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Symmetry-protected topological order

January 01, 1970

Symmetry-protected topological (SPT) order[1][2] is a kind of order in zero-temperature quantum-mechanical states of matter that have a symmetry and a finite energy gap.

To derive the results in a most-invariant way, renormalization group methods are used (leading to equivalence classes corresponding to certain fixed points).[1] The SPT order has the following defining properties:

(a) distinct SPT states with a given symmetry cannot be smoothly deformed into each other without a phase transition, if the deformation preserves the symmetry.
(b) however, they all can be smoothly deformed into the same trivial product state without a phase transition, if the symmetry is broken during the deformation.

The above definition works for both bosonic systems and fermionic systems, which leads to the notions of bosonic SPT order and fermionic SPT order.

Using the notion of quantum entanglement, we can say that SPT states are short-range entangled states with a symmetry (by contrast: for long-range entanglement see topological order, which is not related to the famous EPR paradox). Since short-range entangled states have only trivial topological orders we may also refer the SPT order as Symmetry Protected "Trivial" order.

Characteristic properties edit

  1. The boundary effective theory of a non-trivial SPT state always has pure gauge anomaly or mixed gauge-gravity anomaly for the symmetry group.[3] As a result, the boundary of a SPT state is either gapless or degenerate, regardless how we cut the sample to form the boundary. A gapped non-degenerate boundary is impossible for a non-trivial SPT state. If the boundary is a gapped degenerate state, the degeneracy may be caused by spontaneous symmetry breaking and/or (intrinsic) topological order.
  2. Monodromy defects in non-trivial 2+1D SPT states carry non-trival statistics[4] and fractional quantum numbers[5] of the symmetry group. Monodromy defects are created by twisting the boundary condition along a cut by a symmetry transformation. The ends of such cut are the monodromy defects. For example, 2+1D bosonic Zn SPT states are classified by a Zn integer m. One can show that n identical elementary monodromy defects in a Zn SPT state labeled by m will carry a total Zn quantum number 2m which is not a multiple of n.
  3. 2+1D bosonic U(1) SPT states have a Hall conductance that is quantized as an even integer.[6][7] 2+1D bosonic SO(3) SPT states have a quantized spin Hall conductance.[8]

Relation between SPT order and (intrinsic) topological order edit

SPT states are short-range entangled while topologically ordered states are long-range entangled. Both intrinsic topological order, and also SPT order, can sometimes have protected gapless boundary excitations. The difference is subtle: the gapless boundary excitations in intrinsic topological order can be robust against any local perturbations, while the gapless boundary excitations in SPT order are robust only against local perturbations that do not break the symmetry. So the gapless boundary excitations in intrinsic topological order are topologically protected, while the gapless boundary excitations in SPT order are symmetry protected.[9]

We also know that an intrinsic topological order has emergent fractional charge, emergent fractional statistics, and emergent gauge theory. In contrast, a SPT order has no emergent fractional charge/fractional statistics for finite-energy excitations, nor emergent gauge theory (due to its short-range entanglement). Note that the monodromy defects discussed above are not finite-energy excitations in the spectrum of the Hamiltonian, but defects created by modifying the Hamiltonian.

Examples edit

The first example of SPT order is the Haldane phase of odd-integer spin chain.[10][11][12][13][14] It is a SPT phase protected by SO(3) spin rotation symmetry.[1] Note that Haldane phases of even-integer-spin chain do not have SPT order. A more well known example of SPT order is the topological insulator of non-interacting fermions, a SPT phase protected by U(1) and time reversal symmetry.

On the other hand, fractional quantum Hall states are not SPT states. They are states with (intrinsic) topological order and long-range entanglements.

Group cohomology theory for SPT phases edit

Using the notion of quantum entanglement, one obtains the following general picture of gapped phases at zero temperature. All gapped zero-temperature phases can be divided into two classes: long-range entangled phases (ie phases with intrinsic topological order) and short-range entangled phases (ie phases with no intrinsic topological order). All short-range entangled phases can be further divided into three classes: symmetry-breaking phases, SPT phases, and their mix (symmetry breaking order and SPT order can appear together).

It is well known that symmetry-breaking orders are described by group theory. For bosonic SPT phases with pure gauge anomalous boundary, it was shown that they are classified by group cohomology theory:[15][16] those (d+1)D SPT states with symmetry G are labeled by the elements in group cohomology class  . For other (d+1)D SPT states[17] [18] [19] [20] with mixed gauge-gravity anomalous boundary, they can be described by  ,[21] where   is the Abelian group formed by (d+1)D topologically ordered phases that have no non-trivial topological excitations (referred as iTO phases).

From the above results, many new quantum states of matter are predicted, including bosonic topological insulators (the SPT states protected by U(1) and time-reversal symmetry) and bosonic topological superconductors (the SPT states protected by time-reversal symmetry), as well as many other new SPT states protected by other symmetries.

A list of bosonic SPT states from group cohomology   (  = time-reversal-symmetry group)

symmetry group 1+1D 2+1D 3+1D 4+1D comment
          iTO phases with no symmetry:  
          bosonic topological insulator
          bosonic topological superconductor
         
          2+1D: quantum Hall effect
          1+1D: odd-integer-spin chain; 2+1D: spin Hall effect
         
         

The phases before "+" come from  . The phases after "+" come from  . Just like group theory can give us 230 crystal structures in 3+1D, group cohomology theory can give us various SPT phases in any dimensions with any on-site symmetry groups.

On the other hand, the fermionic SPT orders are described by group super-cohomology theory.[22] So the group (super-)cohomology theory allows us to construct many SPT orders even for interacting systems, which include interacting topological insulator/superconductor.

A complete classification of 1D gapped quantum phases (with interactions) edit

Using the notions of quantum entanglement and SPT order, one can obtain a complete classification of all 1D gapped quantum phases.

First, it is shown that there is no (intrinsic) topological order in 1D (ie all 1D gapped states are short-range entangled).[23] Thus, if the Hamiltonians have no symmetry, all their 1D gapped quantum states belong to one phase—the phase of trivial product states. On the other hand, if the Hamiltonians do have a symmetry, their 1D gapped quantum states are either symmetry-breaking phases, SPT phases, and their mix.

Such an understanding allows one to classify all 1D gapped quantum phases:[15][24][25][26][27] All 1D gapped phases are classified by the following three mathematical objects:   , where   is the symmetry group of the Hamiltonian,   the symmetry group of the ground states, and   the second group cohomology class of  . (Note that   classifies the projective representations of  .) If there is no symmetry breaking (ie  ), the 1D gapped phases are classified by the projective representations of symmetry group  .

See also edit

References edit

  1. ^ a b c Gu, Zheng-Cheng; Wen, Xiao-Gang (26 October 2009). "Tensor-entanglement-filtering renormalization approach and symmetry-protected topological order". Physical Review B. 80 (15): 155131. arXiv:0903.1069. Bibcode:2009PhRvB..80o5131G. doi:10.1103/physrevb.80.155131. ISSN 1098-0121. S2CID 15114579.
  2. ^ Pollmann, Frank; Berg, Erez; Turner, Ari M.; Oshikawa, Masaki (22 February 2012). "Symmetry protection of topological phases in one-dimensional quantum spin systems". Physical Review B. 85 (7): 075125. arXiv:0909.4059. Bibcode:2012PhRvB..85g5125P. doi:10.1103/physrevb.85.075125. ISSN 1098-0121. S2CID 53135907.
  3. ^ Wen, Xiao-Gang (9 August 2013). "Classifying gauge anomalies through symmetry-protected trivial orders and classifying gravitational anomalies through topological orders". Physical Review D. 88 (4): 045013. arXiv:1303.1803. Bibcode:2013PhRvD..88d5013W. doi:10.1103/physrevd.88.045013. ISSN 1550-7998. S2CID 18250786.
  4. ^ Levin, Michael; Gu, Zheng-Cheng (10 September 2012). "Braiding statistics approach to symmetry-protected topological phases". Physical Review B. 86 (11): 114109. arXiv:1202.3120. Bibcode:2012PhRvB..86k5109L. doi:10.1103/physrevb.86.115109. ISSN 1098-0121. S2CID 118688476.
  5. ^ Wen, Xiao-Gang (31 January 2014). "Symmetry-protected topological invariants of symmetry-protected topological phases of interacting bosons and fermions". Physical Review B. 89 (3): 035147. arXiv:1301.7675. Bibcode:2014PhRvB..89c5147W. doi:10.1103/physrevb.89.035147. ISSN 1098-0121. S2CID 55842699.
  6. ^ Lu, Yuan-Ming; Vishwanath, Ashvin (14 September 2012). "Theory and classification of interacting integer topological phases in two dimensions: A Chern-Simons approach". Physical Review B. 86 (12): 125119. arXiv:1205.3156. Bibcode:2012PhRvB..86l5119L. doi:10.1103/physrevb.86.125119. ISSN 1098-0121. S2CID 86856666.
  7. ^ Liu, Zheng-Xin; Mei, Jia-Wei; Ye, Peng; Wen, Xiao-Gang (24 December 2014). "U(1)×U(1)symmetry-protected topological order in Gutzwiller wave functions". Physical Review B. 90 (23): 235146. arXiv:1408.1676. Bibcode:2014PhRvB..90w5146L. doi:10.1103/physrevb.90.235146. ISSN 1098-0121. S2CID 14800302.
  8. ^ Liu, Zheng-Xin; Wen, Xiao-Gang (7 February 2013). "Symmetry-Protected Quantum Spin Hall Phases in Two Dimensions". Physical Review Letters. 110 (6): 067205. arXiv:1205.7024. Bibcode:2013PhRvL.110f7205L. doi:10.1103/physrevlett.110.067205. ISSN 0031-9007. PMID 23432300. S2CID 12995741.
  9. ^ One should also note the semantical subtleness of the name SPT: "symmetry protected" does not mean that the stability of the state is conserved "because of the symmetry", but it is just meant that the symmetry is kept by the interactions corresponding to the process.
  10. ^ Haldane, F. D. M. (11 April 1983). "Nonlinear Field Theory of Large-Spin Heisenberg Antiferromagnets: Semiclassically Quantized Solitons of the One-Dimensional Easy-Axis Néel State". Physical Review Letters. 50 (15). American Physical Society (APS): 1153–1156. Bibcode:1983PhRvL..50.1153H. doi:10.1103/physrevlett.50.1153. ISSN 0031-9007.
  11. ^ Haldane, F.D.M. (1983). "Continuum dynamics of the 1-D Heisenberg antiferromagnet: Identification with the O(3) nonlinear sigma model". Physics Letters A. 93 (9). Elsevier BV: 464–468. Bibcode:1983PhLA...93..464H. doi:10.1016/0375-9601(83)90631-x. ISSN 0375-9601.
  12. ^ Affleck, Ian; Haldane, F. D. M. (1 September 1987). "Critical theory of quantum spin chains". Physical Review B. 36 (10). American Physical Society (APS): 5291–5300. Bibcode:1987PhRvB..36.5291A. doi:10.1103/physrevb.36.5291. ISSN 0163-1829. PMID 9942166.
  13. ^ Affleck, I (15 May 1989). "Quantum spin chains and the Haldane gap". Journal of Physics: Condensed Matter. 1 (19). IOP Publishing: 3047–3072. Bibcode:1989JPCM....1.3047A. doi:10.1088/0953-8984/1/19/001. ISSN 0953-8984. S2CID 250850599.
  14. ^ Mishra, Shantanu; Catarina, Gonçalo; Wu, Fupeng; Ortiz, Ricardo; Jacob, David; Eimre, Kristjan; Ma, Ji; Pignedoli, Carlo A.; Feng, Xinliang; Ruffieux, Pascal; Fernández-Rossier, Joaquín; Fasel, Roman (13 October 2021). "Observation of fractional edge excitations in nanographene spin chains". Nature. 598 (7880): 287–292. arXiv:2105.09102. Bibcode:2021Natur.598..287M. doi:10.1038/s41586-021-03842-3. PMID 34645998. S2CID 234777902.
  15. ^ a b Chen, Xie; Liu, Zheng-Xin; Wen, Xiao-Gang (22 December 2011). "Two-dimensional symmetry-protected topological orders and their protected gapless edge excitations". Physical Review B. 84 (23): 235141. arXiv:1106.4752. Bibcode:2011PhRvB..84w5141C. doi:10.1103/physrevb.84.235141. ISSN 1098-0121. S2CID 55330505.
  16. ^ Chen, Xie; Gu, Zheng-Cheng; Liu, Zheng-Xin; Wen, Xiao-Gang (4 April 2013). "Symmetry protected topological orders and the group cohomology of their symmetry group". Physical Review B. 87 (15): 155114. arXiv:1106.4772. Bibcode:2013PhRvB..87o5114C. doi:10.1103/physrevb.87.155114. ISSN 1098-0121. S2CID 118546600.
  17. ^ Vishwanath, Ashvin; Senthil, T. (28 February 2013). "Physics of Three-Dimensional Bosonic Topological Insulators: Surface-Deconfined Criticality and Quantized Magnetoelectric Effect". Physical Review X. 3 (1): 011016. arXiv:1209.3058. Bibcode:2013PhRvX...3a1016V. doi:10.1103/physrevx.3.011016. ISSN 2160-3308.
  18. ^ Anton Kapustin, "Symmetry Protected Topological Phases, Anomalies, and Cobordisms: Beyond Group Cohomology" arXiv:1403.1467
  19. ^ Wang, Juven C.; Gu, Zheng-Cheng; Wen, Xiao-Gang (22 January 2015). "Field-Theory Representation of Gauge-Gravity Symmetry-Protected Topological Invariants, Group Cohomology, and Beyond". Physical Review Letters. 114 (3): 031601. arXiv:1405.7689. Bibcode:2015PhRvL.114c1601W. doi:10.1103/physrevlett.114.031601. ISSN 0031-9007. PMID 25658993. S2CID 2370407.
  20. ^ Kapustin, Anton; Thorngren, Ryan; Turzillo, Alex; Wang, Zitao (2015). "Fermionic symmetry protected topological phases and cobordisms". Journal of High Energy Physics. 2015 (12): 1–21. arXiv:1406.7329. Bibcode:2015JHEP...12..052K. doi:10.1007/jhep12(2015)052. ISSN 1029-8479. S2CID 42613274.
  21. ^ Wen, Xiao-Gang (4 May 2015). "Construction of bosonic symmetry-protected-trivial states and their topological invariants via G×SO(∞) nonlinear σ models". Physical Review B. 91 (20): 205101. arXiv:1410.8477. Bibcode:2015PhRvB..91t5101W. doi:10.1103/physrevb.91.205101. ISSN 1098-0121. S2CID 13950401.
  22. ^ Gu, Zheng-Cheng; Wen, Xiao-Gang (23 September 2014). "Symmetry-protected topological orders for interacting fermions: Fermionic topological nonlinear σ models and a special group supercohomology theory". Physical Review B. 90 (11): 115141. arXiv:1201.2648. Bibcode:2014PhRvB..90k5141G. doi:10.1103/physrevb.90.115141. ISSN 1098-0121. S2CID 119307777.
  23. ^ Verstraete, F.; Cirac, J. I.; Latorre, J. I.; Rico, E.; Wolf, M. M. (14 April 2005). "Renormalization-Group Transformations on Quantum States". Physical Review Letters. 94 (14): 140601. arXiv:quant-ph/0410227. Bibcode:2005PhRvL..94n0601V. doi:10.1103/physrevlett.94.140601. ISSN 0031-9007. PMID 15904055. S2CID 21362387.
  24. ^ Chen, Xie; Gu, Zheng-Cheng; Wen, Xiao-Gang (13 January 2011). "Classification of gapped symmetric phases in one-dimensional spin systems". Physical Review B. 83 (3): 035107. arXiv:1008.3745. Bibcode:2011PhRvB..83c5107C. doi:10.1103/physrevb.83.035107. ISSN 1098-0121. S2CID 9139955.
  25. ^ Turner, Ari M.; Pollmann, Frank; Berg, Erez (8 February 2011). "Topological phases of one-dimensional fermions: An entanglement point of view". Physical Review B. 83 (7): 075102. arXiv:1008.4346. Bibcode:2011PhRvB..83g5102T. doi:10.1103/physrevb.83.075102. ISSN 1098-0121. S2CID 118491997.
  26. ^ Fidkowski, Lukasz; Kitaev, Alexei (8 February 2011). "Topological phases of fermions in one dimension". Physical Review B. 83 (7). American Physical Society (APS): 075103. arXiv:1008.4138. Bibcode:2011PhRvB..83g5103F. doi:10.1103/physrevb.83.075103. ISSN 1098-0121. S2CID 1201670.
  27. ^ Schuch, Norbert; Pérez-García, David; Cirac, Ignacio (31 October 2011). "Classifying quantum phases using matrix product states and projected entangled pair states". Physical Review B. 84 (16): 165139. arXiv:1010.3732. Bibcode:2011PhRvB..84p5139S. doi:10.1103/physrevb.84.165139. ISSN 1098-0121. S2CID 74872240.

January 01, 1970
symmetry, protected, topological, order, this, article, technical, most, readers, understand, please, help, improve, make, understandable, experts, without, removing, technical, details, june, 2020, learn, when, remove, this, message, symmetry, protected, topo. This article may be too technical for most readers to understand Please help improve it to make it understandable to non experts without removing the technical details June 2020 Learn how and when to remove this message Symmetry protected topological SPT order 1 2 is a kind of order in zero temperature quantum mechanical states of matter that have a symmetry and a finite energy gap To derive the results in a most invariant way renormalization group methods are used leading to equivalence classes corresponding to certain fixed points 1 The SPT order has the following defining properties a distinct SPT states with a given symmetry cannot be smoothly deformed into each other without a phase transition if the deformation preserves the symmetry b however they all can be smoothly deformed into the same trivial product state without a phase transition if the symmetry is broken during the deformation The above definition works for both bosonic systems and fermionic systems which leads to the notions of bosonic SPT order and fermionic SPT order Using the notion of quantum entanglement we can say that SPT states are short range entangled states with a symmetry by contrast for long range entanglement see topological order which is not related to the famous EPR paradox Since short range entangled states have only trivial topological orders we may also refer the SPT order as Symmetry Protected Trivial order Contents 1 Characteristic properties 2 Relation between SPT order and intrinsic topological order 3 Examples 4 Group cohomology theory for SPT phases 5 A complete classification of 1D gapped quantum phases with interactions 6 See also 7 ReferencesCharacteristic properties editThe boundary effective theory of a non trivial SPT state always has pure gauge anomaly or mixed gauge gravity anomaly for the symmetry group 3 As a result the boundary of a SPT state is either gapless or degenerate regardless how we cut the sample to form the boundary A gapped non degenerate boundary is impossible for a non trivial SPT state If the boundary is a gapped degenerate state the degeneracy may be caused by spontaneous symmetry breaking and or intrinsic topological order Monodromy defects in non trivial 2 1D SPT states carry non trival statistics 4 and fractional quantum numbers 5 of the symmetry group Monodromy defects are created by twisting the boundary condition along a cut by a symmetry transformation The ends of such cut are the monodromy defects For example 2 1D bosonic Zn SPT states are classified by a Zn integer m One can show that n identical elementary monodromy defects in a Zn SPT state labeled by m will carry a total Zn quantum number 2m which is not a multiple of n 2 1D bosonic U 1 SPT states have a Hall conductance that is quantized as an even integer 6 7 2 1D bosonic SO 3 SPT states have a quantized spin Hall conductance 8 Relation between SPT order and intrinsic topological order editSPT states are short range entangled while topologically ordered states are long range entangled Both intrinsic topological order and also SPT order can sometimes have protected gapless boundary excitations The difference is subtle the gapless boundary excitations in intrinsic topological order can be robust against any local perturbations while the gapless boundary excitations in SPT order are robust only against local perturbations that do not break the symmetry So the gapless boundary excitations in intrinsic topological order are topologically protected while the gapless boundary excitations in SPT order are symmetry protected 9 We also know that an intrinsic topological order has emergent fractional charge emergent fractional statistics and emergent gauge theory In contrast a SPT order has no emergent fractional charge fractional statistics for finite energy excitations nor emergent gauge theory due to its short range entanglement Note that the monodromy defects discussed above are not finite energy excitations in the spectrum of the Hamiltonian but defects created by modifying the Hamiltonian Examples editThe first example of SPT order is the Haldane phase of odd integer spin chain 10 11 12 13 14 It is a SPT phase protected by SO 3 spin rotation symmetry 1 Note that Haldane phases of even integer spin chain do not have SPT order A more well known example of SPT order is the topological insulator of non interacting fermions a SPT phase protected by U 1 and time reversal symmetry On the other hand fractional quantum Hall states are not SPT states They are states with intrinsic topological order and long range entanglements Group cohomology theory for SPT phases editUsing the notion of quantum entanglement one obtains the following general picture of gapped phases at zero temperature All gapped zero temperature phases can be divided into two classes long range entangled phases ie phases with intrinsic topological order and short range entangled phases ie phases with no intrinsic topological order All short range entangled phases can be further divided into three classes symmetry breaking phases SPT phases and their mix symmetry breaking order and SPT order can appear together It is well known that symmetry breaking orders are described by group theory For bosonic SPT phases with pure gauge anomalous boundary it was shown that they are classified by group cohomology theory 15 16 those d 1 D SPT states with symmetry G are labeled by the elements in group cohomology class H d 1 G U 1 displaystyle H d 1 G U 1 nbsp For other d 1 D SPT states 17 18 19 20 with mixed gauge gravity anomalous boundary they can be described by k 1 d H k G i T O d 1 k displaystyle oplus k 1 d H k G iTO d 1 k nbsp 21 where i T O d 1 displaystyle iTO d 1 nbsp is the Abelian group formed by d 1 D topologically ordered phases that have no non trivial topological excitations referred as iTO phases From the above results many new quantum states of matter are predicted including bosonic topological insulators the SPT states protected by U 1 and time reversal symmetry and bosonic topological superconductors the SPT states protected by time reversal symmetry as well as many other new SPT states protected by other symmetries A list of bosonic SPT states from group cohomology H d 1 G U 1 k 1 d H k G i T O d 1 k displaystyle H d 1 G U 1 oplus k 1 d H k G iTO d 1 k nbsp Z 2 T displaystyle Z 2 T nbsp time reversal symmetry group symmetry group 1 1D 2 1D 3 1D 4 1D comment 0 displaystyle 0 nbsp 0 displaystyle 0 nbsp Z displaystyle Z nbsp 0 displaystyle 0 nbsp Z 2 displaystyle Z 2 nbsp iTO phases with no symmetry i T O d 1 displaystyle iTO d 1 nbsp U 1 Z 2 T displaystyle U 1 rtimes Z 2 T nbsp Z 2 displaystyle Z 2 nbsp Z 2 displaystyle Z 2 nbsp 2 Z 2 Z 2 displaystyle 2Z 2 Z 2 nbsp Z Z 2 Z displaystyle Z oplus Z 2 Z nbsp bosonic topological insulator Z 2 T displaystyle Z 2 T nbsp Z 2 displaystyle Z 2 nbsp 0 displaystyle 0 nbsp Z 2 Z 2 displaystyle Z 2 Z 2 nbsp 0 displaystyle 0 nbsp bosonic topological superconductor Z n displaystyle Z n nbsp 0 displaystyle 0 nbsp Z n displaystyle Z n nbsp 0 displaystyle 0 nbsp Z n Z n displaystyle Z n Z n nbsp U 1 displaystyle U 1 nbsp 0 displaystyle 0 nbsp Z displaystyle Z nbsp 0 displaystyle 0 nbsp Z Z displaystyle Z Z nbsp 2 1D quantum Hall effect S O 3 displaystyle SO 3 nbsp Z 2 displaystyle Z 2 nbsp Z displaystyle Z nbsp 0 displaystyle 0 nbsp Z 2 displaystyle Z 2 nbsp 1 1D odd integer spin chain 2 1D spin Hall effect S O 3 Z 2 T displaystyle SO 3 times Z 2 T nbsp 2 Z 2 displaystyle 2Z 2 nbsp Z 2 displaystyle Z 2 nbsp 3 Z 2 Z 2 displaystyle 3Z 2 Z 2 nbsp 2 Z 2 displaystyle 2Z 2 nbsp Z 2 Z 2 Z 2 T displaystyle Z 2 times Z 2 times Z 2 T nbsp 4 Z 2 displaystyle 4Z 2 nbsp 6 Z 2 displaystyle 6Z 2 nbsp 9 Z 2 Z 2 displaystyle 9Z 2 Z 2 nbsp 12 Z 2 2 Z 2 displaystyle 12Z 2 2Z 2 nbsp The phases before come from H d 1 G U 1 displaystyle H d 1 G U 1 nbsp The phases after come from k 1 d H k G i T O d 1 k displaystyle oplus k 1 d H k G iTO d 1 k nbsp Just like group theory can give us 230 crystal structures in 3 1D group cohomology theory can give us various SPT phases in any dimensions with any on site symmetry groups On the other hand the fermionic SPT orders are described by group super cohomology theory 22 So the group super cohomology theory allows us to construct many SPT orders even for interacting systems which include interacting topological insulator superconductor A complete classification of 1D gapped quantum phases with interactions editUsing the notions of quantum entanglement and SPT order one can obtain a complete classification of all 1D gapped quantum phases First it is shown that there is no intrinsic topological order in 1D ie all 1D gapped states are short range entangled 23 Thus if the Hamiltonians have no symmetry all their 1D gapped quantum states belong to one phase the phase of trivial product states On the other hand if the Hamiltonians do have a symmetry their 1D gapped quantum states are either symmetry breaking phases SPT phases and their mix Such an understanding allows one to classify all 1D gapped quantum phases 15 24 25 26 27 All 1D gapped phases are classified by the following three mathematical objects G H G PS H 2 G PS U 1 displaystyle G H G Psi H 2 G Psi U 1 nbsp where G H displaystyle G H nbsp is the symmetry group of the Hamiltonian G PS displaystyle G Psi nbsp the symmetry group of the ground states and H 2 G PS U 1 displaystyle H 2 G Psi U 1 nbsp the second group cohomology class of G PS displaystyle G Psi nbsp Note that H 2 G U 1 displaystyle H 2 G U 1 nbsp classifies the projective representations of G displaystyle G nbsp If there is no symmetry breaking ie G PS G H displaystyle G Psi G H nbsp the 1D gapped phases are classified by the projective representations of symmetry group G H displaystyle G H nbsp See also editAKLT Model Topological insulator Periodic table of topological invariants Quantum spin Hall effect Topological orderReferences edit a b c Gu Zheng Cheng Wen Xiao Gang 26 October 2009 Tensor entanglement filtering renormalization approach and symmetry protected topological order Physical Review B 80 15 155131 arXiv 0903 1069 Bibcode 2009PhRvB 80o5131G doi 10 1103 physrevb 80 155131 ISSN 1098 0121 S2CID 15114579 Pollmann Frank Berg Erez Turner Ari M Oshikawa Masaki 22 February 2012 Symmetry protection of topological phases in one dimensional quantum spin systems Physical Review B 85 7 075125 arXiv 0909 4059 Bibcode 2012PhRvB 85g5125P doi 10 1103 physrevb 85 075125 ISSN 1098 0121 S2CID 53135907 Wen Xiao Gang 9 August 2013 Classifying gauge anomalies through symmetry protected trivial orders and classifying gravitational anomalies through topological orders Physical Review D 88 4 045013 arXiv 1303 1803 Bibcode 2013PhRvD 88d5013W doi 10 1103 physrevd 88 045013 ISSN 1550 7998 S2CID 18250786 Levin Michael Gu Zheng Cheng 10 September 2012 Braiding statistics approach to symmetry protected topological phases Physical Review B 86 11 114109 arXiv 1202 3120 Bibcode 2012PhRvB 86k5109L doi 10 1103 physrevb 86 115109 ISSN 1098 0121 S2CID 118688476 Wen Xiao Gang 31 January 2014 Symmetry protected topological invariants of symmetry protected topological phases of interacting bosons and fermions Physical Review B 89 3 035147 arXiv 1301 7675 Bibcode 2014PhRvB 89c5147W doi 10 1103 physrevb 89 035147 ISSN 1098 0121 S2CID 55842699 Lu Yuan Ming Vishwanath Ashvin 14 September 2012 Theory and classification of interacting integer topological phases in two dimensions A Chern Simons approach Physical Review B 86 12 125119 arXiv 1205 3156 Bibcode 2012PhRvB 86l5119L doi 10 1103 physrevb 86 125119 ISSN 1098 0121 S2CID 86856666 Liu Zheng Xin Mei Jia Wei Ye Peng Wen Xiao Gang 24 December 2014 U 1 U 1 symmetry protected topological order in Gutzwiller wave functions Physical Review B 90 23 235146 arXiv 1408 1676 Bibcode 2014PhRvB 90w5146L doi 10 1103 physrevb 90 235146 ISSN 1098 0121 S2CID 14800302 Liu Zheng Xin Wen Xiao Gang 7 February 2013 Symmetry Protected Quantum Spin Hall Phases in Two Dimensions Physical Review Letters 110 6 067205 arXiv 1205 7024 Bibcode 2013PhRvL 110f7205L doi 10 1103 physrevlett 110 067205 ISSN 0031 9007 PMID 23432300 S2CID 12995741 One should also note the semantical subtleness of the name SPT symmetry protected does not mean that the stability of the state is conserved because of the symmetry but it is just meant that the symmetry is kept by the interactions corresponding to the process Haldane F D M 11 April 1983 Nonlinear Field Theory of Large Spin Heisenberg Antiferromagnets Semiclassically Quantized Solitons of the One Dimensional Easy Axis Neel State Physical Review Letters 50 15 American Physical Society APS 1153 1156 Bibcode 1983PhRvL 50 1153H doi 10 1103 physrevlett 50 1153 ISSN 0031 9007 Haldane F D M 1983 Continuum dynamics of the 1 D Heisenberg antiferromagnet Identification with the O 3 nonlinear sigma model Physics Letters A 93 9 Elsevier BV 464 468 Bibcode 1983PhLA 93 464H doi 10 1016 0375 9601 83 90631 x ISSN 0375 9601 Affleck Ian Haldane F D M 1 September 1987 Critical theory of quantum spin chains Physical Review B 36 10 American Physical Society APS 5291 5300 Bibcode 1987PhRvB 36 5291A doi 10 1103 physrevb 36 5291 ISSN 0163 1829 PMID 9942166 Affleck I 15 May 1989 Quantum spin chains and the Haldane gap Journal of Physics Condensed Matter 1 19 IOP Publishing 3047 3072 Bibcode 1989JPCM 1 3047A doi 10 1088 0953 8984 1 19 001 ISSN 0953 8984 S2CID 250850599 Mishra Shantanu Catarina Goncalo Wu Fupeng Ortiz Ricardo Jacob David Eimre Kristjan Ma Ji Pignedoli Carlo A Feng Xinliang Ruffieux Pascal Fernandez Rossier Joaquin Fasel Roman 13 October 2021 Observation of fractional edge excitations in nanographene spin chains Nature 598 7880 287 292 arXiv 2105 09102 Bibcode 2021Natur 598 287M doi 10 1038 s41586 021 03842 3 PMID 34645998 S2CID 234777902 a b Chen Xie Liu Zheng Xin Wen Xiao Gang 22 December 2011 Two dimensional symmetry protected topological orders and their protected gapless edge excitations 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90 115141 ISSN 1098 0121 S2CID 119307777 Verstraete F Cirac J I Latorre J I Rico E Wolf M M 14 April 2005 Renormalization Group Transformations on Quantum States Physical Review Letters 94 14 140601 arXiv quant ph 0410227 Bibcode 2005PhRvL 94n0601V doi 10 1103 physrevlett 94 140601 ISSN 0031 9007 PMID 15904055 S2CID 21362387 Chen Xie Gu Zheng Cheng Wen Xiao Gang 13 January 2011 Classification of gapped symmetric phases in one dimensional spin systems Physical Review B 83 3 035107 arXiv 1008 3745 Bibcode 2011PhRvB 83c5107C doi 10 1103 physrevb 83 035107 ISSN 1098 0121 S2CID 9139955 Turner Ari M Pollmann Frank Berg Erez 8 February 2011 Topological phases of one dimensional fermions An entanglement point of view Physical Review B 83 7 075102 arXiv 1008 4346 Bibcode 2011PhRvB 83g5102T doi 10 1103 physrevb 83 075102 ISSN 1098 0121 S2CID 118491997 Fidkowski Lukasz Kitaev Alexei 8 February 2011 Topological phases of fermions in one dimension Physical Review B 83 7 American Physical Society APS 075103 arXiv 1008 4138 Bibcode 2011PhRvB 83g5103F doi 10 1103 physrevb 83 075103 ISSN 1098 0121 S2CID 1201670 Schuch Norbert Perez Garcia David Cirac Ignacio 31 October 2011 Classifying quantum phases using matrix product states and projected entangled pair states Physical Review B 84 16 165139 arXiv 1010 3732 Bibcode 2011PhRvB 84p5139S doi 10 1103 physrevb 84 165139 ISSN 1098 0121 S2CID 74872240 Retrieved from https en wikipedia org w index php title Symmetry protected topological order amp oldid 1114314319, wikipedia, wiki, book, books, library,

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