Ideal Weyl semimetal induced by magnetic exchange

Soh, Jian-Rui; Juan, Fernando de; Vergniory, Maia G.; Schröter, Niels B. M.; Rahn, M. C.; Yan, Dayu; Jiang, Juan; Bristow, Matthew; Reiss, Pascal; Blandy, Jack N.; Guo, Yanfeng; Shi, Youguo; Kim, T. K.; McCollam, A.; Simon, Steven H.; Chen, Y.; Coldea, A. I.; Boothroyd, A. T.

doi:10.1103/physrevb.100.201102

Cited by 155 publications

(79 citation statements)

References 36 publications

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“…We are confident that the conductance scaling uncovered in this work can be observed in experiment, considering the recent efforts in manufacturing microstructured Weyl semimetals [38], creating strain-induced fields in type-II Weyl semimetals [39], and transport experiments in Dirac nanowires [40,41]. As our results rely on time-reversal symmetry-breaking materials, magneticexchange induced Weyl semimetals [42,43] are promising platforms for experiments. We have uncovered the conditions necessary to observe the unusual scaling of the conductivity: The sample's width needs to be larger than the magnetic length, and the sample's length in transport direction needs to be larger than the mean free path.…”

supporting

confidence: 60%

Anomalous conductance scaling in strained Weyl semimetals

Behrends

Ilan

Bardarson

2019

Phys. Rev. Research

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Magnetotransport provides key experimental signatures in Weyl semimetals. The longitudinal magnetoresistance is linked to the chiral anomaly, and the transversal magnetoresistance to the dominant charge relaxation mechanism. Axial magnetic fields that act with opposite sign on opposite chiralities facilitate new transport experiments that probe the low-energy Weyl nodes. As recently realized, these axial fields can be achieved by straining samples or adding inhomogeneities to them. Here, we identify a robust signature of axial magnetic fields: an anomalous scaling of the conductance in the diffusive ultraquantum regime. In particular, we demonstrate that the longitudinal conductivity in the ultraquantum regime of a disordered Weyl semimetal subjected to an axial magnetic field increases with both the field strength and sample width due to a spatial separation of charge carriers. We contrast axial magnetic with real magnetic fields to clearly distinguish the different behavior of the conductance. Our results rely on numerical tight-binding simulations and are supported by analytical arguments. We argue that the spatial separation of charge carriers can be used for directed currents in microstructured electronic devices. arXiv:1906.08277v1 [cond-mat.mes-hall]

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supporting

confidence: 60%

Anomalous conductance scaling in strained Weyl semimetals

Behrends

Ilan

Bardarson

2019

Phys. Rev. Research

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“…The space-resolved peak structure of the nonlocal conductance which indicates the trajectory of negative refraction can serve as unique evidence of the Fermi arc states. Recent progress on Weyl semimetals with a single pair of Weyl nodes in MnBi 2 Te 4 [42] and EuCd 2 As 2 [43,44] paves the way for the realization of our proposal. Furthermore, the manipulation of the negative refraction process offers potential applications of a Weyl semimetal nanowire as a field-effect transistor [40].…”

Section: Discussionmentioning

confidence: 93%

“…In reality, there are only a few material candidates for Weyl semimetals with only two Weyl points [42][43][44]. Hence, we investigate negative refraction between the surface states of T -symmetric Weyl semimetals, which are more abundant [12][13][14][15][16].…”

Section: Negative Refraction In T -Symmetric Weyl Semimetalsmentioning

confidence: 99%

“…As a result, part of the scattering channels at the Fermi energy level is absent, serving as a source for unique transport properties, including negative refraction between different surfaces [41]. In reality, the electronic transport signatures will depend on the material details and their specific termination, both of which affect the Fermi arcs' orientation, dispersion, and length [12][13][14][15][16][17][42][43][44]. Notably, however, stateof-the-art fabrication techniques allow for controlled surface shaping on the level of a single layer [16,18,45,46], making it possible to explore the broad breadth of surface transport phenomena.…”

Section: Introductionmentioning

confidence: 99%

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Detection of Fermi arcs in Weyl semimetals through surface negative refraction

2020

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One of the main features of Weyl semimetals is the existence of Fermi arc surface states at their surface, which cannot be realized in pure two-dimensional systems in the absence of many-body interactions. Due to the gapless bulk of the semimetal, it is, however, challenging to observe clear signatures from the Fermi arc surface states. Here, we propose to detect such novel surface states via perfect negative refraction that occurs between two adjacent open surfaces with properly orientated Fermi arcs. Specifically, this phenomenon visibly manifests in nonlocal transport measurement, where the negative refraction generates a return peak in the realspace conductance. This provides a unique signature of the Fermi arc surface states. We discuss the appearance of this peak in both inversion-and time-reversal-symmetric Weyl semimetals, where the latter exhibits conductance oscillations due to multiple negative refraction scattering events.

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“…(iv) Finally, in many Weyl semimetals, the Fermi arcs' dispersion is complex, making these surface states not much different from 2D normal metals, which cannot be used for WEYLFETs. Consequently, the material candidate for the WEYLFET should contain short Fermi arcs with small curvature [43][44][45].…”

mentioning

confidence: 99%

Field-effect transistor based on surface negative refraction in Weyl nanowire

Chen

Zilberberg

2020

APL Materials

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Weyl semimetals are characterized by their bulk Weyl points -conical band touching points that carry a topological monopole charge -and Fermi arc states that span between the Weyl points on the surface of the material. Recently, significant progress has been made towards understanding and measuring the physical properties of Weyl semimetals. Yet, potential applications remain relatively sparse. Here, we propose Weyl semimetal nanowires as field-effect transistors, dubbed WEYLFETs. Specifically, applying gradient gate voltage along the nanowire, an electrical field is generated that effectively tilts the open surfaces, thus, varying the relative orientation between Fermi arcs on different surfaces. As a result, perfect negative refraction between adjacent surfaces can occur and longitudinal conductance along the wire is suppressed. The WEYLFET offers a high on/off ratio with low power consumption. Adverse effects due to dispersive Fermi arcs and surface disorder are studied.

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Ideal Weyl semimetal induced by magnetic exchange

Cited by 155 publications

References 36 publications

Anomalous conductance scaling in strained Weyl semimetals

Anomalous conductance scaling in strained Weyl semimetals

Detection of Fermi arcs in Weyl semimetals through surface negative refraction

Field-effect transistor based on surface negative refraction in Weyl nanowire

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