on the Fe(100) surface
  38. A rapid nanobiosensing platform based on herceptin-conjugated graphene for ultrasensitive detection of circulating tumor cells in early breast cancer
  39. Improving flexural strength of UHPC with sustainably synthesized graphene oxide
  40. The role of graphene/graphene oxide in cement hydration
  41. Structural characterization of microcrystalline and nanocrystalline cellulose from Ananas comosus L. leaves: Cytocompatibility and molecular docking studies
  42. Evaluation of the nanostructure of calcium silicate hydrate based on atomic force microscopy-infrared spectroscopy experiments
  43. Combined effects of nano-silica and silica fume on the mechanical behavior of recycled aggregate concrete
  44. Safety study of malapposition of the bio-corrodible nitrided iron stent in vivo
  45. Triethanolamine interface modification of crystallized ZnO nanospheres enabling fast photocatalytic hazard-free treatment of Cr(vi) ions
  46. Novel electrodes for precise and accurate droplet dispensing and splitting in digital microfluidics
  47. Construction of Chi(Zn/BMP2)/HA composite coating on AZ31B magnesium alloy surface to improve the corrosion resistance and biocompatibility
  48. Experimental and multiscale numerical investigations on low-velocity impact responses of syntactic foam composites reinforced with modified MWCNTs
  49. Comprehensive performance analysis and optimal design of smart light pole for cooperative vehicle infrastructure system
  50. Room temperature growth of ZnO with highly active exposed facets for photocatalytic application
  51. Influences of poling temperature and elongation ratio on PVDF-HFP piezoelectric films
  52. Large strain hardening of magnesium containing in situ nanoparticles
  53. Super stable water-based magnetic fluid as a dual-mode contrast agent
  54. Photocatalytic activity of biogenic zinc oxide nanoparticles: In vitro antimicrobial, biocompatibility, and molecular docking studies
  55. Hygrothermal environment effect on the critical buckling load of FGP microbeams with initial curvature integrated by CNT-reinforced skins considering the influence of thickness stretching
  56. Thermal aging behavior characteristics of asphalt binder modified by nano-stabilizer based on DSR and AFM
  57. Building effective core/shell polymer nanoparticles for epoxy composite toughening based on Hansen solubility parameters
  58. Structural characterization and nanoscale strain field analysis of α/β interface layer of a near α titanium alloy
  59. Optimization of thermal and hydrophobic properties of GO-doped epoxy nanocomposite coatings
  60. The properties of nano-CaCO3/nano-ZnO/SBR composite-modified asphalt
  61. Three-dimensional metallic carbon allotropes with superhardness
  62. Physical stability and rheological behavior of Pickering emulsions stabilized by protein–polysaccharide hybrid nanoconjugates
  63. Optimization of volume fraction and microstructure evolution during thermal deformation of nano-SiCp/Al–7Si composites
  64. Phase analysis and corrosion behavior of brazing Cu/Al dissimilar metal joint with BAl88Si filler metal
  65. High-efficiency nano polishing of steel materials
  66. On the rheological properties of multi-walled carbon nano-polyvinylpyrrolidone/silicon-based shear thickening fluid
  67. Fabrication of Ag/ZnO hollow nanospheres and cubic TiO2/ZnO heterojunction photocatalysts for RhB degradation
  68. Fabrication and properties of PLA/nano-HA composite scaffolds with balanced mechanical properties and biological functions for bone tissue engineering application
  69. Investigation of the early-age performance and microstructure of nano-C–S–H blended cement-based materials
  70. Reduced graphene oxide coating on basalt fabric using electrophoretic deposition and its role in the mechanical and tribological performance of epoxy/basalt fiber composites
  71. Effect of nano-silica as cementitious materials-reducing admixtures on the workability, mechanical properties and durability of concrete
  72. Machine-learning-assisted microstructure–property linkages of carbon nanotube-reinforced aluminum matrix nanocomposites produced by laser powder bed fusion
  73. Physical, thermal, and mechanical properties of highly porous polylactic acid/cellulose nanofibre scaffolds prepared by salt leaching technique
  74. A comparative study on characterizations and synthesis of pure lead sulfide (PbS) and Ag-doped PbS for photovoltaic applications
  75. Clean preparation of washable antibacterial polyester fibers by high temperature and high pressure hydrothermal self-assembly
  76. Al 5251-based hybrid nanocomposite by FSP reinforced with graphene nanoplates and boron nitride nanoparticles: Microstructure, wear, and mechanical characterization
  77. Interlaminar fracture toughness properties of hybrid glass fiber-reinforced composite interlayered with carbon nanotube using electrospray deposition
  78. Microstructure and life prediction model of steel slag concrete under freezing-thawing environment
  79. Synthesis of biogenic silver nanoparticles from the seed coat waste of pistachio (Pistacia vera) and their effect on the growth of eggplant
  80. Study on adaptability of rheological index of nano-PUA-modified asphalt based on geometric parameters of parallel plate
  81. Preparation and adsorption properties of nano-graphene oxide/tourmaline composites
  82. A study on interfacial behaviors of epoxy/graphene oxide derived from pitch-based graphite fibers
  83. Multiresponsive carboxylated graphene oxide-grafted aptamer as a multifunctional nanocarrier for targeted delivery of chemotherapeutics and bioactive compounds in cancer therapy
  84. Piezoresistive/piezoelectric intrinsic sensing properties of carbon nanotube cement-based smart composite and its electromechanical sensing mechanisms: A review
  85. Smart stimuli-responsive biofunctionalized niosomal nanocarriers for programmed release of bioactive compounds into cancer cells in vitro and in vivo
  86. Photoremediation of methylene blue by biosynthesized ZnO/Fe3O4 nanocomposites using Callistemon viminalis leaves aqueous extract: A comparative study
  87. Study of gold nanoparticles’ preparation through ultrasonic spray pyrolysis and lyophilisation for possible use as markers in LFIA tests
  88. Review Articles
  89. Advance on the dispersion treatment of graphene oxide and the graphene oxide modified cement-based materials
  90. Development of ionic liquid-based electroactive polymer composites using nanotechnology
  91. Nanostructured multifunctional electrocatalysts for efficient energy conversion systems: Recent perspectives
  92. Recent advances on the fabrication methods of nanocomposite yarn-based strain sensor
  93. Review on nanocomposites based on aerospace applications
  94. Overview of nanocellulose as additives in paper processing and paper products
  95. The frontiers of functionalized graphene-based nanocomposites as chemical sensors
  96. Material advancement in tissue-engineered nerve conduit
  97. Carbon nanostructure-based superhydrophobic surfaces and coatings
  98. Functionalized graphene-based nanocomposites for smart optoelectronic applications
  99. Interfacial technology for enhancement in steel fiber reinforced cementitious composite from nano to macroscale
  100. Metal nanoparticles and biomaterials: The multipronged approach for potential diabetic wound therapy
  101. Review on resistive switching mechanisms of bio-organic thin film for non-volatile memory application
  102. Nanotechnology-enabled biomedical engineering: Current trends, future scopes, and perspectives
  103. Research progress on key problems of nanomaterials-modified geopolymer concrete
  104. Smart stimuli-responsive nanocarriers for the cancer therapy – nanomedicine
  105. An overview of methods for production and detection of silver nanoparticles, with emphasis on their fate and toxicological effects on human, soil, and aquatic environment
  106. Effects of chemical modification and nanotechnology on wood properties
  107. Mechanisms, influencing factors, and applications of electrohydrodynamic jet printing
  108. Application of antiviral materials in textiles: A review
  109. Phase transformation and strengthening mechanisms of nanostructured high-entropy alloys
  110. Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
  111. Catalytic defense against fungal pathogens using nanozymes
  112. A mini-review of three-dimensional network topological structure nanocomposites: Preparation and mechanical properties
  113. Mechanical properties and structural health monitoring performance of carbon nanotube-modified FRP composites: A review
  114. Nano-scale delivery: A comprehensive review of nano-structured devices, preparative techniques, site-specificity designs, biomedical applications, commercial products, and references to safety, cellular uptake, and organ toxicity
  115. Effects of alloying, heat treatment and nanoreinforcement on mechanical properties and damping performances of Cu–Al-based alloys: A review
  116. Recent progress in the synthesis and applications of vertically aligned carbon nanotube materials
  117. Thermal conductivity and dynamic viscosity of mono and hybrid organic- and synthetic-based nanofluids: A critical review
  118. Recent advances in waste-recycled nanomaterials for biomedical applications: Waste-to-wealth
  119. Layup sequence and interfacial bonding of additively manufactured polymeric composite: A brief review
  120. Quantum dots synthetization and future prospect applications
  121. Approved and marketed nanoparticles for disease targeting and applications in COVID-19
  122. Strategies for improving rechargeable lithium-ion batteries: From active materials to CO2 emissions
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Heruntergeladen am 11.10.2025 von https://www.degruyterbrill.com/document/doi/10.1515/ntrev-2021-0079/html
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