Theory of interacting topological crystalline insulators

Isobe, Hiroki; Fu, Liang

doi:10.1103/physrevb.92.081304

Cited by 118 publications

(133 citation statements)

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“…Remarkably, it implies a field-induced dimensional reduction [22] that will strongly enhance correlations hence the advent of the (quasi-) 1D system without electron quasiparticle excitations. This connects to the long-lasting search or application of the Tomonaga-Luttinger liquid (TLL) physics [23], including semiconductor quantum wires [24,25], singlewalled carbon nanotubes [26,27], edge states in fractional quantum Hall states [28,29] and 2D topological insulators [30,31], and so on.Because of the large cyclotron gap, it is expected and confirmed that the Dirac/Weyl semimetals can be driven to the quantum limit at lower magnetic fields than semiconductors [20]. Due to the instability from electron correlations, one possibility is the gap-opening or dynamical mass generation [32] in the nominally massless semimetal as density waves are formed [33].…”

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Tomonaga-Luttinger liquid and localization in Weyl semimetals

Zhang

Nagaosa

2017

Phys. Rev. B

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We study both noncentrosymmetric and time-reversal breaking Weyl semimetal systems under a strong magnetic field with the Coulomb interaction. The three-dimensional bulk system is reduced to many mutually interacting quasi-one-dimensional wires. Each strongly correlated wire can be approached within the Tomonaga-Luttinger liquid formalism. Including impurity scatterings, we inspect the localization effect and the temperature dependence of the electrical resistivity. The effect of a large number of Weyl points in real materials is also discussed.Introduction.-The realization of linear band crossings in three dimensions (3D) in the Weyl semimetals are sparking keen interests [1]. This lends credence to the concept of Weyl fermion [2] in the context of variou condensed matter systems [3,4]. In principle, any solid-state realization should bear time-reversal symmetry breaking (TRB) and/or inversion symmetry breaking (IB) [5][6][7][8][9] so as to lift the Kramers degeneracy and to generate nonzero Berry curvatures. The Weyl point is interesting as a 3D counterpart of the two-dimensional (2D) Dirac physics [10], which means topologically protected monopoles of the momentum-space Berry phase [11]. Among others, the chiral magnetic effect [12] as a result of the chiral anomaly [13][14][15][16] is observed as negative magnetoresistance in Dirac/Weyl semimetals [17,18] once the chiral imbalance of chemical potential is generated by parallel electric and magnetic fields.The intriguing facet of the magnetotransport in Dirac/Weyl semimetals mainly comes from the the unique Landau level formation dissimilar to that of quadratic electronic bands, where the lowest Landau level, a linearly dispersed chiral mode along the direction of the magnetic field, is well separated from the higher levels by a cyclotron gap ∝ √ B, whose 2D variant has been vastly explored in graphene [19]. A further stage is when the (ultra) quantum limit is achieved[20], enabling the lowest Landau level to play a major role in shaping the low-energy physics. In this limit, the magnetic length l B = 1/ √ eB (setting = 1) becomes shorter than the Fermi wavelength since the quantized orbit of electrons shrinks with an increasing B and the lowest Landau level possesses the majority of population [21]. Remarkably, it implies a field-induced dimensional reduction [22] that will strongly enhance correlations hence the advent of the (quasi-) 1D system without electron quasiparticle excitations. This connects to the long-lasting search or application of the Tomonaga-Luttinger liquid (TLL) physics [23], including semiconductor quantum wires [24,25], singlewalled carbon nanotubes [26,27], edge states in fractional quantum Hall states [28,29] and 2D topological insulators [30,31], and so on.Because of the large cyclotron gap, it is expected and confirmed that the Dirac/Weyl semimetals can be driven to the quantum limit at lower magnetic fields than semiconductors [20]. Due to the instability from electron correlations, one possibility is the gap-opening or dynamical m...

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confidence: 99%

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Tomonaga-Luttinger liquid and localization in Weyl semimetals

Zhang

Nagaosa

2017

Phys. Rev. B

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“…Since then, there have been several works which discuss the breakdown of the noninteracting classification in the presence of interactions [14][15][16][17][18][19][20][21][22][23][24][25].…”

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Many-Body Topological Invariants for Fermionic Symmetry-Protected Topological Phases

2017

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We define and compute many-body topological invariants of interacting fermionic symmetryprotected topological phases, protected by an orientation-reversing symmetry, such as time-reversal or reflection symmetry. The topological invariants are given by partition functions obtained by a path integral on unoriented spacetime which, as we show, can be computed for a given ground state wave function by considering a non-local operation, "partial" reflection or transpose. As an application of our scheme, we study the Z8 and Z16 classification of topological superconductors in one and three dimensions.The Thouless-Kohmoto-Nightingale-den Nijs (TKNN) formula [1, 2] is the prototype for topological characterization of phases of matter. It relates the quantized Hall conductance to the (first) Chern number defined for Bloch wave functions. At the level of many-body physics, the quantized Hall conductance can also be formulated in terms of ground state wave functions in the presence of twisted boundary conditions ("the many-body Chern number") [3]. In contrast to local order parameters, the TKNN integer distinguishes different quantum phases of matter by focusing on their global topological properties.More recently, the discovery of topological insulators and superconductors [4, 5] has led to a new research frontier, generally referred to as symmetry protected topological (SPT) phases. These phases are adiabatically connected to topologically trivial states, i.e., atomic insulators which can be represented as simple product states without any entanglement. Nevertheless, they are topologically distinct once a symmetry condition, e.g., timereversal symmetry, is imposed. A complete classification of the noninteracting fermionic SPT phases protected by non-spatial discrete symmetries [6][7][8], as well as crystalline SPT phases protected by spatial symmetries [9][10][11][12], were achieved.However, it was later discovered that the noninteracting topological classification is not the full story, and can be dramatically altered once interaction effects are taken into account [13]. Since then, there have been several works which discuss the breakdown of the noninteracting classification in the presence of interactions [14][15][16][17][18][19][20][21][22][23][24][25].There are various topological invariants for noninteracting fermionic SPT phases using single-particle states (e.g., Bloch wave functions). For example, the Z 2 -valued topological invariants have been introduced for topological insulators both in two and three spatial dimensions [26][27][28][29]. For topological superconductors protected by time-reversal symmetry, the integer-valued topological invariants ("the winding number") have been introduced [6]. However, the discovered breakdown of non-interacting classification clearly indicates that the situation at the interacting level is more intricate, and a general framework to distinguish interacting fermionic SPT phases is lacking. This should be contrasted from the quantized Hall conductance, which can be formulate...

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“…An important question then is whether the nontrivial TCIs predicted by band theories are stable under interactions, or, more precisely, whether these band-theory-based nontrivial TCIs can be smoothly connected to a trivial insulator once strong interactions are switched on (still in the presence of the relevant symmetries). Very recently, the stability of various such TCIs under interactions has been considered and some of them are shown to be unstable, by studying the anomalous surface properties of the TCIs, studying certain dimensionally reduced versions of the TCIs, or studying the formal field theories of the TCIs [20][21][22][23][24][25][26][27][28][29][30][31]. However, an important and interesting question has remained unanswered: how to characterize nontrivial interacting TCIs directly by their bulk properties in a physical way?…”

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confidence: 99%

Bulk characterization of topological crystalline insulators: Stability under interactions and relations to symmetry enriched U (1) quantum spin liquids

Zou

2018

Phys. Rev. B

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Topological crystalline insulators (TCIs) are nontrivial quantum phases of matter protected by crystalline (and other) symmetries. They are originally predicted by band theories, so an important question is their stability under interactions. In this paper, by directly studying the physical bulk properties of several band-theory-based nontrivial TCIs that are conceptually interesting and/or experimentally feasible, we show they are stable under interactions. These TCIs include (1) a weak topological insulator, (2) a TCI with a mirror symmetry and its time-reversal symmetric generalizations, (3) a doubled topological insulator with a mirror symmetry, and (4) two TCIs with symmetry-enforced-gapless surfaces. We describe two complementary methods that allow us to determine the properties of the magnetic monopoles obtained by coupling these TCIs to a U (1) gauge field. These methods involve studying different types of surface states of these TCIs. Applying these methods to our examples, we find all of them have nontrivial monopoles, which proves their stability under interactions. Furthermore, we discuss two levels of relations between these TCIs and symmetry enriched U (1) quantum spin liquids (QSLs). First, these TCIs are directly related to U (1) QSLs with crystalline symmetries. Second, there is an interesting correspondence between U (1) QSLs with crystalline symmetries and U (1) QSLs with internal symmetries. In particular, the TCIs with symmetry-enforced-gapless surfaces are related to the "fractional topological paramagnets" introduced in Zou et al. [arXiv:1710.00743].

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Theory of interacting topological crystalline insulators

Cited by 118 publications

References 51 publications

Tomonaga-Luttinger liquid and localization in Weyl semimetals

Tomonaga-Luttinger liquid and localization in Weyl semimetals

Many-Body Topological Invariants for Fermionic Symmetry-Protected Topological Phases

Bulk characterization of topological crystalline insulators: Stability under interactions and relations to symmetry enriched U (1) quantum spin liquids

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