Nodal lines in momentum space: topological invariants and recent realizations in photonic and other systems

Park, Haedong; Gao, Wenlong; Zhang, Xiao; Oh, Suhk Kun

doi:10.48550/arxiv.2201.06639

Cited by 3 publications

(4 citation statements)

References 167 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…computed over base loops encircling the nodal rings (which provides an effective Z 4 counting in each gap, see details below), and of the Z 2 monopole charge [49,76] when more than two bands must be considered (corresponding to the reduction of the Euler class to the Z 2 second Stiefel-Whitney class). This work thus fills these gaps by providing concrete minimal tight-binding models that can be readily used as a guide for the design of acoustic metamaterials [62,64], photonic crystals [63], electronic circuits [66], and optical traps for cold atoms [51,52].…”

Section: A General 3d Ansatzmentioning

confidence: 99%

“…Such Euler class models are increasingly becoming of importance and have for example been proposed to induce monopole-antimonople generation in quench setups [51], while the observation of this physical observable has just been reported in trapped-ion experiments [52]. In addition, the braiding and emerging of such non-Abelian charges and its relation to Euler class have also been inspiring pursuits in other experimental contexts that range from from phononic systems [53][54][55][56] and electronic systems [38,44,[57][58][59][60][61] to acoustic, photonic and electric circuit metamaterials [62][63][64][65][66].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Multi-gap topological conversion of Euler class via band-node braiding: minimal models, $PT$-linked nodal rings, and chiral heirs

Bouhon¹,

Slager²

2022

Preprint

View full text Add to dashboard Cite

The past few years have seen rapid progress in characterizing topological band structures using symmetry eigenvalue indicated methods. Recently, however, there has been increasing theoretical and experimental interest in multi-gap dependent topological phases that cannot be captured by this paradigm. These topologies arise by braiding band degeneracies that reside between different bands and carry non-Abelian charges due to the presence of either C2T or P T symmetry, culminating in different invariants such as Z-valued Euler class. Here, we present a universal formulation for Euler phases motivated by their homotopy classification that is related to the Skyrmion-profile of a single unit-vector in three-level systems, and that of two unit-vectors in four-level systems. In addition, upon employing the strategy of systematically building 3D models from a pair of sub-dimensional Euler phases, we show that phase transitions between any two inequivalent Euler phases are mediated by the presence of adjacent (in-gap) nodal rings linked with sub-gap nodal lines, forming trajectories corresponding to the braiding or debraiding of nodal points. The stability of the linked adjacent nodal rings is furthermore demonstrated to be indicated by an Euler class monopole charge matching with its Z-valued linking numbers. We finally also systematically address the conversion of Euler phases into descendant Chern phases upon breaking the C2T or P T symmetry. All the topological phases discussed in this work are corroborated with explicit minimal lattice models. These models can themselves directly serve as an extra impetus for experimental searches or be employed for theoretical studies, thereby underpinning the upcoming of this nascent pursuit.

show abstract

Section: A General 3d Ansatzmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multi-gap topological conversion of Euler class via band-node braiding: minimal models, $PT$-linked nodal rings, and chiral heirs

Bouhon¹,

Slager²

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…These emerge when energy bands become degenerate in the vicinity of the Fermi energy, giving rise to so-called band nodes, and they can feature non-trivial topological invariants, boundary signatures, and transport properties. Since the originally proposed Weyl and Dirac point degeneracies, various other types of band nodes have been proposed and studied: from nodal lines (NLs) [10][11][12][13][14] forming intricate linked, knotted, and intersecting structures [15][16][17][18][19], over nodal surfaces [20][21][22][23][24], to nodal points with degeneracies different from two (Weyl) and four (Dirac) [25][26][27][28]. In particular, three-fold degenerate points [29][30][31][32][33][34][35][36][37][38][39][40] [also called triply-degenerate nodal points, triple nodal points, or (for brevity) just triple points (TPs)] have been widely investigated, as they constitute a special intermediate between Weyl and Dirac semimetals.…”

Section: Introductionmentioning

confidence: 99%

Triple nodal points characterized by their nodal-line structure in all magnetic space groups

Lenggenhager¹,

Liu²,

Neupert³

et al. 2022

Preprint

View full text Add to dashboard Cite

We analyze triply degenerate nodal points [or triple points (TPs) for short] in energy bands of crystalline solids. Specifically, we focus on spinless band structures, i.e., when spin-orbit coupling is negligible, and consider TPs formed along high-symmetry lines in the momentum space by a crossing of three bands transforming according to a 1D and a 2D irreducible corepresentation (ICR) of the little co-group. The result is a complete classification of such TPs in all magnetic space groups, including the non-symmorphic ones, according to several characteristics of the nodal-line structure at and near the TP. We show that the classification of the presently studied TPs is exhausted by 13 magnetic point groups (MPGs) that can arise as the little co-group of a high-symmetry line and which support both 1D and 2D spinless ICRs. For 10 of the identified MPGs, the TP characteristics are uniquely determined without further information; in contrast, for the 3 MPGs containing sixfold rotation symmetry, two types of TPs are possible, depending on the choice of the crossing ICRs. The classification result for each of the 13 MPGs is illustrated with first-principles calculations of a concrete material candidate.

show abstract

“…Similarly, Euler class and non-trivial braiding was predicted in phononic systems [35][36][37][38] and electronic systems that are strained [25,39], that undergo a structural phase transition [40,41], or are submitted to an external magnetic field [42]. The most immediate playground for these uncharted topological phases of matter is however the context of metamaterials [43][44][45][46][47][48]. The non-Abelian topological charges were recently detected in one-dimensional (1D) electrical circuit metamaterials [43].…”

mentioning

confidence: 98%

Experimental observation of meronic topological acoustic Euler insulators

Jiang¹,

Bouhon²,

Wu³

et al. 2022

Preprint

View full text Add to dashboard Cite

We report on the experimental observation of a gapped nontrivial Euler topology in an acoustic metamaterial. The topological invariant in this case is the Euler class, which characterizes the twodimensional geometry of the acoustic Bloch wave function of multiple bands in the Brillouin zone-a feature that cannot be captured by conventional topological classification schemes. Starting from a carefully designed acoustic system, we retrieve a rich phase diagram that includes the gapped Euler phase on top of non-Abelian topological nodal phases. In particular we find that the gapped phase is characterized by a meron (half-skyrmion) type topology in which the cancellation of the orbital Zak phases by Zak phases of the bands contributes in forming the characterizing winding number of the acoustic bands. Using pump-probe techniques, we are able to extract the wave functions of the acoustic Bloch bands and demonstrate the non-trivial Euler topology via a direct observation of the meron geometry of these bands in the Brillouin zone, in addition to the detection of the acoustic bulk and edge dispersions. We finally observe a topological edge state in the gapped Euler phase which is a direct manifestation of the underlying cancellation of the Zak phases. These experimental features reveal the unprecedented topological Euler phase as well as setting a benchmark for probing acoustic wave function geometry in the Brillouin zone.

show abstract

Nodal lines in momentum space: topological invariants and recent realizations in photonic and other systems

Cited by 3 publications

References 167 publications

Multi-gap topological conversion of Euler class via band-node braiding: minimal models, $PT$-linked nodal rings, and chiral heirs

Multi-gap topological conversion of Euler class via band-node braiding: minimal models, $PT$-linked nodal rings, and chiral heirs

Triple nodal points characterized by their nodal-line structure in all magnetic space groups

Experimental observation of meronic topological acoustic Euler insulators

Contact Info

Product

Resources

About