Introduction

The graphene synthesized in 20041 have aroused enormous theoretical and experimental interests on two dimensional (2D) materials. Besides graphene, some other pure 2D materials were proposed such as graphyne or graphdiyne2,3,4,5, silicene6,7,8, germanene8, phosphorene9, 10, and borophene11, 12, where graphdiyne3, 5, silicene7, black phosphorene9, and borophene13 have been synthesized experimentally. In addition to pure 2D materials, the studies of binary or multivariate 2D materials were carried out gradually. In 2011, it was reported that monolayers were exfoliated from the layered compounds such as MoS2 in some common solvents, providing a strategy to synthesize 2D crystals14. Inspired by graphene and silicene, binary 2D monolayers consisting of C and Si dubbed silagraphene exhibit rich structures including various chemical stoichiometry and arrangement patterns associated with different electronic properties.

The synthesis of silicon carbide nanotubes15, 16 offered a possibility to prepare 2D crystals silagraphenes and several theoretical studies about silagraphene were carried out. Among various silagraphenes, the most commonly studied structure has C/Si = 1:1 ratio with alternative C and Si arrangement dubbed h-SiC in this paper. The first-principles calculations predicted that h-SiC was a semiconductor17,18,19,20,21,22. Chen et al. reported that a fully hydrogenated/fluorinated h-SiC heterobilayer possessed a quasi-metallic character and an external electric field opened a direct band gap, implying the potential applications in future nanoelectronics and optoelectronics23. Wang et al. showed that h-SiC can be used as metal-free catalyst for CO oxidation24. Keeping C/Si = 1:1 stoichiometry but varying the arrangement patterns, we demonstrated previously that t1-SiC and t2-SiC featuring C–C and Si–Si pairs were semimetal with Dirac cone (DC) featured band structures25. Silagraphenes with other stoichiometry have also been studied recently. The density functional theory (DFT) calculations combined with many-body perturbation formalism revealed that the band gap of silagraphene can be tuned continuously by varying the concentration of Si26. SiC2 was predicted to possess a metallic planar structure with local minimum featuring planar tetracoordinate Si units27. Further global structure search predicted that SiC2 prefers to form three buckled structures using the particle swarm optimization method with dispersed C2 dimers rather than individual C atoms28. Recently the first-principles calculations predicted that SiC7 silagraphene is a semiconductor with a direct band gap of 1.13 eV29. g-SiC3 and g-Si3C are predicted to possess DC band structures30, 31. Meanwhile, significant band gaps are opened and the band structures are topologically nontrivial after the introduction of spin-orbital coupling30.

DC featured band structures commonly lead to unique electronic properties. For example, the charge carrier mobility of graphene which possess DC band structure32, 33 can reach up to 107 cm2 /(V s)34. Only a few 2D materials possess DCs. The pure 2D DC materials include graphyne4, 35, square graphynes36, silicene6, 8, germanene8, and borophene37. The binary 2D DC systems include g-SiC3, g-Si3C30, 31, t1-SiC, t2-SiC25, and silagraphye38, 39. The modified 2D DC systems include 6(H2), 14, 18 graphyne, 6BN, 6, 12 graphyne40, janugraphene, chlorographene41, and hydrogenated and halogenated blue phosphorene42. The organic 2D DC systems include Mn2C18H12 43 and Ni2C24S6H12 44.

Despite many reports on 2D DC systems, fewer studies contribute to the origin of DC formation. Using a two bands model, Wang et al. summarized that the conditions of DC formation include specific symmetries, proper parameters, and a suitable Fermi level where there are only DC points and no other bands45. To understand the origin of DC of graphyne, it was clarified that the acetylenic linkages between vertexes atoms could be reduced to effective hopping terms whose combination decides the existence of DCs46, 47. More recently, by performing calculations using both DFT and a tight binding (TB) model. We proposed “pair coupling”25 and “triple coupling”39 mechanisms to elucidate the origin of DC formation of t1-SiC and α-graphyne, showing different processes of DC formations.

In this work, by performing DF and TB calculations, we analyzed the formation process of band structures of g-SiC3 and g-Si3C and elucidated the origin of DC formation by proposing a “ring coupling” mechanism referring to the couplings among the six same atoms forming a ring. On the basis of this mechanism, the conditions of the systems being self-doped were also discussed. Furthermore, we verified the “ring coupling” mechanism by studying analogous binary monolayers consisting of Ge and C as well as Ge and Si, showing DC featured band structures consistent with the results of Zhao et al.30. Finally, we calculated the electron transport properties of g-SiC3 and g-Si3C using non-equilibrium Green’s function method combined with density functional theory (NEGF-DFT), showing that the studied silagraphene exhibit electron conductance between silicene and graphene.

Results and Discussion

Atomic structures and stability of g-SiC3 and g-Si3C

By geometry optimization using DFT calculation, the atomic structures of g-SiC3 and g-Si3C (shown in Fig. 1) are acquired. They have planar forms with P6/MMM symmetry. And they are both graphene-like but consisting of two elements, one of which forms 6-membered rings. The corresponding structure parameters and formation energies are listed in Table 1. For comparison, the results of graphene and silicene from our previous work39 are also listed in Table 1.

Figure 1
figure 1

Atomic structures of (a) g-SiC3, (b) g-Si3C. (c) Brillouin zone models of all structures in this work.

Table 1 Bond lengths l (Å), lattice parameters a (Å), and formation energies per atom \({E}_{f}\), \({E}_{f^{\prime} }\) (eV), and the electron (hole) group velocities near Fermi surface v of g-SiC3, g-Si3C, graphene, and silicene. aFrom ref. 39.

To analyze the stability of the structures, we calculated two types of formation energy39. The first formation energy \({E}_{f}\) is defined as:

$${E}_{f}=(\sum _{i}{E}_{i}-{E}_{t})/n$$
(1)

where \({E}_{i}\) is the isolated atom energy for the i-th atom, \({E}_{t}\) is the total energy per cell, n is the total number of atoms per cell. The second formation energy is defined as:

$${E}_{f^{\prime} }=(\sum _{i}{n}_{ele-i}{E}_{ele-i}-{E}_{t})/n$$
(2)

where \({n}_{ele-i}\) is the number of the atoms of the i-th element in a cell, \({E}_{ele-i}\) is the energy per atom of the graphene-like structure only consisting of the i-th element (for example, when the i-th element is Si, \({E}_{ele-i}\) means the energy per atom of silicene), n is the total number of atoms per cell.

With higher C/Si proportion the formation energy \({E}_{f}\) of g-SiC3 is higher than g-Si3C, consistent with the fact that graphene is more stable than silicene. Compared with graphene and silicene, the C-C and Si-Si bond-lengths of g-SiC3 and g-Si3C change about 0.01 and 0.02 Å, respectively, and their formation energies \({E}_{f^{\prime} }\) are negative, indicating that the energy of g-SiC3 or g-Si3C is higher than the ideal mixture of graphene and silicene with the same C/Si proportions as g-SiC3 or g-Si3C.

We discussed the possibility of atomic segregation into the graphene and silicene nanoribbons with Si-C interfaces in section S2 of Supplementary Information.

To verify the structure stability, we carried out quantum molecular dynamics (MD) calculations at a canonical ensemble (NVT ensemble) at 600 K. The MD trajectories indicate that the atomic structures of g-SiC3 and g-Si3C do not change significantly after 2.5 ps (See Figure S1 in Supplementary Information). Previous phonon calculations of g-SiC3 and g-Si3C by Zhao et al. did not find modes with imaginary frequencies30. Ding et al. also verified the stability of g-SiC3 by density-functional-based tight binding molecular dynamics simulations and phonon calculations31.

Band structures of g-SiC3 and g-Si3C

In this work, the Brillouin zones of all the structures possess same models with hexagon shown in Fig. 1(c).

Band structure of g-SiC3

The band structure of g-SiC3 possesses DCs calculated by DFT as shown in Fig. 2(a) and (b). The electron/hole group velocity of g-SiC3 near Fermi surface is listed in Table 1. For comparison, the electron/hole group velocities of graphene and silicene were also calculated and listed in Table 1. These values are the group velocities averaged over electrons and holes as well as different directions. The averaged group velocity of g-SiC3 is lower than that of graphene but higher than that of silicene.

Figure 2
figure 2

(a) Band structure (left) and DOS (right) of g-SiC3. For the band structures, the black line is the DFT results and the red line is the results calculated by TB. (b) 3D band structure of g-SiC3 calculated by DFT.

From the density of states (DOS) of g-SiC3 (Fig. 2(a)), the bands near Fermi energy mainly attribute to the pz orbitals of Si and C. So we constructed a TB model to reproduce the band structure by only considering the pz orbitals. For the sake of convenience, we translated properly the lattice of g-SiC3 as Fig. 3, and labeled the vertex atoms A and B as well as the ring atoms 1–6. The TB Hamiltonian can be written as30, 39:

$$\hat{H}=\sum _{i}{E}_{i}{\hat{a}}_{i}^{+}{\hat{a}}_{i}+\sum _{\langle m,n\rangle }(-{t}_{mn}{\hat{a}}_{m}^{+}{\hat{a}}_{n}+{\rm{H}}{\rm{.c}}{\rm{.}})$$
(3)

where \({E}_{i}\) is the onsite energy of the i-th atom, \(-{t}_{mn}\) is the hopping energy between the n-th and m-th atom (only considering the nearest-neighboring atoms for simplicity), \({\hat{a}}_{i}^{+}\) and \({\hat{a}}_{i}\) are creation and annihilation operators, respectively. The TB parameters are determined by fitting against DFT results25. The onsite energies of C and Si are E C  = −1.090 eV and E Si  = 2.459 eV, respectively. The hopping energies of C-C and C-Si are t C-C  = 2.258 eV and t C-Si  = 1.715 eV, respectively. The agreement between the TB and DFT results verifies the rationality of the TB model (See Fig. 2(a)).

Figure 3
figure 3

Atomic structure of g-SiC3 used for TB analysis.

To understand the origin of DC featured band structure of g-SiC3, we make the analysis based on a TB model as follows. For simplicity, we rewrite t C-Si as t, and t C-C as t C .

The couplings among the six C ring atoms are strong due to the same onsite energies. So we first only consider the couplings among the six neighbouring C atoms without considering the couplings between the ring atoms and vertex atoms. The corresponding Hamiltonian can be written as:

$${\hat{H}}_{C}=\sum _{l=1}^{6}{E}_{C}{\hat{a}}_{l}^{+}{\hat{a}}_{l}-\sum _{m=1}^{6}({t}_{C}{\hat{a}}_{m}^{+}{\hat{a}}_{m+1}+{t}_{C}{\hat{a}}_{m+1}^{+}{\hat{a}}_{m})$$
(4)

where l or m are the atom labels for the six C ring atoms shown in Fig. 3, \({\hat{a}}_{7}\) and \({\hat{a}}_{7}^{+}\) mean \({\hat{a}}_{1}\) and \({\hat{a}}_{1}^{+}\), respectively. The eigenfunctions are:

$${|{\phi }_{C-j}\rangle }_{n}=\frac{1}{\sqrt{6}}\sum _{l=1}^{6}{e}^{i\frac{\pi }{3}j\cdot l}{|{\varphi }_{C-l}\rangle }_{n}(j=1,2,\cdots ,6)$$
(5)

where \({|{\varphi }_{C-l}\rangle }_{n}\) is the wave function of l-th C atom in the n-th cell. The conclusion that \({|{\phi }_{C-j}\rangle }_{n}\) is the eigenfunctions of \({\hat{H}}_{C}\) can be verified as:

$${\hat{H}}_{C}{|{\phi }_{C-j}\rangle }_{n}=({E}_{C}-{e}^{i\frac{\pi }{3}j}{t}_{C}-{e}^{-i\frac{\pi }{3}j}{t}_{C}){|{\phi }_{C-j}\rangle }_{n}(j=1,2,\cdots ,6)$$
(6)

The eigenvalues of \(|{\phi }_{C-3}\rangle \) and \(|{\phi }_{C-6}\rangle \) are \({E}_{C}+2{t}_{C}\) and \({E}_{C}-2{t}_{C}\), respectively. \(|{\phi }_{C-2}\rangle \) and \(|{\phi }_{C-4}\rangle \) are degenerated at \({E}_{C}+{t}_{C}\); \(|{\phi }_{C-1}\rangle \) and \(|{\phi }_{C-5}\rangle \) are degenerated at \({E}_{C}-{t}_{C}\). There are four eigenvalues in total.

Based on the wave functions \({|{\phi }_{C-j}\rangle }_{n}\) and the wave functions of Si atoms, we define the Bloch basis sets:

$${|j\rangle }_{{\bf{k}}}=\frac{1}{\sqrt{N}}\sum _{n}{e}^{i{\bf{k}}\cdot {{\bf{R}}}_{n}}{|{\phi }_{C-j}\rangle }_{n}j=1,2,\ldots ,6$$
(7)
$${|A\rangle }_{{\bf{k}}}=\frac{1}{\sqrt{N}}\sum _{n}{e}^{i{\bf{k}}\cdot {{\bf{R}}}_{n}}{|{\phi }_{Si-A}\rangle }_{n}$$
(8)
$${|B\rangle }_{{\bf{k}}}=\frac{1}{\sqrt{N}}\sum _{n}{e}^{i{\bf{k}}\cdot {{\bf{R}}}_{n}}{|{\phi }_{Si-B}\rangle }_{n}$$
(9)

where \({|{\phi }_{Si-A}\rangle }_{n}\) and \({|{\phi }_{Si-B}\rangle }_{n}\) are the wavefunctions of Si atoms labeled A and B shown in Fig. 3. The eigenfunctions of this system are the linear superposition of these eight functions. With these eight functions as basis vectors in the order of

$${|A\rangle }_{{\bf{k}}},{|1\rangle }_{{\bf{k}}},{|2\rangle }_{{\bf{k}}},\,\cdots ,{|6\rangle }_{{\bf{k}}},{|B\rangle }_{{\bf{k}}}$$
(10)

The matrix \(H({\bf{k}})\) of Hamilton operator \(\hat{H}\) can be written as

$$H({\bf{k}})=(\begin{array}{lllll}{H}_{AA} & {H}_{A1} & {H}_{A2} & \cdots & {H}_{AB}\\ {H}_{1A} & {H}_{11} & {H}_{12} & \cdots & {H}_{1B}\\ {H}_{2A} & {H}_{21} & {H}_{22} & \cdots & {H}_{1B}\\ \cdots & & & & \\ {H}_{BA} & {H}_{B1} & {H}_{B1} & \cdots & {H}_{BB}\end{array})$$
(11)

The diagonal elements are

$${H}_{jj}={}_{{\bf{k}}}\langle j|\hat{H}{|j\rangle }_{{\bf{k}}}={E}_{C}-{e}^{i\frac{\pi }{3}j}{t}_{C}-{e}^{-i\frac{\pi }{3}j}{t}_{C}$$
(12)
$${H}_{AA}={}_{{\bf{k}}}\langle A|\hat{H}{|A\rangle }_{{\bf{k}}}={H}_{BB}={}_{{\bf{k}}}\langle B|\hat{H}{|B\rangle }_{{\bf{k}}}={E}_{Si}$$
(13)

Refer to the off-diagonal elements, due to the couplings among six C ring atoms having been considered, \({H}_{jj^{\prime} }\)(\(j\ne j^{\prime} \)) are all zero; and because the Si atoms at A and B are not neighbors, \({H}_{AB}\) is zero. So the non-zero elements of off-diagonal elements are only \({H}_{jA}\) and \({H}_{jB}\) as well as their conjugates. The non-zero elements are listed in Table 2, where \({\bf{a}}=a{\bf{i}},\,{\bf{b}}=a(-\frac{1}{2}{\bf{i}}+\frac{\sqrt{3}}{2}{\bf{j}})\) (Fig. 1(a)). These deduction procedures are similar to the case of h-SiC25. From Table 2, for \({H}_{jj}\), there are four different values corresponding to the four eigenvalues of \(|{\phi }_{C-j}\rangle \), independent of Bloch wave vector k. Among the four values of \({H}_{jj}\), \({H}_{22}\) and \({H}_{44}\) are degenerated at \({E}_{C}+{t}_{C}\), and \({H}_{11}\) and \({H}_{55}\) are degenerated at \({E}_{C}-{t}_{C}\).

Table 2 H matrix elements.

Now we discuss the values of the elements of matrix \(H({\bf{k}})\) at the K \((\frac{-2\pi }{3a}{\bf{i}}+\frac{2\pi }{\sqrt{3}a}{\bf{j}})\) point in Brillouin zone [Fig. 1(c)] listed in Table 2. At the K point, some of the elements \({H}_{jA}\) and \({H}_{jB}\) are zeros. So we can divide the basis vectors in Eq. (10) into three groups so that the couplings at the K point only exist between the vectors from the same groups but not between the vectors from different groups:

  1. (1)

    \({|A\rangle }_{{\bf{k}}},\,{|2\rangle }_{{\bf{k}}},\,{|5\rangle }_{{\bf{k}}};\)

  2. (2)

    \({|B\rangle }_{{\bf{k}}},\,{|4\rangle }_{{\bf{k}}},\,{|1\rangle }_{{\bf{k}}}\)

  3. (3)

    \({|3\rangle }_{{\bf{k}}},\,{|6\rangle }_{{\bf{k}}}\)

If the vector \({|1\rangle }_{{\bf{k}}}\) from the second group changes to \(-{|1\rangle }_{{\bf{k}}}\), the matrix of the second group is the conjugate of the matrix of the first group in total Brillouin zone. So after diagonalization of the first and second group respectively, three pairs of energy bands can be acquired, each pair of which are equal in total Brillouin zone, and the middle pair are located near the Fermi surface. Referring to the third group, because there is little coupling between \({|3\rangle }_{{\bf{k}}}\) and \({|6\rangle }_{{\bf{k}}}\) for any wave vector k, the two energy levels \({E}_{C}+2{t}_{C}\) and \({E}_{C}-2{t}_{C}\) remain unchanged in the total Brillouin zone when only considering the couplings within each group.

On the basis of analysis above, we divide the formation of DCs band structure into the following three steps conceptually to understand the origin of DCs band structure:

  1. (a)

    First, the couplings among the six C ring atoms generate six energy states, where two pairs of energy states are degenerated at \({E}_{C}+{t}_{C}\) and \({E}_{C}-{t}_{C}\), respectively, and the other two energy states are located at \({E}_{C}+2{t}_{C}\) and \({E}_{C}-2{t}_{C}\), respectively. Including the two energy states of Si atoms degenerated at \({E}_{Si}\), there are eight energy states in total. This process is shown in Fig. 4(a).

    Figure 4
    figure 4

    3D band structure of g-SiC3 from TB. (a) The couplings between the wave functions from same or different groups are all not considered. (b) Only the couplings between the wave functions from same groups are considered. (c) The couplings between the wave functions from same and different groups are all considered.

  2. (b)

    The eight energy states can be divided into three groups as mentioned above. And we only consider the intra-group couplings ignoring inter-group couplings in total Brillouin zone. Then after diagonalization, both of the first and the second group generate three bands making up three pairs of bands, among which, each pair are equal in total Brillouin zone, and the middle pair lie around the Fermi surface. As for the third group, two flat bands will be acquired due to little couplings between these two states. This process is shown in Fig. 4(b).

  3. (c)

    The inter-group couplings not considered above are included at this step. This makes the band gap to be generated except for the K points where no inter-group couplings exist. So the bands maintain touching at the K points and are separated in the other zones, resulting in the formation of DCs bands. This process is shown in Fig. 4(c).

On the basis of “ring coupling” mechanism, changing the TB parameters E C , E Si , t C-C , and t C-Si does not influence the formation of DC band structure. So this DC band structure is robust to change vertex element or ring element into other elements. This conclusion can be verified by the calculation of g-Si3C, g-GeC3, g-Ge3C, g-GeSi3, and g-Ge3Si later in this work. If the onsite energies of the two vertex atoms are not equal due to different types of vertex atoms, the three pairs of bands generated by the couplings within the first group and the second group would possess different values within each pair of bands at the K point, leading to a semiconducting system. This explains why SiC7 is a semiconductor29.

Conditions of g-SiC3-like systems possessing self-doped band structure

From the band structure of g-SiC3 [Fig. 2(a)], near Fermi surface, the energy value of valence band (VB) at the Γ point is very close to the energy value of the K point where DC appears (DC point). If the energy value of VB at the Γ point is slightly higher than DC point, the DC point would be slightly lower than Fermi surface, forming the so-called self-doped system4, 30. So it is important to compare the value of VB or CB (if the value of CB at the Γ point is lower than the DC point, the DC point will be higher than Fermi surface) at the Γ point with DC point. From discussion above, the energy value of DC point is the middle eigenvalue of the matrix of the first group (or the second group) at the K point. While, from Table 2, at the Γ point, the couplings only exist among the four wave functions

$${|3\rangle }_{{\bf{k}}},{|6\rangle }_{{\bf{k}}},{|A\rangle }_{{\bf{k}}}\,{\rm{and}}\,{|B\rangle }_{{\bf{k}}}$$
(14)

corresponding to the energy levels \({E}_{C}+2{t}_{C}\), \({E}_{C}-2{t}_{C}\), \({E}_{Si}\), and \({E}_{Si}\), respectively. To acquire the values of VB and CB at the Γ point, the Hamiltonian matrix with the vectors in Eq. (14) as basis set is diagonalized at the Γ point with scanning \({E}_{Si}\) and other parameters remaining unchanged. The result is shownin Fig. 5(a). And for comparing the values of VB and CB at the Γ point with the DC point, we calculated the values of DC point with scanning \({E}_{Si}\) without changing the other parameters as shown in Fig. 5(a). We discuss the results as the follows.

  1. (1)

    When \({E}_{Si}\) is near \({E}_{C}\) (−4.825 eV < \({E}_{Si}\) < 2.645 eV), the value of DC point is higher than the value of VB at the Γ and lower than the value of CB at Γ, so the DC point exists on the Fermi surface, and this system is a DC system.

  2. (2)

    When \({E}_{Si}\) is far from \({E}_{C}\) (\({E}_{Si}\) < −4.825 eV or \({E}_{Si}\) > 2.645 eV), the DC point deviated from the Fermi surface. Specially, when \({E}_{Si}\) < −4.825 eV, the value of CB at the Γ is lower than the value of DC point, leading to DC point higher than Fermi surface; while when \({E}_{Si}\) > 2.645 eV, the value of VB at the Γ is higher than the value of DC point, leading to DC point lower than Fermi surface.

  3. (3)

    When \({E}_{Si}\) < −4.825 eV or \({E}_{Si}\) > 2.645 eV, but \({E}_{Si}\) is very close to −4.825 eV or 2.645 eV, the DC point deviated only slightly from the Fermi surface, leading to the formation of a self-doped system.

Figure 5
figure 5

The values of band at the Γ and the K point of g-SiC3 with scanning E Si and other parameters unchanged. The black lines express the four levels from the couplings of the hexagon C ring. The green lines with the equal horizontal coordinate and vertical coordinate express the parameter E Si . The blue lines express the four values of bands at the Γ point which are the eigenvalues of the Hamilton submatrix with the vectors in Eq. (14) as basis set at the Γ point. The red lines express the value of Dirac point which is the middle eigenvalue of the Hamilton submatrix with the vectors of the first group as basis set at the K point. (a) The TB parameters unchanged compared to g-SiC3. (b) Decreasing the hopping energy between C and Si (t C-Si ) with hopping energy between C and C (t C-C ) as well as onsite energy of C (E C ) unchanged compared to g-SiC3. (c) Decreasing the hopping energy between C and C (t C-C ) with hopping energy between C and Si (t C-Si ) as well as the onsite energy of C (E C ) unchanged compared to g-SiC3.

So, increasing the difference between the onsite energies of vertex atoms and ring atoms change the systems into self-doped systems. The calculations for g-GeC3 and g-Ge3C later in this paper support this conclusion.

To examine the influence of hoping energy on the formation of self-doped systems, we changed the hoping energy \({t}_{C-Si}\) (\({t}_{C-C}\)), and performed the same calculations required in Fig. 5(a) to acquire Fig. 5(b) [Fig. 5(c)].

From Fig. 5(b), reducing \({t}_{C-Si}\), from 1.715 to 1.2 eV, with \({E}_{C}\) and \({t}_{C-C}\) unchanged, shrinks the range of \({E}_{Si}\), from [−4.825, 2.645] eV to [−3.494, 1.314] eV, in which the DC point is located on the Fermi level. While, from Fig. 5(c), reducing \({t}_{C-C}\), from 2.258 to 1.4 eV, with \({E}_{C}\) and \({t}_{C-Si}\) unchanged, enlarges the range of \({E}_{Si}\), from [−4.825, 2.645] eV to [−5.992, 3.812] eV, in which the DC point is located on the Fermi level. So, decreasing \({t}_{C-Si}\) and increasing \({t}_{C-C}\) may change the system into self-doped system.

Increasing (decreasing) bond length can mimic the decreasing (increasing) of hopping energy, so increasing the C-Si bond length and/or decreasing the C-C bond length may change g-SiC3 into self-doped system, while increasing the C-C bond length and/or decreasing the C-Si bond length increase the difference between the value of Dirac point and the value of VB at the Γ point compared with the equilibrium system. We decreased (increased) the C-C bond length with 0.06 Å and increased (decreased) the C-Si bond length with 0.06 Å, keeping the lattice parameter unchanged; then calculated their band structures by DFT (Fig. 6). From Fig. 6, we found that: (1) When the C-C bond length is decreased by 0.06 Å and C-Si bond length is increased by 0.06 Å, with lattice parameter unchanged, the value of Dirac point (−0.121 eV) is lower than the value of VB at the Γ point (0.027 eV), forming a self-doped system [Fig. 6(a)]. (2) When the C-C bond length is increased with 0.06 Å and C-Si bond length is decreased by 0.06 Å, with lattice parameter unchanged, the difference (0.242 eV) between the value of Dirac point (0.010 eV) and the value of VB at the Γ point (−0.232 eV) increases [Fig. 6(b)] compared with the equilibrium system. (For the equilibrium system, the value of Dirac point is −0.027 eV, the value of valence at the Γ point is −0.067 eV, and the difference is 0.040 eV. [Fig. 2(a)]) So the DF calculations support our TB analysis above, and we may tune the bond length of g-SiC3 to change g-SiC3 into a self-doped system by depositing the monolayers on appropriate substrates. Thermal vibrations around equilibrium atom positions are not expected to affect the self-doping behavior due to random features of bond length changes.

Figure 6
figure 6

Band structures and DOS of g-SiC3 with C-C and C-Si bond length changed and lattice parameter unchanged. (a) C-C bond length is decreased with 0.06 Å and C-Si bond length is increased with 0.06 Å with lattice parameter unchanged. (b) C-C bond length is increased with 0.06 Å and C-Si bond length is decreased with 0.06 Å with lattice parameter unchanged.

Band structure of g-Si3C

g-Si3C (Fig. 1(b)), possessing similar atomic structure as g-SiC3 [Fig. 1(a)], also displays DCs in band structure (Fig. 7) due to “ring coupling” mechanism referring to the couplings of six Si ring atoms. The group velocity of g-Si3C near Fermi surface is listed in Table 1 after averaged over electrons and holes as well as different directions. The electron/hole group velocity of g-Si3C is lower than that of graphene or g-SiC3 and is similar to that of silicene. These results are related to the transport properties discussed later.

Figure 7
figure 7

(a) Band structure (left) and DOS (right) of g-Si3C. For the band structure, the black lines are the results calculated by DFT and the red lines are the results calculated by TB. (b) 3D band structure of g-Si3C calculated by DFT.

Figure 8 shows the formation process of DCs band structure of g-Si3C similar to the formation process of DCs band structure of g-SiC3 (Fig. 4). The TB parameters are obtained by fitting DFT results: the onsite energies of C and Si are E C  = −2.113 eV and E Si  = 0.428 eV, respectively; The hopping energies of Si-Si and C-Si are t Si-Si  = 1.037 eV and t C-Si  = 1.212 eV, respectively.

Figure 8
figure 8

3D band structure of g-Si3C by TB. (a) The couplings between the wave functions from same or different groups are all not considered. (b) Only the couplings between the wave functions from same groups are considered. (c) The couplings between the wave functions from same and different groups are all considered.

Figure 8(a) shows differences opposite to Fig. 4(a): for Fig. 8(a) which is the “band structure” of g-Si3C, the band from vertex A (or B) lie out of the “other four bands” (the four energy levels from the coupling of the six same type atoms in a ring), while for Fig. 4(a) which is the “band structure” of g-SiC3, the band from vertex A (or B) lie among the “other four bands”. This can be explained as follows: because the C-C coupling is stronger than the Si-Si coupling (t C-C  > t Si-Si ), the differences between the highest band and the lowest band of the “other four band” for g-Si3C is smaller than g-SiC3, which results to the band from vertex A (or B) for g-Si3C laying out of the “other four bands”.

Atomic structures and band structures of g-GeC3, g-Ge3C, g-GeSi3, and g-Ge3Si

Similar to g-SiC3 and g-Si3C, substituting Si or C with Ge from the same main group in the periodic table, we constructed the binary models of g-GeC3, g-Ge3C, g-GeSi3, and g-Ge3Si. Their atomic structures optimized by DFT are shown in Fig. 9. Their atomic structure parameters and formation energy are listed in Table 3. For the purpose of comparison, we optimized the geometry structure of germanene. Due to silicene and germanene preferring to sp3 hybridization, g-Ge3C, g-GeSi3, and g-Ge3Si are all buckled with non-planar structures. While, g-GeC3 is a planar structure with all atoms in a plane because carbon prefer to sp2 hybridization and this structure consists of more carbon atoms than g-Ge3C. These results are similar to the study of Zhao et al. except for the g-Ge3C (a planar structure in their studies)30. As shown in Tables 1 and 3, the formation energy \({E}_{f}\) of g-GeC3, g-Ge3C, g-GeSi3, and g-Ge3Si decreases gradually, which can be understood by the fact that the formation energy \({E}_{f}\) decreases in the order of graphene (9.23 eV), silicene (4.77 eV) and germanene (4.03 eV) and the energy \({E}_{f}\) of silicene is very close to germanene.

Figure 9
figure 9

Atomic structures of (a) g-GeC3, (b) g-Ge3C, (c) g-GeSi3, and (d) g-Ge3Si.

Table 3 Bond lengths l (Å), lattice parameters a (Å), size of buckle d z (Å) and formation energies per atom [\({E}_{f}\) and \({E}_{f^{\prime} }\) (eV)] of g-GeC3, g-Ge3C, g-GeSi3, g-Ge3Si, and germanene.

The g-GeC3, g-Ge3C, g-GeSi3, and g-Ge3Si systems also possess DCs band structures (Fig. 10) due to possessing similar atomic structures as g-SiC3 and g-Si3C, as well as all elements belong to IV group. A small difference is that the Dirac points of g-GeC3 and g-Ge3C deviate slightly from Fermi surface, leading to the formation of self-doped systems. Specifically, as for g-GeC3, because the value of VB at the Γ point is higher than the value of Dirac point, the DC point is lower than Fermi surface. According to the discussions above, it is understood that the difference between the onsite energies of Ge and C atom is larger than that between Si and C atom as well as the hopping energy between Ge and C atom is smaller than that between Si and C atom. And referring to g-Ge3C, the value of CB at the Γ point is lower than the Dirac point, so the Dirac point is higher than Fermi surface. Because the atomic structure of g-Ge3C is buckled, the pz orbitals may be coupled to the other orbitals, and the band near Fermi surface may include the other orbitals except for the pz orbitals, leading to the formation of self-doped system. From the band structure of planar g-Ge3C calculated by Zhao et al.30, there is a band from non-pz orbitals near Fermi surface, consistent with our analysis. These results agree with the studies of Zhao et al.30.

Figure 10
figure 10

Band structures and DOS of (a) g-GeC3, (b) g-Ge3C, (c) g-GeSi3, and (d) g-Ge3Si.

When the C atom of g-Si3C is substituted by B, N, Al, or P, the atomic model structures of XSi3 (X = B, N, Al, or P) can be constructed. When the Si atom of g-SiC3 is substituted by B, BC3 can be constructed. According to the analyses above, these structures should also possess DC band structures. However, because the numbers of the valence electrons of these structures are different from g-SiC3 or g-Si3C, the DCs of these structures are either above or under the Fermi surface. Previous studies support this discussion48, 49.

Electron transport properties of g-SiC3 and g-Si3C nanoribbons

For the potential nanoelectronic device applications, we calculated directly the electron transport properties of g-SiC3 and g-Si3C nanoribbons.

The current density versus voltage curves were calculated and shown in Fig. 11 for the lead-molecule-lead junctions. Here we showed the current density, dividing the current by the surface area of electrode. The current density and voltage have nearly linear relationship over the bias voltages ranging from 0 to 2.0 V. We found that the current of g-SiC3 is larger than g-Si3C, both of which are smaller than graphene but larger than silicenes in both bulked and planar forms. It is known that graphene has larger electron conductance than silicene50. The studied binary monolayers have conductance between graphene and silicene and the conductance increases as the C concentration increases (Figure S5 in Supplementary Information). Table 4. lists the electron conductance of the systems under various bias voltages. These electron transport results are consistent with the electron/hole group velocities calculated from the band structures shown earlier.

Figure 11
figure 11

Current density versus voltage relations of graphene (black square), g-SiC3 (red circle), g-Si3C (blue triangle), bulked silicene (pink down triangle), planar silicene (green diamond) under bias voltages of 0.5 V, 1.0 V, 1.5 V, and 2.0 V.

Table 4 Electron conductance of graphene, g-SiC3, g-Si3C, bulked silicene, and planar silicene under various bias voltages.

Conclusions

In this work we proposed a “ring coupling” mechanism to illustrate the formation of DCs of g-SiC3 and g-Si3C as the examples of binary monolayers AB3 and A3B (A, B = C, Si, and Ge): (1) the couplings of six C ring atoms form six new wave functions corresponding to four energy levels. The middle two energy levels are doubly degenerated, respectively. (2) The two wave functions of Si and the four wave functions corresponding to the middle two doubly degenerated levels are divided into two groups; each group contains one wave function of Si and two wave functions each from the two different doubly degenerated wave functions. The intra-group coupling of each group forms three bands, and there are six bands in total from these two groups. The six bands make up three pairs, and each pair are equal at the K point. The rest two of the six functions from the couplings of six C ring atoms form two flat bands (they are the third group). (3) After considering the inter-group couplings among the three groups, the gap is formed. However, there are no inter-group couplings at the K point where the bands remain contact, leading to the formation of DCs.

Based on this “ring coupling” mechanism, the possible methods changing the g-SiC3-like monolayers into self-doped systems are discussed: (a) Increasing the difference between the onsite energies of ring atom and vertex atom, (b) decreasing the hopping energies between the ring atom and vertex atom. (c) increasing the hopping energy between the two ring atoms.

The “ring coupling” mechanism proposed in this work is applicable to 2D DC materials possessing ring patterns. We previously also studied other typical 2D structures. Specifically, we used the “pair coupling” mechanism to explain DC formation in 2D materials with paired atoms, e.g. t1-SiC25. Moreover, we proposed the “triple coupling” mechanism to understand DC formation in α-grahynes where triple atom-chains were coupled first39. The “ring coupling”, “pair coupling”, and “triple coupling” mechanisms share the similar methodology but account for various arrangement patterns in understanding the general mechanism of Dirac cone formation in 2D materials, thus they can be unified into a more general framework called “divide-and-couple”, which can be applied to illustrate the origins of Dirac cone formation in other Fermi Dirac systems.

Method and computational details

In this work, the DFT calculations were carried out using the Vienna ab initio simulation package (VASP)51, 52. The exchange-correlation function and pseudopotentials adopted the form of Perdew-Burke-Ernzerh (PBE) within a generalized gradient approximation (GGA)53 and the projector augmented-wave (PAW) method54 respectively. For binary 2D systems, we adopted 700 eV energy cutoff for the expansion of plane wave basis set and (7 × 7 × 1) for Monkhorst-Pack sampling, leading to convergence of 0.001 eV. For unitary 2D systems, the (17 × 17 × 1) Monkhorst-Pack grid was used. The SCF calculations converge to 5.0 × 10−7 eV/atom, while the geometry optimizations converge to 5.0 × 10−6 eV/atom using conjugated gradient method. The QMD calculations were carried out with a 700 eV energy cutoff, a (5 × 5 × 1) Monkhorst-Pack k-point sampling, and the SCF tolerance 1.25 × 10−7 eV/atom. The vacuum region among layers is longer than 15 Å to avoid the influences among periodic images.

To evaluate the electron transport properties for their potential applications as electronic devices, we calculated the current-voltage (I-V) characteristics, electron transmission spectrum, and density of states of g-SiC3 and g-Si3C, compared with graphene and silicene in both bulked and planar forms using ab initio modeling package nanodcal55, 56. Figure S4(a) in the Supplementary Information illustrates the lead-molecule-lead junction with the semi-infinite Au lead. We first optimized the molecule-electrode distances using the DMol3 program. The Perdew-Burke-Ernzerhof (PBE) functional under General Gradient Approximation (GGA) was adopted with double-ζ polarization basis set and DFT Semi-core pseudopotentials57, 58. T = 300 K was used for the Fermi-Dirac distribution around Fermi level throughout the work of this section. Figure S4(b–f) shows the configurations of the optimized junctions.