- 1Institute for Theoretical Physics and Astrophysics, University of Würzburg, Würzburg, Germany
- 2School of Science, Westlake University, Hangzhou, China
We study the topological properties of the generalized two-dimensional (2D) Su-Schrieffer-Heeger (SSH) models. We show that a pair of Dirac points appear in the Brillouin zone (BZ), consisting a semimetallic phase. Interestingly, the locations of these Dirac points are not pinned to any high-symmetry points of the BZ but tunable by model parameters. Moreover, the merging of two Dirac points undergoes a novel topological phase transition, which leads to either a weak topological insulator or a nodal-line metallic phase. We demonstrate these properties by constructing two specific models, which we referred as type-I and type-II 2D SSH models. The feasible experimental platforms to realize our models are also discussed.
1 Introduction
Topological phases of matter have attracted tremendous research interests in recent decades [1, 2]. Among those famous topological models, the 1D Su-Schrieffer-Hegger (SSH) model provides a prototype and simple model endowed with rich physics to investigate topological phenomena in condensed matter physics [3]. It exhibits fascinating topological properties such as the topological phase transitions associated with Zak phase and fractional fermions number at the ends of the sample [3]. It also helps to clarify the theory of bulk polarization based on Berry phase [4], which has wide and deep impacts on condensed matter physics in recent decades, especially on the development of topological band insulators [5, 6].
Recently, the 1D SSH model has been extended to 2D on a square lattice. For instance, Liu et al. found that the 2D SSH model shows nontrivial topological phases even the Berry curvature is zero in the whole BZ [7]. Benalcazar et al. extended the 1D SSH model to two-, and three-dimensional systems with a π-flux inserted at each plaquette of the lattice. The proposed Benalcazar-Bernevig-Hughes (BBH) models hold quantized bulk quadrupole and octupole moments in 2D and 3D, respectively [8, 9]. Similar to 1D SSH model, bound states carrying fractional charges exist at the corners of the system. Thus the BBH provides a concert example for the higher-order topological insulators (HOTIs). Such HOTIs generalize the conventional bulk-boundary correspondence. Typically, a topological bulk state in d-dimension has robust (d − 1)-dimensional boundary states. Nevertheless, HOTIs have localized states at boundaries that are two or three dimensions lower than the bulk. The HOTIs have consequently attracted both theoretical and experimental interest over past years [10–31], and the higher-order topological protection has been extended to superconductors [32–38] and semimetals [39–41].
Since several types of 2D SSH models are possible when generalizing the 1D SSH model, it is thus natural to ask whether these models exhibit interesting topological properties. In this work, we investigate the properties of two typical kinds of 2D SSH models. Remarkably, we find that these models have rich topological phases. In the semimetallic phase, a pair of Dirac points appear in the BZ. Interestingly, the locations of the Dirac points are not pinned but can be easily tuned by continuous parameter modulations without breaking any symmetries. The merging of two Dirac points will experience a novel topological phase transition which transform the system to either a weak topological insulator or a nodal-line metallic phase. We demonstrate the topological properties of these different phases by employing two independent winding numbers together with boundary signatures and symmetry arguments. We also discuss how to realize our model experimentally based on synthetic quantum materials.
The remainder of this paper is organized as follows. Section 2 introduces the type-I 2D SSH model and its band structure. Section 3 presents the semimetallic phases of the type-I 2D SSH model. Section 4 shows the anisotropic nature of type-I 2D SSH model. Section 5 considers properties of type-II 2D SSH model. Finally, we conclude our results with a discussion in Section 6.
2 Type-I Two-Dimensional Su-Schrieffer-Heeger Model
Let us focus on the type-I 2D SSH model first [42]. We consider a type-I 2D SSH model as shown in Figure 1A, where the weak (thin) bonds and strong (thick) bonds are alternately dimerized along the two adjacent parallel lattice rows (x-direction) or columns (y-direction). The four orbital degrees of freedom in each unit cell are labeled as 1–4. For clarity, we consider spinless fermions. The lattice Hamiltonian is
where
where k = (kx, ky) is the 2D wave-vector; t and tx/y are the staggered hopping amplitudes along x/y-directions. For simplicity, we put the lattice constant to be unity and assume t > 0 hereafter. From its off-diagonal form, the Hamiltonian in Eq. 2 respects chiral (sublattice) symmetry. Explicitly, the chiral symmetry is
where we have defined
FIGURE 1. (A) Schematic of the type-I 2D SSH lattice. Blue (red) thick and thin bonds mark alternately dimerized hopping amplitudes in x(y)-direction. (B) The full phase diagram of the type-I 2D SSH model in the parameter space (tx, ty). The shadowed region represents the semimetals (SMs) with a pair of Dirac points. The orange dashed line at tx = ty corresponds to a nodal-line metallic phase. Other regions are the weak topological insulators.
3 Semimetallic Phases
The type-I 2D SSH model actually possesses three different topological phases, as shown in the phase diagram Figure 1B. Here we first discuss the semimetallic phase with a pair of Dirac points within the region |tx + ty| < 2t and tx ≠ ty. Due to the presence of chiral symmetry, the conduction and valence bands touch at zero energy (Figure 2A). Thus, the existence of Dirac points is constrained by the conditions ξη(k) = ζη(k) = 0. Consequently, we find a pair of Dirac points located at K± ≡±(Kx, − Ky), where Kx/y are given by
FIGURE 2. Band structure in different phases of type-I 2D SSH model. (A) Band structure in the semimetallic phase with tx = 0.2t and ty = 0.8t. (B) Band structure for the nodal-line metallic phase with tx = ty = 0.5t. (C) Band structure for a critical phase point with tx = 1.6t and ty = 0.4t. (D) Band structure for the weak topological insulators with tx = 1.6t and ty = 1.2t.
Astonishingly, the Dirac points are not pinned to any high-symmetry points but are highly tunable by parameter modulations. If we consider a simple parameterization with tx = s ∈ [0, t], ty = t − s, and t = 1, we find that the relation Kx + Ky = 2π/3 holds true. As a result, the Dirac points move along a line segment when we vary the parameter s. Interestingly, no symmetries are broken as we move around Dirac points by variation of tx and ty. The Dirac points are topologically protected by a quantized charge
Let us then turn to the nodal-line metallic phase under the specific condition tx = ty [Figure 2B]. From Eq. 4, we find that the system exhibits a gapless nodal line at
The appearance of a gapless nodal line is a direct consequence of accidental mirror symmetry along the line x + y = 0. In momentum space, the mirror symmetry is expressed as MH(kx, ky)M−1 = H( −ky, − kx). Note that the Hamiltonian H(k) commutes with the mirror operator M along the nodal-line kx + ky = 0. Therefore, we can label the eigen states of the Hamiltonian H(k) by the eigen states of mirror operator M as
We further note that the mirror operator commute with the chiral symmetry operator, i.e.,
4 Weak Topological Insulating Phases
The merging of two Dirac points can transfer the system from the semimetallic phase to a weak topological insulator, which provides a novel type of topological phase transition. Figure 2C presents the band structure at the critical merging points, at which the spectrum stays linear along one direction while becomes parabolic along another direction [45]. Specifically, the weak topological insulators is located in the region |tx + ty| > 2t and tx ≠ ty. The weak topological insulators possess a direct band gap, see Figure 2D. It is described by two winding numbers (wx, wy) with one of them being one and the other being zero. The winding number is defined as
for arbitrary ky/x ∈ [0, 2π]. Actually, this weak topological insulators can be further divided into two subphases: (i) wx = 1, wy = 0 (tx > ty and |tx + ty| > 2t) and (ii) wx = 0, wy = 1 (tx < ty and |tx + ty| > 2t). When wx = 1, wy = 0 (wx = 0, wy = 1), the system is nontrivial along x(y)-direction and trivial along y(x)-direction. It is clear that once crossing the boundary tx = ty the system will shift from subphase (i) to subphase (ii) or vice versa. Correspondingly, a totally flat edge band exists in the gap of the energy spectrum of a ribbon along x(y)-direction for the subphase (i) [subphase (ii)]. Figures 3A,B present the band structure of a ribbons along x- and y -direction, respectively, for the subphase (ii). The flat edge bands exist only in Figure 3A. Notably, neither the topologically trivial insulator with wx = wy = 0 nor the nontrivial phase with wx = wy = 1 appear in the inclined 2D SSH model.
FIGURE 3. (A) Energy spectrum of a ribbon along x-direction with width Wy = 20. Notice the flat band at zero energy. (B) Energy spectrum of the ribbons along y-direction with width Wx = 20. (C) Wannier bands θy as a function of kx. (D) Wannier bands θx as a function of ky. The other parameters are tx = 1.2t and ty = 1.8t.
Furthermore, the calculation of Wannier bands can also provide consistent results with that of wx/y to identify the topological properties. Specifically, the Wilson loop operator parallel to y direction is constructed as [9, 46].
where each projection operator is defined as
5 Type-II Two-Dimensional Su-Schrieffer-Heeger Model
Now, let us consider another similar model: the type-II 2D SSH model, in which the alternatively dimerization pattern is shown in Figure 4A. The lattice Hamiltonian reads as
FIGURE 4. (A) Schematic of the type-II 2D SSH lattice. Blue (red) thick and thin bonds mark alternately dimerized hopping amplitudes in x(y)-direction. (B) The band structure with at pair of Dirac points. Her we take tx = 0.4t, ty = 1.2t.
The type-II model has many similarities with the type-I model, thus we just focus on the semimetallic phase with Dirac points here. The effective Bloch Hamiltonian describing the type-II 2D SSH model has the same form as Eq. 2 but with the off-diagonal parts replaced as
Its energy bands are
where we have defined the functions as
Its Dirac points are located along kx = 0 (or kx = π) when ty > 0 (or ty < 0) (see Figure 4D). Explicitly, the Dirac points locate at
where
6 Discussion and Conclusion
Here we discuss how to realize our proposals experimentally. The most important ingredient is the controllable nearest-neighbor couplings between sites on the square lattice. Fortunately, such techniques have been developed in synthetic quantum materials such as photonic and acoustic crystals [14, 28, 47–49], electric circuits [50], and waveguides [15, 51]. For instance, to realize our model in an acoustic system, the 3D printed “atoms” can be arranged to a square lattice with four contained in each unit cell and the alternately dimerized couplings between neighbors can be modulated the diameters that the sound wave go through. Another feasible platform to realize our model is based on ultracold gases in optical lattices [52, 53], in which the lattice geometry and hopping strengths are adjustable.
Note that our results are distinctively different from recent reports to realize Dirac states in square lattices [54–56]. These proposals require necessary π fluxes on each plaquette, and the Dirac points are pinned to boundaries of the BZ, which may makes it more difficult to detect experimentally. While our 2D SSH model does not require delicate manipulations of external flux. Interestingly, our models even provide platforms to realize the so called toric-code insulator [56].
In conclusion, we have proposed the 2D SSH models on a square lattice to realize tunable Dirac states. We have found that the locations of Dirac points are not pinned in the BZ but movable by parameter modifications. The merging of two Dirac points leads to a topological phase transition, which converts the system from a semimetallic phase to either a nodal-line metallic or a weak topological insulator. We expect that our model can be realized in different metamaterial platforms.
Data Availability Statement
The original contributions presented in the study are included in the article/Supplementary Material, further inquiries can be directed to the corresponding author.
Author Contributions
C-AL initiated the project, derived the results and wrote the manuscript.
Funding
This work was supported by the DFG (SPP1666 and SFB1170 “ToCoTronics”), the Würzburg-Dresden Cluster of Excellence ct.qmat, EXC2147, Project-id 390858490, and the Elitenetzwerk Bayern Graduate School on “Topological Insulators”, and the NSF of Zhejiang under Grant No. Q20A04005.
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s Note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
Acknowledgments
The author acknowledges S. B. Zhang, S. J. Choi, B. Fu, and B. Trauzettel for helpful discussions.
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Keywords: su-schrieffer-heeger (SSH) models, topological states, two-dimensions, Dirac points, topological phase transitions
Citation: Li C-A (2022) Topological States in Two-Dimensional Su-Schrieffer-Heeger Models. Front. Phys. 10:861242. doi: 10.3389/fphy.2022.861242
Received: 24 January 2022; Accepted: 01 March 2022;
Published: 16 March 2022.
Edited by:
Rui Wang, Chongqing University, ChinaReviewed by:
Rafael A. Molina, Spanish National Research Council (CSIC), SpainMingda Li, Massachusetts Institute of Technology, United States
Copyright © 2022 Li. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Chang-An Li, Y2hhbmdhbi5saUB1bmktd3VlcnpidXJnLmRl