Weyl semimetal phase in the non-centrosymmetric compound TaAs

Yang, Lexian; Liu, Z. K.; Sun, Yan; Han, Peng; Yang, Haifeng; Zhang, T.; Zhou, Bo; Zhang, Y.; Guo, Yanfeng; Rahn, M. C.; Prabhakaran, D.; Hussain, Zahid; Felser, Claudia; Chen, Y. L.

doi:10.1038/nphys3425

Cited by 912 publications

(899 citation statements)

References 36 publications

Supporting

Mentioning

865

Contrasting

Unclassified

Order By: Relevance

“…On the surface of a Weyl semimetal, the Fermi surface consists of open arcs connecting the projection of bulk Weyl points onto the surface Brillouin zone [2], instead of closed loops. The presence of Fermi arcs on the surface is a remarkable property that directly reflects the nontrivial topology of the bulk, and plays a key role in the experimental identification of Weyl semimetals [32,33,36]. In contrast, as shown by recent theoretical works [18,21,23,24,28,48,49], existing Dirac and nodal line semimetals do not have robust Fermi arcs that are stable against symmetry-allowed perturbations.…”

Section: Introductionmentioning

confidence: 94%

“…The nontrivial topology gives rise to anomalous bulk properties of topological semimetals such as the chiral anomaly [3][4][5]. Several classes of topological semimetals have been theoretically proposed so far, including Weyl, [2,[6][7][8][9][10][11][12][13], Dirac [14][15][16][17] and nodal line semimetals [7,[17][18][19][20][21][22][23][24][25][26][27][28][29][30], some among which have been experimentally observed [31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47].Surface states of topological semimetals have attracted much attention. On the surface of a Weyl semimetal, the Fermi surface consists of open ar...…”

mentioning

confidence: 99%

See 1 more Smart Citation

Topological semimetals with helicoid surface states

et al. 2016

View full text Add to dashboard Cite

Riemann surfaces are geometric constructions in complex analysis that may represent multi-valued holomorphic functions using multiple sheets of the complex plane. We show that the energy dispersion of surface states in topological semimetals can be represented by Riemann surfaces generated by holomorphic functions in the two-dimensional momentum space, whose constant height contours correspond to Fermi arcs. This correspondence is demonstrated in the recently discovered Weyl semimetals and leads us to predict new types of topological semimetals, whose surface states are represented by double-and quad-helicoid Riemann surfaces. The intersection of multiple helicoids, or the branch cut of the generating function, appears on high-symmetry lines in the surface Brillouin zone, where surface states are guaranteed to be doubly degenerate by a glide reflection symmetry. We predict the heterostructure superlattice [(SrIrO3)2(CaIrO3)2] to be a topological semimetal with double-helicoid Riemann surface states.Introduction The study of topological semimetals [1] has seen rapid progress since the theoretical proposal of a three-dimensional Weyl semimetal in a magnetic phase of pyrochlore iridates [2]. In general, topological semimetals are materials where the conduction and the valence bands cross in the Brillouin zone and the crossing cannot be removed by perturbations preserving certain crystalline symmetry such as the lattice translation. Bloch states in the vicinity of the band crossing possess a nonzero topological index, e.g., the Chern number in case of Weyl semimetals. The nontrivial topology gives rise to anomalous bulk properties of topological semimetals such as the chiral anomaly [3][4][5]. Several classes of topological semimetals have been theoretically proposed so far, including Weyl, [2,[6][7][8][9][10][11][12][13], Dirac [14][15][16][17] and nodal line semimetals [7,[17][18][19][20][21][22][23][24][25][26][27][28][29][30], some among which have been experimentally observed [31][32][33][34][35][36][37][38][39][40][41][42][43][44][45][46][47].Surface states of topological semimetals have attracted much attention. On the surface of a Weyl semimetal, the Fermi surface consists of open arcs connecting the projection of bulk Weyl points onto the surface Brillouin zone [2], instead of closed loops. The presence of Fermi arcs on the surface is a remarkable property that directly reflects the nontrivial topology of the bulk, and plays a key role in the experimental identification of Weyl semimetals [32,33,36]. In contrast, as shown by recent theoretical works [18,21,23,24,28,48,49], existing Dirac and nodal line semimetals do not have robust Fermi arcs that are stable against symmetry-allowed perturbations. Therefore, the general condition for protected Fermi arcs and their existence in topological semimetals beyond Weyl remain open questions.In this work, we report the discovery of a new topological semimetal phase in a wide variety of nonsymmorphic crystal structures with the glide reflection sym-

show abstract

Section: Introductionmentioning

confidence: 94%

mentioning

confidence: 99%

Topological semimetals with helicoid surface states

et al. 2016

View full text Add to dashboard Cite

show abstract

“…The prediction and discovery of topological insulators (TIs) [1][2][3][4][5][6][7][8][9][10][11][12][13] have triggered the quest for other classes of materials that host exotic quantum states, such as topological superconductors [14][15][16] and Weyl [17][18][19][20][21], Dirac [22][23][24][25][26], and nodal-line [27,28] semimetals. Similar to TIs, topological superconductors (TSCs) are characterized by a full paring gap in the bulk and topologically protected gapless states on the edge or surface that can support massless Majorana fermions [14,15,[29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Evolution of the topologically protected surface states in superconductorβ-Bi₂Pd from the three-dimensional to the two-dimensional limit

Wang

Margine

2017

J. Phys.: Condens. Matter

View full text Add to dashboard Cite

The recent discovery of topologically protected surface states in the noncentrosymmetric α-BiPd and the centrosymmetric β-Bi2Pd has renewed the interest in the Bi-Pd family of superconductors. Here, we employ first-principles calculations to investigate the structure, electronic, and topological features of β-Bi2Pd, in bulk and in thin films of various thicknesses. We find that the Van der Waals dispersion corrections are important for reproducing the experimental structural parameters, while the spin-orbit interaction is critical for properly describing the appearance of topological electronic states. By increasing the thickness of the slab, the Dirac-cone surface states and the Rashba-type surface states gradually emerge at 9 and 11 triple-layers.

show abstract

“…In the 1980s, topology entered with the discovery of the quantum Hall effect. These ideas came together in the mid-2000s to unveil broad applications to electronic systems in the form of topological insulators, superconductors [3,4] and semimetals with topological Weyl (and other) fermion excitations [5][6][7][8][9][10][11][12][13][14][15][16][17][18]. The AHE re-appears as one of the key emergent properties of topological semimetals, and coming full circle, most ferromagnets are now believed to host Weyl fermions to which their AHE is at least in part attributed.…”

Section: Pacs Numbersmentioning

confidence: 99%

Anomalous Hall Effect and Topological Defects in Antiferromagnetic Weyl Semimetals: Mn3Sn/Ge

2017

View full text Add to dashboard Cite

We theoretically study the interplay between bulk Weyl electrons and magnetic topological defects, including magnetic domains, domain walls, and Z6 vortex lines, in the antiferromagnetic Weyl semimetals Mn3Sn and Mn3Ge with negative vector chirality. We argue that these materials possess a hierarchy of energies scales which allows a description of the spin structure and spin dynamics using a XY model with Z6 anisotropy. We propose a dynamical equation of motion for the XY order parameter, which implies the presence of Z6 vortex lines, the double-domain pattern in the presence of magnetic fields, and the ability to control domains with current. We also introduce a minimal electronic model which allows efficient calculation of the electronic structure in the antiferromagnetic configuration, unveiling Fermi arcs at domain walls, and sharp quasi-bound states at Z6 vortices. Moreover, we have shown how these materials may allow electronic-based imaging of antiferromagnetic microstructure, and propose a possible device based on domain-dependent anomalous Hall effect. PACS numbers:The Hall effect has long been a nucleation center for geometry and topology in the physics of solids. In the 1950s, prescient work of Karplus and Luttinger identified Berry curvature of electron wavefunctions as the heart of the anomalous Hall effect (AHE) in ferromagnets [1,2]. In the 1980s, topology entered with the discovery of the quantum Hall effect. These ideas came together in the mid-2000s to unveil broad applications to electronic systems in the form of topological insulators, superconductors [3,4] and semimetals with topological Weyl (and other) fermion excitations [5][6][7][8][9][10][11][12][13][14][15][16][17][18]. The AHE re-appears as one of the key emergent properties of topological semimetals, and coming full circle, most ferromagnets are now believed to host Weyl fermions to which their AHE is at least in part attributed.The dissipationless nature of the Hall effect also makes it interesting for applications. Uses based on ferromagnets may, however, be limited by the difficulty of miniaturization posed by large fields generated by the magnetization. For this reason, antiferromagnetic realizations of AHE may be of practical interest, but the microstructure, dynamics, and AHE of antiferromagnets are relatively uninvestigated. Here we attack these issues in the family of noncollinear antiferromagnets including Mn 3 Sn and Mn 3 Ge, for which a strong AHE was predicted and then experimentally verified to exist [19][20][21]. First principles calculations further indicate that in Mn 3 Sn and Mn 3 Ge there are Weyl nodes around the Fermi level [22,23]. We argue that these materials possess a hierarchy of energies scales which permits a description of the microstructure and spin dynamics as an XY model with Z 6 anisotropy. We propose a dynamical equation of motion for the XY order parameter, which implies a rich domain structure, the presence of Z 6 vortex lines, and the ability to control domains with current. We further introduce a ...

show abstract

Weyl semimetal phase in the non-centrosymmetric compound TaAs

Abstract: . This discovery not only confirms TaAs as a 3D TWS, but also provides an ideal platform for realizing exotic physical phenomena (for example, negative magnetoresistance, chiral magnetic e ects and the quantum anomalous Hall e ect) which may also lead to novel future applications.

Cited by 912 publications

References 36 publications

Topological semimetals with helicoid surface states

Topological semimetals with helicoid surface states

Evolution of the topologically protected surface states in superconductorβ-Bi₂Pd from the three-dimensional to the two-dimensional limit

Anomalous Hall Effect and Topological Defects in Antiferromagnetic Weyl Semimetals: Mn3Sn/Ge

Contact Info

Product

Resources

About

Weyl semimetal phase in the non-centrosymmetric compound TaAs

Abstract: . This discovery not only confirms TaAs as a 3D TWS, but also provides an ideal platform for realizing exotic physical phenomena (for example, negative magnetoresistance, chiral magnetic e ects and the quantum anomalous Hall e ect) which may also lead to novel future applications.

Cited by 912 publications

References 36 publications

Topological semimetals with helicoid surface states

Topological semimetals with helicoid surface states

Evolution of the topologically protected surface states in superconductorβ-Bi2Pd from the three-dimensional to the two-dimensional limit

Anomalous Hall Effect and Topological Defects in Antiferromagnetic Weyl Semimetals: Mn3Sn/Ge

Contact Info

Product

Resources

About

Evolution of the topologically protected surface states in superconductorβ-Bi₂Pd from the three-dimensional to the two-dimensional limit