Observation of nodal line in non-symmorphic topological semimetal InBi

Ekahana, Sandy Adhitia; Wu, Shu-Chun; Jiang, Juan; Okawa, Kenjiro; Prabhakaran, D.; Hwang, Choongyu; Mo, S.-K.; Sasagawa, T.; Felser, Claudia; Yan, Binghai; Liu, Zhongkai; Chen, Yulin

doi:10.1088/1367-2630/aa75a1

Cited by 63 publications

(44 citation statements)

References 59 publications

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“…However, the DNLs usu-ally reside far away from E F . For example, similar DNLs have been observed by ARPES in ZrSiS [33,34] and InBi [35], which are hundreds of meV away from the Fermi level. In contrast, the DNLs in IrO 2 cross the Fermi level, which provides an ideal platform to realize a possible application of DNLs.…”

Section: Methodssupporting

confidence: 71%

Strong spin-orbit coupling and Dirac nodal lines in the three-dimensional electronic structure of metallic rutile IrO2

Jiang

Shi

et al. 2019

Phys. Rev. B

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Using high-resolution angle-resolved photoemission spectroscopy and ab initio calculation, we have studied the bulk and surface electronic structure of metallic rutile 5d transition metal oxide IrO 2 that harbors both edge and corner sharing Ir-O octahedrons. We observe strong modulation of the band structure by spin-orbit coupling (SOC). The measured band structure is well reproduced by our ab initio calculation without band renormalization, suggesting the absence of the SOC-enhanced correlation effect in IrO 2. In accordance with the calculation, we visualize two types of Dirac nodal lines (DNLs) protected by mirror symmetry and nonsymmorphic crystal symmetry, respectively. SOC gaps the first type of DNLs, which may contribute largely to the strong spin Hall effect. The second type of DNLs at the edges of Brillouin zone, however, remain intact against SOC. Our results not only provide important insights into the exotic transport properties of IrO 2 , but also shed light on the understanding of the role of SOC in the iridate family.

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Section: Methodssupporting

confidence: 71%

Strong spin-orbit coupling and Dirac nodal lines in the three-dimensional electronic structure of metallic rutile IrO2

Jiang

Shi

et al. 2019

Phys. Rev. B

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“…However, such separation between the topological states and Fermi level is not a hinder to detection in experiments. For example, the topological states of nonsymmorphic topological semimetal InBi [29], NLSM ZrSiS [30] and Dirac nodal links materials TiB 2 [74] depart from the Fermi level larger than 0.5eV could be well resolved by ARPES through tuning the photon energy. Moreover, electric gating can routinely tune the Fermi level of the 2D systems with electron or hole doping.…”

Section: Resultsmentioning

confidence: 99%

“…In comparison with topological insulators [1,2], topological semimetals have gapless bulk states and topologically protected surface states. Up to now, the well-known topological semimetals include Dirac semimetals (DSMs) [3][4][5][6][7][8][9][10], Weyl semimetals (WSMs) [11][12][13][14][15][16][17][18][19][20][21], and node-line semimetals (NLSMs) [22][23][24][25][26][27][28][29][30]. For DSMs and WSMs, their nontrivial band crossing points distribute at separate k points in the Brillouin zone (BZ).…”

Section: Introductionmentioning

confidence: 99%

“…So far, three types of symmetry protected mechanisms for NLSMs have been proposed: (i) mirror reflection symmetry protected NSLMs [39,40]; (ii) NLSMs derives from combined protection of time reversal symmetry and space inversion symmetry [22,23,[41][42][43][44][45][46]; (iii) NLSMs determined by non-symmorphic space group with glide plane or screw axes symmetries [27,47]. Although many different crystalline symmetries can stabilize the NLSMs, few materials including pure Be [46], PbTaSe 2 [48], ZrSiS [30], PtSn 4 [49], InBi [29], and ZrSiSe/ZrSiTe [50] were experimentally verified as topological NLSMs by angle-resolved photoemission spectroscopy (ARPES). There are challenges to experimental realization and observation of NLSMs.…”

Section: Introductionmentioning

confidence: 99%

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New type of hybrid nodal line semimetal in Be₂Si

Wang

Zhou

et al. 2019

New J. Phys.

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Following Dirac and Weyl semimetals, nodal line semimetals represent a new type of topological semimetal and attracted extensive interest in modern condensed matter physics. Recently, a kind of hybrid nodal lines have been proposed (Zhang et al 2018 Phys.Rev. B 97 125143) and it mainly come from anisotropy interaction. Based on the first-principle calculations and k·p model, we predict a cubic Be 2 Si with topological nontrivial electronic states exhibiting fascinating type-I and type-II hybrid nodal line around Fermi level. Unexpectedly the low energy electronic states of Be 2 Si are isotropy in k x and k y directions and a new effective model has been proposed for the appearance of this new type hybrid nodal line. The four-fold degenerated type-I and type-II nodal points in the hybrid nodal lines along the high symmetry lines of Γ-K and Γ-X are protected by mirror reflection, time reversal and space inversion symmetry. The spin-orbit coupling effect only induces slight band gap in the hybrid nodal lines in Be 2 Si whose nontrivial nature remains. Moreover, the nontrivial hybrid nodal lines in Be 2 Si are robust to external strain. The results in present work indicate that Be 2 Si are promising candidates for future experimental studies of nontrivial topological semimetals and an excellent platform to study the interaction between the two types Dirac fermions.

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“…The nodal lines are predicted in many materials, such as HgCr 2 Se 4 [20], graphene networks [76], Cu 3 (Pd/Zn)N [77,78], SrIrO 3 [79,80], TlTaSe 2 [81], Ca 3 P 2 [82,83], CaTe [84], compressed black phosphorus [85], CaAg(P/As) [86], CaP 3 family [87], PdS monolayer [88], Zintl compounds [89], BaMX 3 (M=V, Nb and Ta, X=S, Se) [90], rare earth monopnictides [91], alkalineearth compounds [92][93][94], other carbon-based materials [69,95], and metallic rutile oxides XO 2 (X=Ir, Os, Rd) [96]. So far, the nodal lines have been verified in ZrSiS [97][98][99], PbTaSe 2 [100,101], InBi [102] and PtSn 4 [103] by ARPES.…”

Section: Topological Nodal-line Semimetalmentioning

confidence: 99%

Quantum transport in topological semimetals under magnetic fields (II)

Sun

2019

Front. Phys.

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We review our recent works on the quantum transport, mainly in topological semimetals and also in topological insulators, organized according to the strength of the magnetic field. At weak magnetic fields, we explain the negative magnetoresistance in topological semimetals and topological insulators by using the semiclassical equations of motion with the nontrivial Berry curvature. We show that the negative magnetoresistance can exist without the chiral anomaly. At strong magnetic fields, we establish theories for the quantum oscillations in topological Weyl, Dirac, and nodal-line semimetals. We propose a new mechanism of 3D quantum Hall effect, via the "wormhole" tunneling through the Weyl orbit formed by the Fermi arcs and Weyl nodes in topological semimetals. In the quantum limit at extremely strong magnetic fields, we find that an unexpected Hall resistance reversal can be understood in terms of the Weyl fermion annihilation. Additionally, in parallel magnetic fields, longitudinal resistance dips in the quantum limit can serve as signatures for topological insulators.

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Observation of nodal line in non-symmorphic topological semimetal InBi

Cited by 63 publications

References 59 publications

Strong spin-orbit coupling and Dirac nodal lines in the three-dimensional electronic structure of metallic rutile IrO2

Strong spin-orbit coupling and Dirac nodal lines in the three-dimensional electronic structure of metallic rutile IrO2

New type of hybrid nodal line semimetal in Be₂Si

Quantum transport in topological semimetals under magnetic fields (II)

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Observation of nodal line in non-symmorphic topological semimetal InBi

Cited by 63 publications

References 59 publications

Strong spin-orbit coupling and Dirac nodal lines in the three-dimensional electronic structure of metallic rutile IrO2

Strong spin-orbit coupling and Dirac nodal lines in the three-dimensional electronic structure of metallic rutile IrO2

New type of hybrid nodal line semimetal in Be2Si

Quantum transport in topological semimetals under magnetic fields (II)

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New type of hybrid nodal line semimetal in Be₂Si