Thermodynamic signature of Dirac electrons across a possible topological transition in 
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Nair, Nityan; Dumitrescu, Philipp T.; Channa, Sanyum; Griffin, Sinéad M.; Neaton, Jeffrey B.; Potter, Andrew C.; Analytis, James

doi:10.1103/physrevb.97.041111

Cited by 23 publications

(12 citation statements)

References 26 publications

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“…We also note that increasing temperature leads to the closure of the band gap of the material, with the formation of a hole pocket at the Γ point and an associated electron pocket elsewhere in the BZ. This temperature-dependent shift of the electronic bands is consistent with experimental reports 63 and has been connected to the resistivity anomaly in ZrTe 5 5,16,17,64,65 .…”

Section: Resultssupporting

confidence: 91%

Unraveling the topology of ZrTe5 by changing temperature

Monserrat

Narayan

2019

Phys. Rev. Research

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We study the effects of temperature on the topological nature of ZrTe5, which sits near the phase boundary between strong and weak topological insulating orders. Using first-principles calculations, we show that the band gap and the topological indices of ZrTe5 are extremely sensitive to thermal expansion, and that the electron-phonon interaction accounts for more than a third of the total temperature-dependent effects in ZrTe5. We find that the temperature dependence of the band gap has an opposite sign in the strong and weak topological insulator phases. Based on this insight, we propose a robust and unambiguous method to determine the topological nature of any given sample of ZrTe5: if the band gap decreases with temperature it is a strong topological insulator, and if it increases with temperature it is a weak topological insulator. An analogous strategy is expected to be generally applicable to other materials and to become particularly important in the vicinity of topological phase boundaries where other methods provide ambiguous results. arXiv:1909.07613v2 [cond-mat.mtrl-sci]

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Section: Resultssupporting

confidence: 91%

Unraveling the topology of ZrTe5 by changing temperature

Monserrat

Narayan

2019

Phys. Rev. Research

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“…The temperature of the resistivity maximum varied with sample thickness and doping [25][26][27]. Recently, this resistivity peak was also related to the potential topological properties of ZrTe 5 and interpreted as a signature for a transition upon cooling [28] from a WTI to an STI state [29] or the reverse [30], as well as a signature of Dirac polarons [31].…”

Section: Introductionmentioning

confidence: 99%

Optical conductivity and resistivity in a four-band model for ZrTe5 from ab initio calculations

et al. 2020

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ZrTe 5 is considered a potential candidate for either a Dirac semimetal or a topological insulator in close proximity to a topological phase transition. Recent optical conductivity results motivated a two-band model with a conical dispersion in 2D, in contrast to density-functional-theory calculations. Here, we reconcile the two by deriving a four-band model for ZrTe 5 using k • p theory, and fitting its parameters to the ab initio band structure. The optical conductivity with an adjusted electronic structure matches the key features of experimental data. The chemical potential varies strongly with temperature, to the point that it may cross the gap entirely between zero and room temperature. The temperature-dependent resistivity displays a broad peak and confirms theoretically the conclusions of recent experiments attributing the origin of the resistivity peak to the large shift of the chemical potential with temperature.

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“…1A) with Sb x>xc=0.07. Recently discovered three-dimensional (3D) Dirac semimetals also show a large diamagnetism of similar magnitude in the bulk magnetic susceptibility (15)(16)(17)(18), when their EF is located near the Dirac points.…”

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confidence: 99%

Giant orbital diamagnetism of three-dimensional Dirac electrons in Sr3PbO antiperovskite

et al. 2021

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In Dirac semimetals, inter-band mixing has been known theoretically to give rise to a giant orbital diamagnetism when the Fermi level is close to the Dirac point. In Bi1-xSbx and other Dirac semimetals, an enhanced diamagnetism in the magnetic susceptibility c has been observed and interpreted as a manifestation of such giant orbital diamagnetism. Experimentally proving their orbital origin, however, has remained challenging. Cubic antiperovskite Sr3PbO is a three-dimensional Dirac electron system and shows the giant diamagnetism in c as in the other Dirac semimetals. 207 Pb NMR measurements are conducted in this study to explore the microscopic origin of diamagnetism. From the analysis of the Knight shift K as a function of c and the relaxation rate T1 -1 for samples with different hole densities, the spin and the orbital components in K are successfully separated. The results establish that the enhanced diamagnetism in Sr3PbO originates

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Thermodynamic signature of Dirac electrons across a possible topological transition in ZrTe5

Cited by 23 publications

References 26 publications

Unraveling the topology of ZrTe5 by changing temperature

Unraveling the topology of ZrTe5 by changing temperature

Optical conductivity and resistivity in a four-band model for ZrTe5 from ab initio calculations

Giant orbital diamagnetism of three-dimensional Dirac electrons in Sr3PbO antiperovskite

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