Periodic table of topological insulators and topological superconductors

The periodic table of topological insulators and topological superconductors, also called tenfold classification of topological insulators and superconductors, is an application of topology to condensed matter physics. It indicates the mathematical group for the topological invariant of the topological insulators and topological superconductors, given a dimension and discrete symmetry class.[1] The ten possible discrete symmetry families are classified according to three main symmetries: particle-hole symmetry, time-reversal symmetry and chiral symmetry. The table was developed between 2008–2010[1] by the collaboration of Andreas P. Schnyder, Shinsei Ryu, Akira Furusaki and Andreas W. W. Ludwig;[2][3] and independently by Alexei Kitaev.[4]

Overview

Periodic table of topological insulators and superconductors (1D up to 3D)[1]
Symmetry class Operation Dimension
1 2 3
A X X X
AIII X X 1
AI 1 X X
BDI 1 1 1
D X 1 X
DIII -1 1 1
AII -1 X X
CII -1 -1 1
C X -1 X
CI 1 -1 1

These table applies to topological insulators and topological superconductors with an energy gap, when particle-particle interactions are excluded. The table is no longer valid when interactions are included.[1]

The topological insulators and superconductors are classified here in ten symmetry classes (A,AII,AI,BDI,D,DIII,AII,CII,C,CI) named after Altland–Zirnbauer classification, defined here by the properties of the system with respect to three operators: the time-reversal operator , charge conjugation and chiral symmetry . The symmetry classes are ordered according to the Bott clock (see below) so that the same values repeat in the diagonals.[5]

An X in the table of "Symmetries" indicates that the Hamiltonian of the symmetry is broken with respect to the given operator. A value of ±1 indicates the value of the operator squared for that system.[5]

The dimension indicates the dimensionality of the systes: 1D (chain), 2D (plane) and 3D lattices. It can be extended up to any number of positive integer dimension. Below, there can be four possible group values that are tabulated for a given class and dimension:[5]

  • A value of 0 indicates that there is no topological phase for that class and dimension.
  • The group indicates that the topological invariant can take integer values (e.g. ±0,±1,±2,...).
  • The group of indicates that the topological invariant can take even values (e.g. ±0,±2,±4,...).
  • The group of indicates that the topological invariant can take two values (e.g ±1).

Physical examples

The non-chiral Su–Schrieffer–Heeger model (), can be associated with symmetry class BDI with an integer topological invariant due to gauge invariance.[6][7] The problem is similar to the integer quantum Hall effect and the quantum anomalous Hall effect (both in ) which are A class, with integer Chern number.[8]

Contrarily, the Kitaev chain (), is an example of symmetry class D, with a binary topological invariant.[7] Similarly, the superconductors () are also in class D, but with a topological invariant.[7]

The quantum spin Hall effect () described by Kane–Mele model is an example of AII class, with a topological invariant.[9]

Construction

Discrete symmetry classes

There are ten discrete symmetry classes of topological insulators and superconductors, corresponding to the ten Altland–Zirnbauer classes of random matrices. They are defined by three symmetries of the Hamiltonian , (where , and , are the annihilation and creation operators of mode , in some arbitrary spatial basis) : time-reversal symmetry, particle-hole (or charge conjugation) symmetry, and chiral (or sublattice) symmetry.

  • Chiral symmetry is a unitary operator , that acts on , as a unitary rotation (,) and satisfies . A Hamiltonian possesses chiral symmetry when , for some choice of (on the level of first-quantised Hamiltonians, this means and are anticommuting matrices).
  • Time-reversal symmetry (TRS) is an antiunitary operator , that acts on , (where , is an arbitrary complex coefficient, and , denotes complex conjugation) as . It can be written as where is the complex conjugation operator and is a unitary matrix. Either or . A Hamiltonian with time reversal symmetry satisfies , or on the level of first-quantised matrices, , for some choice of .
  • Charge conjugation or particle-hole symmetry (PHS) is also an antiunitary operator which acts on as , and can be written as where is unitary. Again either or depending on what is. A Hamiltonian with particle hole symmetry satisfies , or on the level of first-quantised Hamiltonian matrices, , for some choice of .

In the Bloch Hamiltonian formalism for crystal structures, where the Hamiltonian acts on modes of crystal momentum , the chiral symmetry, TRS, and PHS conditions become

  • (chiral symmetry)
  • (time-reversal symmetry),
  • (particle-hole symmetry).

It is evident that if two of these three symmetries are present, then the third is also present, due to the relation .

The aforementioned discrete symmetries label 10 distinct discrete symmetry classes, which coincide with the Altland–Zirnbauer classes of random matrices.

Symmetry class Time reversal symmetry Particle hole symmetry Chiral symmetry
A No No No
AIII No No Yes
AI Yes, No No
BDI Yes, Yes, Yes
D No Yes, No
DIII Yes, Yes, Yes
AII Yes, No No
CII Yes, Yes, Yes
C No Yes, No
CI Yes, Yes, Yes

Equivalence classes of Hamiltonians

A bulk Hamiltonian in a particular symmetry group is restricted to be a Hermitian matrix with no zero-energy eigenvalues (i.e. so that the spectrum is "gapped" and the system is a bulk insulator) satisfying the symmetry constraints of the group. In the case of dimensions, this Hamiltonian is a continuous function of the parameters in the Bloch momentum vector in the Brillouin zone; then the symmetry constraints must hold for all .

Given two Hamiltonians and , it may be possible to continuously deform into while maintaining the symmetry constraint and gap (that is, there exists continuous function such that for all the Hamiltonian has no zero eigenvalue and symmetry condition is maintained, and and ). Then we say that and are equivalent.

However, it may also turn out that there is no such continuous deformation. in this case, physically if two materials with bulk Hamiltonians and , respectively, neighbor each other with an edge between them, when one continuously moves across the edge one must encounter a zero eigenvalue (as there is no continuous transformation that avoids this). This may manifest as a gapless zero energy edge mode or an electric current that only flows along the edge.

An interesting question is to ask, given a symmetry class and a dimension of the Brillouin zone, what are all the equivalence classes of Hamiltonians. Each equivalence class can be labeled by a topological invariant; two Hamiltonians whose topological invariant are different cannot be deformed into each other and belong to different equivalence classes.

Classifying spaces of Hamiltonians

For each of the symmetry classes, the question can be simplified by deforming the Hamiltonian into a "projective" Hamiltonian, and considering the symmetric space in which such Hamiltonians live. These classifying spaces are shown for each symmetry class:[4]

Symmetry class Classifying space of Classifying space
A
AIII
AI
BDI
D
DIII
AII
CII
C
CI

For example, a (real symmetric) Hamiltonian in symmetry class AI can have its positive eigenvalues deformed to +1 and its negative eigenvalues deformed to -1; the resulting such matrices are described by the union of real Grassmannians

Classification of invariants

The strong topological invariants of a many-band system in dimensions can be labeled by the elements of the -th homotopy group of the symmetric space. These groups are displayed in this table, called the periodic table of topological insulators:

Symmetry class
A
AIII
AI
BDI
D
DIII
AII
CII
C
CI

There may also exist weak topological invariants (associated to the fact that the suspension of the Brillouin zone is in fact equivalent to a sphere wedged with lower-dimensional spheres), which are not included in this table. Furthermore, the table assumes the limit of an infinite number of bands, i.e. involves Hamiltonians for .

The table also is periodic in the sense that the group of invariants in dimensions is the same as the group of invariants in dimensions. In the case of no ant-iunitary symmetries, the invariant groups are periodic in dimension by 2.

For nontrivial symmetry classes, the actual invariant can be defined by one of the following integrals over all or part of the Brillouin zone: the Chern number, the Wess-Zumino winding number, the Chern–Simons invariant, the Fu–Kane invariant.

Dimensional reduction and Bott clock

The periodic table also displays a peculiar property: the invariant groups in dimensions are identical to those in dimensions but in a different symmetry class. Among the complex symmetry classes, the invariant group for A in dimensions is the same as that for AIII in dimensions, and vice versa. One can also imagine arranging each of the eight real symmetry classes on the Cartesian plane such that the coordinate is if time reversal symmetry is present and if it is absent, and the coordinate is if particle hole symmetry is present and if it is absent. Then the invariant group in dimensions for a certain real symmetry class is the same as the invariant group in dimensions for the symmetry class directly one space clockwise. This phenomenon was termed the Bott clock by Alexei Kitaev, in reference to the Bott periodicity theorem.[1][10]

Eightfold Bott clock (bold classes are chiral)
PHS
TRS
-1 X 1
-1 CII AII DII
X C D
1 CI AI BDI

The Bott clock can be understood by considering the problem of Clifford algebra extensions.[1] Near an interface between two inequivalent bulk materials, the Hamiltonian approaches a gap closing. To lowest order expansion in momentum slightly away from the gap closing, the Hamiltonian takes the form of a Dirac Hamiltonian . Here, are a representation of the Clifford Algebra , while is an added "mass term" that and anticommutes with the rest of the Hamiltonian and vanishes at the interface (thus giving the interface a gapless edge mode at ). The term for the Hamiltonian on one side of the interface cannot be continuously deformed into the term for the Hamiltonian on the other side of the interface. Thus (letting be an arbitrary positive scalar) the problem of classifying topological invariants reduces to the problem of classifying all possible inequivalent choices of to extend the Clifford algebra to one higher dimension, while maintaining the symmetry constraints.

See also

References

  • Altland, Alexander; Zirnbauer, Martin R. (1997). "Novel Symmetry Classes in Mesoscopic Normal-Superconducting Hybrid Structures". Physical Review B. 55 (2): 1142. arXiv:cond-mat/9602137. Bibcode:1997PhRvB..55.1142A. doi:10.1103/PhysRevB.55.1142. S2CID 96427496.
  1. ^ a b c d e f Chiu, C.; J. Teo; A. Schnyder; S. Ryu (2016). "Classification of topological quantum matter with symmetries". Rev. Mod. Phys. 88 (35005): 035005. arXiv:1505.03535. Bibcode:2016RvMP...88c5005C. doi:10.1103/RevModPhys.88.035005. S2CID 119294876.
  2. ^ Schnyder, Andreas P.; Ryu, Shinsei; Furusaki, Akira; Ludwig, Andreas W. W. (2008-11-26). "Classification of topological insulators and superconductors in three spatial dimensions". Physical Review B. 78 (19): 195125. arXiv:0803.2786. Bibcode:2008PhRvB..78s5125S. doi:10.1103/PhysRevB.78.195125.
  3. ^ Ryu, Shinsei; Schnyder, Andreas P; Furusaki, Akira; Ludwig, Andreas W W (2010-06-17). "Topological insulators and superconductors: tenfold way and dimensional hierarchy". New Journal of Physics. 12 (6): 065010. arXiv:0912.2157. Bibcode:2010NJPh...12f5010R. doi:10.1088/1367-2630/12/6/065010. ISSN 1367-2630.
  4. ^ a b Kitaev, Alexei (2009). "Periodic table for topological insulators and superconductors". AIP Conference Proceedings. AIP. pp. 22–30. arXiv:0901.2686. doi:10.1063/1.3149495.
  5. ^ a b c Topology course team (2021). "10 symmetry classes and the periodic table of topological insulators". Online course on topology in condensed matter - TU Delft. Retrieved 2024-09-13.
  6. ^ Sachdev, Subir (2023-04-13). Quantum Phases of Matter. Cambridge University Press. ISBN 978-1-009-21269-4.
  7. ^ a b c Huber, Sebastian (2013). "5 Topological insulators and superconductors". Topological quantum numbers in condensed matter systems. ETH Zurich.
  8. ^ Altland, Alexander; Simons, Ben (2023-09-14). Condensed Matter Field Theory. Cambridge University Press. ISBN 978-1-108-49460-1.
  9. ^ Stanescu, Tudor D. (2024-07-02). Introduction to Topological Quantum Matter & Quantum Computation. CRC Press. ISBN 978-1-040-04191-8.
  10. ^ Ryu, Shinsei. "General approach to topological classification". Topology in Condensed Matter. Retrieved 2018-04-30.