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Article: Higher-order Dirac fermions in three dimensions

TitleHigher-order Dirac fermions in three dimensions
Authors
Issue Date2020
Citation
Physical Review B, 2020, v. 101, n. 20, article no. 205134 How to Cite?
AbstractRelativistic massless Weyl and Dirac fermions exhibit the isotropic and linear dispersion relations to preserve the Pioncaré symmetry, the most fundamental symmetry in high energy physics. In solids, the counterparts of the Pioncaré symmetry are crystallographic symmetries, and hence, it is natural to explore generalizations of Dirac and Weyl fermions compatible with their crystallographic symmetries and then the new physics coming along with them. Here, we study an important kind of generalization, namely massless Dirac fermions with higher-order dispersion relations protected by crystallographic symmetries in three-dimensional nonmagnetic systems. We perform a systematic search over all 230 space groups with time-reversal symmetry and spin-orbit coupling considered. We find that the order of dispersion cannot be higher than three, i.e., only the quadratic and cubic Dirac points (QDPs and CDPs) are possible. We discover previously unknown classes of higher-order Dirac points, including the chiral QDPs with Chern numbers of ±4 and the QDPs/CDPs without centrosymmetry. Especially the chiral QDPs feature four extensive surface Fermi arcs and four chiral Landau bands and hence leads to observable signatures in spectroscopic and transport experiments. We further show that these higher-order Dirac points represent parent phases for other exotic topological structures. Via controlled symmetry breaking, QDPs and CDPs can be transformed into double Weyl points, triple Weyl points, charge-2 Dirac points or Weyl loops. Using first-principles calculations, we also identify possible material candidates, including α-TeO2 and YRu4B4, which realize the predicted nodal structures.
Persistent Identifierhttp://hdl.handle.net/10722/335028
ISSN
2023 Impact Factor: 3.2
2023 SCImago Journal Rankings: 1.345
ISI Accession Number ID

 

DC FieldValueLanguage
dc.contributor.authorWu, Weikang-
dc.contributor.authorYu, Zhi Ming-
dc.contributor.authorZhou, Xiaoting-
dc.contributor.authorZhao, Y. X.-
dc.contributor.authorYang, Shengyuan A.-
dc.date.accessioned2023-10-24T08:28:34Z-
dc.date.available2023-10-24T08:28:34Z-
dc.date.issued2020-
dc.identifier.citationPhysical Review B, 2020, v. 101, n. 20, article no. 205134-
dc.identifier.issn2469-9950-
dc.identifier.urihttp://hdl.handle.net/10722/335028-
dc.description.abstractRelativistic massless Weyl and Dirac fermions exhibit the isotropic and linear dispersion relations to preserve the Pioncaré symmetry, the most fundamental symmetry in high energy physics. In solids, the counterparts of the Pioncaré symmetry are crystallographic symmetries, and hence, it is natural to explore generalizations of Dirac and Weyl fermions compatible with their crystallographic symmetries and then the new physics coming along with them. Here, we study an important kind of generalization, namely massless Dirac fermions with higher-order dispersion relations protected by crystallographic symmetries in three-dimensional nonmagnetic systems. We perform a systematic search over all 230 space groups with time-reversal symmetry and spin-orbit coupling considered. We find that the order of dispersion cannot be higher than three, i.e., only the quadratic and cubic Dirac points (QDPs and CDPs) are possible. We discover previously unknown classes of higher-order Dirac points, including the chiral QDPs with Chern numbers of ±4 and the QDPs/CDPs without centrosymmetry. Especially the chiral QDPs feature four extensive surface Fermi arcs and four chiral Landau bands and hence leads to observable signatures in spectroscopic and transport experiments. We further show that these higher-order Dirac points represent parent phases for other exotic topological structures. Via controlled symmetry breaking, QDPs and CDPs can be transformed into double Weyl points, triple Weyl points, charge-2 Dirac points or Weyl loops. Using first-principles calculations, we also identify possible material candidates, including α-TeO2 and YRu4B4, which realize the predicted nodal structures.-
dc.languageeng-
dc.relation.ispartofPhysical Review B-
dc.titleHigher-order Dirac fermions in three dimensions-
dc.typeArticle-
dc.description.naturelink_to_subscribed_fulltext-
dc.identifier.doi10.1103/PhysRevB.101.205134-
dc.identifier.scopuseid_2-s2.0-85085842624-
dc.identifier.volume101-
dc.identifier.issue20-
dc.identifier.spagearticle no. 205134-
dc.identifier.epagearticle no. 205134-
dc.identifier.eissn2469-9969-
dc.identifier.isiWOS:000533794000003-

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