Abstract
Topological phase transition is accompanied with a change of topological numbers. According to the bulk-edge correspondence, the gap closing and the breakdown of the adiabaticity are necessary at the phase transition point to make the topological number ill-defined. However, the gap closing is not always needed. In this paper, we show that two topological distinct phases can be continuously connected without gap closing, provided the symmetry of the system changes during the process. Here we propose the generic principles how this is possible by demonstrating various examples such as 1D polyacetylene with the charge-density-wave order, 2D silicene with the antiferromagnetic order, 2D silicene or quantum well made of HgTe with superconducting proximity effects and 3D superconductor Cu doped Bi2Se3. It is argued that such an unusual phenomenon can occur when we detour around the gap closing point provided the connection of the topological numbers is lost along the detour path.
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Introduction
Topological insulator and superconductor are among the most fascinating concepts in physics found in this decade1,2,3,4,5,6,7. It is characterized by the topological numbers such as the Chern number and the index. When there are two topological distinct phases, a topological phase transition may occur between them. According to the bulk-edge correspondence, the gap must close at the topological phase transition point since the topological number cannot change its quantized value without gap closing. Note that the topological number is only defined in the gapped system and remains unchanged for any adiabatic process. Alternatively we may think of the edge or surface of the sample in a topological phase. Gapless edge or surface modes appear because the boundary of the sample separates a topological state and the vacuum whose topological numbers are zero. The phenomenon is known as the bulk-edge correspondence. We wonder if a topological phase transition cannot occur without gap closing at all.
The topological classes are classified8 by the eigenvalues of , and , where , and , represent the time-reversal, particle-hole and chiral symmetry operators. There are ten classes, which are separated into two complex and eight real representations. The topological periodic table has been established as in Table I, which classifies all the possible homotopy groups and topological numbers depending on the symmetry and dimensionality of the system. One important fact about this topological periodic table is that the adiabatic connection is possible between the two classes with the difference in dimensions by one9. As for the eight real representations, this connection is summarized by the symmetry clock shown in Fig. 1. Namely, considering the Hamiltonian H(k, r) which depends on both the D-dimensional real space coordinates r and d-dimensional momentum space coordinates k, the mapping connecting the neighboring classes in the symmetry clock is possible by adding r- or k-dependent Hamiltonian9. This means that the essential dimensionality is d′ = d − D and the adiabatic connection exists next to each other along the diagonal direction in the topological periodic table. In addition to this diagonal shift, one can consider the horizontal shift, i.e., dimensionality d′ by introducing the defects such as vortex (D = 1) and point defect (D = 2)10. There are several works on the vertical shift in the periodic table11,12,13,14,15. However in these cases, the gap closing is necessary for topological phase transitions.
In this paper, we study the adiabatic connection within the common dimensionality d′ and the possible change in the topological numbers without closing the gap. We propose two principles. Let the energy spectrum be given by Eρ(k) with a topological phase transition taking place at a critical point ρ = ρcr of a certain parameter ρ, where the gap closes. Let us assume that we can extend the Hamiltonian to include a new parameter Δs so that the energy spectrum is modified as
The phase transition point is (ρcr, 0) in the (ρ, Δs) phase diagram. We may detour the point (ρcr, 0) in the phase diagram, along which the gap never closes though a topological phase transition occurs. The second principle is that the topological number should become ill-defined by a symmetry change along the above detour. This invalidates requirements of the gap closing when the topological number changes.
Results
We have explored the generic principles of topological phase transition without gap closing by demonstrating various examples. The first example is a simple one-dimensional model of polyacetylene with reduced symmetry at intermediate states (BDI → A → BDI) by way of the charge-density-wave (CDW). We also present a two-dimensional example of silicene with the antiferromagnet (AF) order as another model with symmetry reducing. We then present three models with enhanced symmetry at intermediate state (AII → DIII → AII) by way of introducing the superconducting (SC) order8. They are silicene and quantum well made of HgTe as two-dimensional models and superconductor Cu doped Bi2Se3 as a three-dimensional model.
Polyacetylene with CDW order
We start with presenting a well-known one-dimensional example of polyacetylene with the CDW order from a new light. Polyacetylene belongs to the class BDI. With including the CDW order, the class change occurs into A by breaking the time-reversal and particle-hole symmetries simultaneously. We now show that there are two ways of topological phase transitions, one (BDI → BDI) with gap closing and the other (BDI → A → BDI) without gap closing.
Effective Hamiltonian
Polyacetylene is a bipartite system with one unit cell made of A and B sites. The bipartiteness introduces a pseudospin. We neglect the spin degree of freedom. The tight-binding model is given by16,17,18,19,20
in the momentum space, where τi is the Pauli matrix acting on the pseudospin Ψ = {ψA, ψB} and
where k is the momentum (0 ≤ k < 2π), t is the mean transfer integral, δ is the dimerization of the transfer integral. The energy spectrum is given by
The band gap locates at k = π and is given by 2|Epoly (π)| = 2|δ|. We consider polyacetylene with a finite length. We show the band structure in Figs. 2(c1), (c2), (c3). For δ < 0, the system is in the topological phase, as is evidenced by the presence of the gapless edge states in Fig. 2(c1). As |δ| increases, the gap decreases and vanishes at δ = 0 as in Fig. 2(c2). For δ > 0, the gap opens again but no gapless modes appear as in Fig. 2(c3): Hence, it is in the trivial phase. Thus, the topological phase transition occurs with gap closing at δ = 0.
We proceed to introduce CDW to polyacetylene. We assume it to generate the site-energy difference m between the A and B sites. The Hamiltonian is modified as
The energy spectrum is modified to be
which is of the form (1). The gap does not close when m ≠ 0.
Phase diagram
We explore the topological phase diagram in the (δ, m) plane in Fig. 2(a). We show the band gap as a function of the electric field δ and the CDW gap m in Fig. 2(b). It is intriguing that the gapless point exists only at one isolated point (0, 0) in the phase diagram. We consider two paths connecting the topological state at (δ, 0) with δ < 0 and a trivial state at (δ, 0) with δ > 0 shown in the phase diagram. In Fig. 2(c) we show the energy spectrum of finite chain at typical points.
We have already studied the first path along the δ axis. As the second path, we first move along the m axis. As changing δ, there is no gap closing even at δ = 0 due to the CDW gap: See Fig. 2(c5). When δ exceeds 0 as in Fig. 2(c6) we remove the CDW order. The resultant phase is a trivial insulator, as is given by Fig. 2(c3) on the δ axis. Along this process the gap never closes. This is an explicit example of a topological phase transition without gap closing.
Topological analysis
We analyze the topological number. For this purpose we define
where is the normalized vector, which we illustrate in Fig. 3(a).
When m = 0, the pseudospin is confined in the xy plane and the homotopy class is . Correspondingly, the quantity (7) takes only two values; Nwind = 1 for δ < 0 and Nwind = 0 for δ > 0. It is the winding number, as explained in Fig. 3(a). Indeed, the system is topological for δ < 0 and trivial for δ > 0.
On the other hand, when the CDW is present (m ≠ 0), the pseudospin acquires the z component and the homotopy class changes to the trivial class π1(S2) = 0. The quantity (7) is no longer the quantized to be an integer. Indeed, we can continuously change Nwind(m) from Nwind(m) = 1 to Nwind(m) = 0 as we move in the (δ, m) plane: See Fig. 3(b).
Silicene with AF order
We next present a two-dimensional example of silicene with the AF order as another model with symmetry reducing. Silicene is a honeycomb structure made of silicone atoms. It is a quantum spin-Hall (QSH) insulator21 and belongs to the class AII. When we introduce the AF order in the z axis, the class changes into A, but it is still a topological insulator. We call it spin-Chern insulator because the time-reversal symmetry is broken. We show that there are two ways of topological phase transitions between the QSH insulator and the trivial insulator with and without gap closing.
Low-energy Dirac theory
We analyze the physics of electrons near the Fermi energy, which is described by Dirac electrons near the K and K′ points. We also call them the Kη points with the valley index η = ±. We introduce the AF order mz along the z direction. The low-energy Dirac theory reads13,22,23
where σa and τa with a = x, y, z are the Pauli matrices of the spin and the sublattice pseudospin, respectively. The first term arises from the nearest-neighbor hopping, where is the Fermi velocity with the lattice constant a = 3.86Å. The second term is the intrinsic spin-orbit interaction with λSO = 3.9 meV. The third term represents the AF order. We have neglected the Rashba interaction since its existence does not modify the essential part of the physics. We present the Hamiltonian containing it in Supplementary Information.
The system undergoes a topological phase transition as the AF order mz changes13. The energy spectrum is given by
The system is a topological insulator for |mz| < 2λSO with the gap 2|λSO − mz|, as is evidenced by the emergence of gapless edge modes based on the bulk-edge correspondence: See Fig. 4(c1). As ηmz changes at the Kη point, the gap decreases and closes at the critical point mz = ηλSO, as in Fig. 4(c2). Then, the gap opens again, but there appear no longer gapless edge modes as in Fig. 4(c3), indicating that the system is in the trivial phase. The Chern and spin-Chern numbers are calculated to be
This is a typical example of a topological phase transition with gap closing.
Let us now introduce the AF order additionally in the x and y directions. The low-energy Dirac theory is given by
The energy spectrum is given by
which is of the form (1). The band gap locates at k = 0 and is given by . It closes only at (mx, my, mz) = (0, 0, ηλSO).
Phase diagram
We explore the phase diagram in the (mz, mx) plane with my = 0 in Fig. 4(a). We show the band gap as a function of the AF orders mz and mx in Fig. 4(b). The gapless points exist only at two isolated points (ηλSO, 0) in the phase diagram. We consider two paths connecting the QSH state at the origin and a trivial state at (mz, 0) with mz > λSO shown in the phase diagram. In Fig. 4(c) we show the band structure of silicene with edges at typical points. Along the detour the gap never closes. Hence we have shown that there are two ways of topological phase transitions with and without gap closing.
Topological analysis
Silicene is a topological insulator characterized by the Chern number and the index. It is to be noted that the z axis has been chosen by the intrinsic SO interaction in the Hamiltonian (8). As far as the AF order is along the z axis, there exists a rotational symmetry around the z axis. The system is the sum of two decoupled systems of sz = 1/2 and −1/2 and their respective Chern numbers are the topological numbers in this case. Equivalently, one can define the sum (Chern number) and the half of the difference (spin-Chern number) of these two Chern numbers. Note that the index is well defined when the time-reversal symmetry is present while the spin-Chern number is well defined when the spin sz is a good quantum number. They are equal mod 2 when both of them are well defined24.
When mx = my = 0, the spin-Chern number is well-defined. The topological phase is indexed by . However, when we introduce mx, the AF direction cants and the spin-Chern number becomes ill-defined. The system becomes a trivial insulator for mx ≠ 0 or my ≠ 0. After we make a detour around the critical point, we decreases mx until mx = 0, where the spin-Chern number becomes well-defined again. However, the system is in the trivial phase with when mz > λSO.
Helical edge states with AF order
It is quite interesting that the QSH insulator becomes a trivial insulator as soon as mx is introduced. (We assume mz = 0 for simplicity.) We are able to construct an effective low energy theory to explain how such a transition occurs. The helical edges are described by the 4 × 4-matrix Hamiltonian given by
It is diagonalized as
The Hamiltonian describes two edge modes crossing at k = 0 for mx = 0. As soon as mx ≠ 0, the level crossing turns into the level anticrossing, with open gap. The gap monotonously increases as |mx| increases. The system is topological for mx = 0 and is trivial for mx ≠ 0.
Silicene with SC order
We then present three models with symmetry increasing transitions (AII → DIII) by way of superconducting proximity effect25,26,27,28,29,30. The system is in the class AII without the SC order and the gap closing occurs at the topological phase transition point separating the two phases with and 0. However, we are able to make a topological phase transition (AII → DIII → AII) to occur without gap closing by switching on and off the SC order.
The first model is silicene with the SC order, which might be experimentally achieved by silicene synthesized on the Ir substrate, which has recently been found31. Its prominent feature is that Ir is superconducting at 0.1 K. This opens a natural way to fabricate superconducting proximity effects on to silicene by cooling down the system made of silicene together with the Ir substrate.
Low-energy Dirac theory
We analyze silicene by applying external electric field perpendicular to the sheet. The effective Dirac Hamiltonian in the momentum space reads22,23,32
The third term is the staggered potential term V induced by the electric field.
The system exhibits a topological phase transition from a QSH insulator to a trivial insulator as |V| increases32. The energy spectrum is given by
The band gap locates at k = 0 and is given by 2|Esi(0)| = 2|ηszλSO − V|. It closes at V = ±λSO. The QSH state has gapless edge states as in Fig. 5(c1). At V = λSO, the gap closes as in Fig. 5(c2) and it opens for V > λSO as in Fig. 5(c3). The Chern and spin-Chern numbers are calculated to be
This is a typical example of a topological phase transition with gap closing.
We assume that Cooper pairs are formed by mixing electrons at the K and K′ points and condense in silicene by attaching the s-wave SC. We present the BCS Hamiltonian and the associated BdG Hamiltonian in Supplementary Information.
It is straightforward to diagonalize the BdG Hamiltonian,
which is of the form (1). The band gap locates at k = 0 and it closes at (±λSO, 0) in the (V, Δs) plane.
Phase diagram
We explore the phase diagram in the (V, Δs) plane in Fig. 5(a). We show the band gap as a function of the electric field V and the SC gap Δs in Fig. 5(b). The gapless points exist only at two isolated points (±λSO, 0) in the phase diagram. We consider two paths connecting the QSH state at the origin and a trivial state at (V, 0) with V > λSO shown in the phase diagram. In Fig. 5(c) we show the band structure of silicene with edges at typical points.
As to the second path, we first move along the Δs axis from the origin in the phase diagram. Namely, we cool down the sample below the critical temperature of superconductivity. As soon as the critical temperature is passed, a topological class change occurs by adding the particle-hole symmetry associated with the Cooper-pair condensation. The SC gap mixes the helical edge modes, resulting in the disappearance of gapless edge modes and the system becomes trivial [Fig. 5(c4)]. The mechanism how the helical edge modes disappear is precisely the same as we demonstrated before: See Eq.(14). After the detour we warm up the sample. The superconductivity disappears. The resultant phase is a trivial insulator, as is given by Fig. 5(c3) on the V axis. Along this process the gap never closes.
Let us study this class change more in detail to confirm that it does not involve the gap closing. For this purpose we analyze a system where SC is attached on one-half of the system. It is important to demonstrate whether there emerge edge states between the boundary of the two regions25,33. The region without SC is in the QSH phase, while the superconducting region is in the trivial phase. We may alternatively calculate the band structure of silicene in torus geometry with the SC order introduced to one-half side of a cylinder [Fig. 6(a)]. Note that there are no edge states in silicene in torus geometry even in the QSH phase. The band structure is well known34 and given in Fig. 6(b). Once the superconducting gap is introduced partially as in Fig. 6(a), two boundaries appear between the SC and normal regions. We naively expect the emergence of gapless edge modes along each boundary due to the bulk-edge correspondence, as is the case34 between the QSH phase and the trivial phase. Nevertheless, we find no gapless edge states to appear as in Fig. 6(c). This reflects the fact that the topological phase changes between Δs = 0 and Δs ≠ 0 undergoes without gap closing.
Topological analysis
We next search for the reason why a topological phase transition can occur without gap closing as soon as the superconductor gap Δs is introduced. For this purpose we investigate the topological charges of the system. With the superconducting proximity effects, silicene belongs to the class DIII. Thus the topological class change occurs from AII to DIII as soon as the superconductor gap Δs is introduced, i.e., by adding the particle-hole and chiral symmetries. Both classes AII and DIII are characterized by the indices. However they are different objects. Consequently, although we have given the phase diagram in Fig. 5(a), each domain is indexed by different topological indices.
Since the spin sz is a good quantum number along the E axis in the phase diagram, the index is essentially the spin-Chern number for Δs = 0. The latter counts the numbers of up-spin electrons and down-spin electrons separately. When the SC order is introduced, the ground state is a condensed phase of Cooper pairs each of which is a pair of up-spin and down spin electrons. Consequently, the spin Chern number becomes ill-defined for Δs ≠ 0 and the gap closing is not required between the QSH state at Δs = 0 and a trivial state at Δs ≠ 0.
A comment is in order. Here we have assumed the singlet SC order. When we assume the triplet SC order, the energy spectrum is shown to be of the form
The triplet SC parameter Δt does not contribute to the gap at k = 0. The gap closing occurs although this is a topological class change from AII to DIII together with the Bose-Einstein condensation. This is not surprising since the spin-Chern number is well-defined for Δt ≠ 0 because the members of a Cooper pair are either up-spin or down-spin electrons.
Quantum well made of HgTe and CdTe
We present another two-dimensional example, which is the Bernevig-Hughes-Zhang (BHZ) model of the QSH system. The BHZ model describes the electronic structure of the subband of a quantum well made of HgTe and CdTe35, which is experimentally verified36. A topological phase transition can be induced by changing the thickness of the quantum well.
The Hilbert space is spanned by the four states which are eigenstates of the operator mJ, | ± 1/2〉 and | ± 3/2〉. We present the BHZ Hamiltonian in Supplementary Information. The energy spectrum is determined as
where A, B, C, D are sample-dependent parameters and M is the Dirac mass. The topological phase transition is known to occur at M = 0.
To explain it let us slightly simplify the model by choosing C = 0. Then, the energy spectrum is simplified as
The band gap locates at k = 0 and is given by 2|EBHZ (0)| = 2|M|. We show the band structure of silicene with edges in Figs. 7(c1),(c2),(c3). For M/B < 0, the system is in the topological phase, as is evidenced by the presence of the gapless edge modes in Fig. 7(c1). As |M| decreases, the gap decreases and closes at M = 0 as in Fig. 7(c2). For M/B > 0, the gap opens again but no gapless modes appear as in Fig. 7(c3): Hence, it is in the trivial phase. Thus, the topological phase transition occurs with gap closing.
We proceed to assume that the singlet Cooper pairs are formed due to the SC proximity effects with the SC gap Δs. The first pairing is between |1/2〉 and | − 1/2〉. The second pairing is between |3/2〉 and |− 3/2〉. In general these two gaps are different, but we assume them to be equal for simplicity. The BdG Hamiltonian is derived and given in Supplementary Information. It is diagonalized as
where each level is two-fold degenerate. The gap does not close when Δs ≠ 0.
We show the topological phase diagram in the (M, Δs) plane, the band gap and the band structure of silicene with edges with straight edge in Fig. 7. Employing the same discussion as in the case of silicene, we find that it is possible to make a topological phase transition without gap closing.
Cu doped Bi2Se3
Finally we present a three-dimensional example. Bi2Se3 is a three-dimensional topological insulator37. On the other hand, Cu doped Bi2Se338,39,40 becomes superconducting at low temperature38,39,40,41. The topological class change occurs from AII to DIII.
The Hamiltonian is given by42,43
with the chemical potential μ and
where σa and τa with a = x, y, z are the Pauli matrices of the spin and the orbital pseudospin, respectively: (v, v, vz) is the Fermi velocity and mi are sample parameters, which satisfy m1m2 > 0. The system is topological when m0m1 < 0 and trivial when m0m1 > 0. The energy spectrum is given by
The band gap locates at the Γ point with kx = ky = kz = 0, where EBiSe (0) = ±|m0|. The band gap is 2|m0|.
We cool the system below the SC transition point. There are four possible superconducting pairing40. The simplest one is the intra-orbital spin-singlet pairing, which results in trivial superconductor. The other three pairings lead to topological superconductor. We concentrate on the intra-orbital spin-singlet pairing since only this pairing enables the topological class change without gap closing. The BdG Hamiltonian is derived and given in Supplementary Information. It is diagonalized as
where each level is two-fold degenerate. The gap does not close when Δs ≠ 0. In the same way, the topological class change occurs without gap closing in the three-dimensional space.
Topological superconductor
We have so far studied a model Hamiltonian where the initial and final states are normal state without SC order. Here, we consider a situation where initial and final states are SC states. We consider a model Hamiltonian of two-dimensional spin-triplet px-wave superconductor with opposite spin pairing Sz = 0 or spin-singlet dxy-wave one. Although the initial Hamiltonian is 4 × 4 matrix in the electron-hole and spin spaces, it can be block diagonalized by 2 × 2 matrix in the absence of magnetic scattering and spin-orbit coupling. In order to consider the edge state for flat surface parallel to the y direction, we fix momentum ky. Then, the original two-dimensional Hamiltonian is reduced to be one-dimensional one. The resulting Hamiltonian can be written as
with Δ(kx) = Δ0 for px-wave pairing and Δ(kx) = Δ0 sin ky for dxy-wave one, respectively.
The energy spectrum of this Hamiltonian is
with ε = −t cos kx − μ and t > 0 with μ = μ0 + t cos ky. For |μ| < t, the superconducting state becomes topological with the zero-energy surface Andreev bound state44,45. On the other hand, for |μ| > t, it becomes trivial without zero energy ABS. For |μ| = t, the gap closing occurs at kx = 0 or kx = ±π. It has been clarified that the zero energy surface Andreev bound state is protected by the bulk topological number46.
Now, let us introduce an additional term Δ1τy. Then, the time reversal symmetry is broken and the resulting Hamiltonian becomes
The energy spectrum is obtained as
There is no gap closing for all kx and μ.
We first start from the topological phase with Δ1 = 0 with |μ| < t. Next, we switch on Δ1. Then, the system becomes a fully gapped one with time reversal symmetry breaking. We can change μ from |μ| < t to |μ| > t. During this change, there is no gap closing. After we switch off Δ1, we reach the topological trivial phase of the original Hamiltonian. One of the example relevant to the intermediate state is dxy-wave superconductor with s-wave pairing, where the relative phase between these two states is π/2. The (dxy + is)-wave pairing was focused on as the possible surface state of dxy-wave pairing in the context of Cuprate47. Topological phase transition for fixed momentum has been discussed in superfluid 3He-B under a magnetic field h parallel to the surface48. In this case, helical Andreev bound state remains gapless up to some critical field hc protected by discrete symmetry. There is no bulk gap closing at the transition point h = hc.
Discussion
According to the bulk-edge correspondence, a topological phase transition requires the gap closing and the breakdown of the adiabaticity at the transition point. This is not necessarily the case provided a topological class or symmetry change occurs such that the original set of topological numbers become ill-defined. There exists two possibilities of symmetry change. Both the cases with reduced symmetry and enhanced symmetry have been considered.
When the symmetry is reduced, the target space of the Hamiltonian becomes wider, which enables us to connect two distinct spaces adiabatically. As such an example we have considered a one-dimensional example of polyacetylene by way of the CDW, which induces the class change BDI → A. Here, the homotopy class changes from and the winding number becomes ill-defined. Consequently, we are able to make a topological phase transition (BDI → A → BDI) to occur without gap closing by switching on and off the CDW. We have also analyzed silicene with the AF order as another example with symmetry reducing. It is interesting that a topological phase transition without gap closing takes place within the same class A. However, there is a symmetry change whether the spin sz is a good quantum number and not. The reduced symmetry case may be regarded as an explicit example of the symmetry protected topological order49,50,51,52.
When the symmetry is enhanced, the above reasoning no longer follows. As such examples we have considered symmetry increasing transitions (AII → DIII) by way of introducing the SC order. Although both the classes AII and DIII are characterized by the index, their physical meaning is different. The index is essentially the spin-Chern number in the class AII system, which becomes ill-defined as soon as the system moves into the SC phase (DIII) due to the SC order. We have explicitly shown that a topological phase transition (AII → DIII → AII) may occur without gap closing by switching on and off the SC order.
We also note there is an another mechanism of topological phase transition without gap closing, which is induced by interactions53,54. The topological phase transition without gap closing is possible due to the appearnace of zeros in the Green function.
To conclude, we mention the implications of the adiabatic connection between the different sectors of topological number. Up to now only the single-particle Hamiltonian has been considered, but in reality the electron-electron interaction is effective and the gaps are often induced by the order parameters. Therefore, the character of the quantum critical phenomenon depends strongly on whether the continuous change of the topological number is possible or not. Namely, when we write down the effective action for the quantum phase transition, there are multiple order parameters relevant to the gapless point when the continuous detour is possible to change the topological number. When the multiple topological phase transitions merges at one point, even more interesting quantum critical phenomenon is expected. The global view of the phase diagram taking into account all the possible classes will be an important direction to study the topological quantum transition.
Change history
11 February 2014
A correction has been published and is appended to both the HTML and PDF versions of this paper. The error has not been fixed in the paper.
11 February 2014
Topological phase transition is accompanied with a change of topological numbers. According to the bulk-edge correspondence, the gap closing and the breakdown of the adiabaticity are necessary at the phase transition point to make the topological number ill-defined. However, the gap closing is not always needed. In this paper, we show that two topological distinct phases can be continuously connected without gap closing, provided the symmetry of the system changes during the process. Here we propose the generic principles how this is possible by demonstrating various examples such as 1D polyacetylene with the charge-density-wave order, 2D silicene with the antiferromagnetic order, 2D silicene or quantum well made of HgTe with superconducting proximity effects and 3D superconductor Cu doped Bi2Se3. It is argued that such an unusual phenomenon can occur when we detour around the gap closing point provided the connection of the topological numbers is lost along the detour path.
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Acknowledgements
This work was supported in part by Grants-in-Aid (No. 22740196) for Scientific Research from the Ministry of Education, Science, Sports and Culture of Japan, the Funding Program for World-Leading Innovative RD on Science and Technology (FIRST Program) and by the “Topological Quantum Phenomena” Grant-in Aid (No. 22103005) for Scientific Research on Innovative Areas from the Ministry of Education, Culture, Sports, Science and Technology (MEXT) of Japan.
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M.E. performed the calculations. All authors contributed to the preparation of this manuscript.
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Topological Phase Transition without Gap Closing
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Ezawa, M., Tanaka, Y. & Nagaosa, N. Topological Phase Transition without Gap Closing. Sci Rep 3, 2790 (2013). https://doi.org/10.1038/srep02790
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DOI: https://doi.org/10.1038/srep02790
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