Tuning magnetotransport in a compensated semimetal at the atomic scale

Wang, Lin; Gutiérrez-Lezama, Ignacio; Barreteau, Céline; Ubrig, Nicolas; Giannini, E.; Morpurgo, Alberto F.

doi:10.1038/ncomms9892

Nat Commun

2015

DOI: 10.1038/ncomms9892

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Tuning magnetotransport in a compensated semimetal at the atomic scale

Lin Wang

Ignacio Gutiérrez-Lezama

Céline Barreteau

et al.

Abstract: Either in bulk form, or in atomically thin crystals, layered transition metal dichalcogenides continuously reveal new phenomena. The latest example is 1T'-WTe2, a semimetal found to exhibit the largest known magnetoresistance in the bulk, and predicted to become a topological insulator in strained monolayers. Here we show that reducing the thickness through exfoliation enables the electronic properties of WTe2 to be tuned, which allows us to identify the mechanisms responsible for the observed magnetotransport… Show more

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Cited by 149 publications

(248 citation statements)

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“…Since then great efforts have been made towards expanding the spectrum of topological materials and bringing many conceptual materials into reality. Transition metal pentatellurides such as ZrTe5 and HfTe5 have been widely studied in bulk form since early 1980's due to their anomalous resistivity peak and X-ray diffraction intensity peak at low temperature 3,4 , large thermoelectric power 5 , pressure-induced superconductivity 6,7 , absence of a structural phase transition corresponding to resistivity anomaly 8 , and chiral magnetic effect 9 . In recent years, ZrTe5 research has been revived because of its non-trivial topological properties.…”

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confidence: 99%

Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe₅

Qiu

Charnas

et al. 2016

Nano Lett.

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Transition metal pentatelluride ZrTe5 is a versatile material in condensed-matter physics and has been intensively studied since the 1980's. The most fascinating feature of ZrTe5 is that it is a 3D Dirac semimetal which has linear energy dispersion in all three dimensions in momentum space. Structure-wise, ZrTe5 is a layered material held together by weak interlayer van der Waals force. The combination of its unique band structure and 2D atomic structure provides a fertile ground for more potential exotic physical phenomena in ZrTe5 related to 3D Dirac semimentals. However the physical properties of its few-layer form have yet to be thoroughly explored. Here we report strong optical and electrical in-plane anisotropy of mechanically exfoliated few-layer ZrTe5. Raman spectroscopy shows significant intensity change with sample orientations, and the behavior of angle-resolved phonon modes at the Γ point is explained by theoretical calculation. DC conductance measurement indicates a 50% of difference along different in-plane directions. The diminishing of resistivity anomaly in few-layer samples indicates the evolution of band structure with reduced thickness. Low-temperature Hall experiment sheds lights on more intrinsic anisotropic electrical transport, with hole mobility of 3,000 and 1,500 cm 2 /V· s along a-axis and c-axis respectively. Pronounced quantum oscillations in magnetoresistance are observed at low temperatures with highest electron mobility up to 44,000 cm 2 /V· s.Keywords: ZrTe5 Single crystal, 2D material, optical anisotropy, electrical anisotropy, quantum oscillations 3The discovery of graphene 1 began a new era of condensed-matter research because of its unique two-dimensional Dirac band structure, which hosts many profound physical phenomena such as the anomalous integer quantum Hall effect (IQHE) 2 . Since then great efforts have been made towards expanding the spectrum of topological materials and bringing many conceptual materials into reality. Transition metal pentatellurides such as ZrTe5 and HfTe5 have been widely studied in bulk form since early 1980's due to their anomalous resistivity peak and X-ray diffraction intensity peak at low temperature 3,4 , large thermoelectric power 5 , pressure-induced superconductivity 6,7 , absence of a structural phase transition corresponding to resistivity anomaly 8 , and chiral magnetic effect 9 . In recent years, ZrTe5 research has been revived because of its non-trivial topological properties. Some theoretical predictions and experimental results 10,11 indicate that it is a 3D Dirac semimetal, a mimic of graphene with linear energy dispersion in all three directions. On the other hand, its monolayer form is also claimed to be a candidate of quantum spin Hall insulator 12,13 , which is very rare among the natural compounds 14 . Shubnikov-de Haas oscillations 10,15,16 , Zeeman Splitting 17,18 , and fractional quantum Hall effect 19 were also observed in bulk ZrTe5.Meanwhile in recent years the 2D family has been expanded to a wide range of mat...

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mentioning

confidence: 99%

Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe₅

Qiu

Charnas

et al. 2016

Nano Lett.

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“…Although this is indeed the case in conventional field-effect devices, here we report the observation of a much longer-range field-effect, affecting electronic transport through a material over a depth orders of magnitude longer than the electrostatic screening length. The phenomenon, which occurs because the electrical conductivity is governed by non-local processes, manifests itself in large gate-induced changes in the transport properties of conductors as long as their thickness is smaller than or comparable to the carrier mean free path.We observe such a long-range field-effect in crystals of WTe 2 , a material possessing remarkable electronic properties [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. Transport experiments have shown that bulk WTe 2 is a nearly perfectly compensated semi-metal exhibiting record-high magnetoresistance (MR) because of the high electron and hole mobility [6,9,22].…”

mentioning

confidence: 99%

“…the possibility for electromagnetic waves to penetrate into a conductor over a distance much larger than that predicted by the conventional theory. Although in the past it had been realized that gate-tuning of surface scattering could result in gate dependence of transport properties in systems -such as metals-in which no field-effect should be expected [36,37], no direct experimental demonstration of this phenomenon and of its long-range nature has been provided [38].Our devices consist of WTe 2 crystals with thickness ranging from 10 to 50 nm exfoliated onto a highly doped Silicon substrate covered with a 285 nm SiO 2 insulating layer [22]. The doped Silicon substrate can be used as a gate electrode, even though for most devices -and certainly in the 50 nm thick crystals-no significant gate-induced modulation of transport is a priori expected.…”

mentioning

confidence: 99%

“…We observe such a long-range field-effect in crystals of WTe 2 , a material possessing remarkable electronic properties [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. Transport experiments have shown that bulk WTe 2 is a nearly perfectly compensated semi-metal exhibiting record-high magnetoresistance (MR) because of the high electron and hole mobility [6,9,22].…”

mentioning

confidence: 99%

“…Transport experiments have shown that bulk WTe 2 is a nearly perfectly compensated semi-metal exhibiting record-high magnetoresistance (MR) because of the high electron and hole mobility [6,9,22]. They have also shown that whenever the crystal thickness is reduced below the mean-free path (few hundreds nanometers or even longer), the carrier mobility is suppressed by scattering at the surface [22]. As established long ago, this implies that transport at the microscopic scale is governed by non-local processes, i.e.…”

mentioning

confidence: 99%

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Direct Observation of a Long-Range Field Effect from Gate Tuning of Nonlocal Conductivity

et al. 2016

Self Cite

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We report the direct observation of a long-range field-effect in WTe2 devices, leading to large gateinduced changes of transport through crystals much thicker than the electrostatic screening length. The phenomenon -which manifests itself very differently from the conventional field-effect-originates from the non-local nature of transport in the devices that are thinner than the carrier mean free path. We reproduce theoretically the gate dependence of the measured classical and quantum magnetotransport, and show that the phenomenon is caused by the gate-tuning of the bulk carrier mobility by changing the scattering at the surface. Our results demonstrate experimentally the possibility to gate tune the electronic properties deep in the interior of conducting materials, avoiding limitations imposed by electrostatic screening.Conventional field-effect transistors (FETs) exploit electrostatic gating to tune the electronic properties of materials by means of charge accumulation [1][2][3][4][5]. Gateinduced charge accumulation occurs close to the material surface, on a depth limited by the so-called screening length, which is typically very short, ∼1-2 nm. Electrostatic screening, therefore, seems to preclude the possibility to use FET devices to control the electronic properties in the interior of materials, i.e., their bulk response. Although this is indeed the case in conventional field-effect devices, here we report the observation of a much longer-range field-effect, affecting electronic transport through a material over a depth orders of magnitude longer than the electrostatic screening length. The phenomenon, which occurs because the electrical conductivity is governed by non-local processes, manifests itself in large gate-induced changes in the transport properties of conductors as long as their thickness is smaller than or comparable to the carrier mean free path.We observe such a long-range field-effect in crystals of WTe 2 , a material possessing remarkable electronic properties [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. Transport experiments have shown that bulk WTe 2 is a nearly perfectly compensated semi-metal exhibiting record-high magnetoresistance (MR) because of the high electron and hole mobility [6,9,22]. They have also shown that whenever the crystal thickness is reduced below the mean-free path (few hundreds nanometers or even longer), the carrier mobility is suppressed by scattering at the surface [22]. As established long ago, this implies that transport at the microscopic scale is governed by non-local processes, i.e. the relation between current density and electric field is non-local [26][27][28][29][30][31] [32]. It is well-known that in this non-local regime different physical phenomena exhibit an unusual behavior, as illustrated by so-called anomalous skin effect [33][34][35], i.e. the possibility for electromagnetic waves to penetrate into a conductor over a distance much larger than that predicted by the conventional theory. Although in the past it had...

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Epitaxial Stitching and Stacking Growth of Atomically Thin Transition‐Metal Dichalcogenides (TMDCs) Heterojunctions

Chen

Wan

2017

Adv Funct Materials

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(1 of 21)their novel electrical, [9,10,[16][17][18][19][20][21] magnetical, [22,23] optical, [13,[24][25][26][27][28] catalytical, [29][30][31] thermal [32,33] and mechanical properties [34,35] that cannot been seen in the traditional bulk materials. These exciting properties [14,[36][37][38][39][40][41] of TMDCs have offered unprecedented platforms for opening up new fundamental research [21,[42][43][44] and technological innovation. [45][46][47][48][49][50][51][52][53] TMDCs are formed of a "sandwich" structure with two chalcogen atoms layers (S, Se, Te) separated by a transition metal atoms layer (for instance Mo, W, V, Nb, Ti and so on) [38,39] which is different from the single carbon atomic lattice of graphene. [54][55][56][57][58][59][60] Similar with graphite, TMDCs are characterized by the weak van der Waals interaction between interlayers and strong intralayer covalent bonding. Therefore, it offers fantastic transferability of exfoliation of the bulk TMDCs into few-or even single-layered structures by physical or chemical methods, such as mechanical exfoliation by adhesive tape, [61][62][63] liquid exfoliation, [64][65][66][67] and chemical exfoliation assisted by ion intercalation. [68][69][70] Group VI transition metal element [15] dichalcogenides (MX 2 , M = Mo, W; X = S, Se, etc.) have become the flagship materials among the family of 2D-TMDCs layered materials after graphene. [71,72] The electronic and optoelectronic properties of group VI dichalcogenides (MX 2 ) are remarkably affected by the thickness or the number of layers in MX 2 . For example, the band gap of MX 2 could be effectively tuned by the thickness. In addition, the transition from indirect band gap to direct band gap for the semiconducting trigonal prismatic MX 2 as the thickness decreased to a monolayer, [73,74] which results in photoluminescence (PL) enhancement. [75] The semiconducting nature of trigonal prismatic MX 2 guarantees the advantages for future nano-electronic and optoelectronic development based on its high on/off current ratio performance and the presence of fascinating bandgap transition emissions. More importantly, valley pseudospin and layer pseudospin resulting from the strong spin-orbit coupling have been demonstrated in monolayer and few-layered MX 2 , [76][77][78] which is crucial for extensive exploration of spintronics and valleytronic devices. Interestingly, 2D-MX 2 exhibits a variety of infusive characteristics beyond their bulk counterparts due to the quantum confinement and surface effects, [79] which are the most frequently In recent years, ultrathin two-dimensional (2D) transition metal dichalcogenides (TMDCs), such as MX 2 (M = Mo, W; X = S, Se, etc.) have become the flagship materials after graphene. 2D-MX 2 have attracted significant attention due to their novel properties arising from their strict dimensional confinement as well as strong spin-orbit coupling effects, which provides an ideal platform for exploring new fundamental research and realizing technological innovation. The 2D nature and the...

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Tuning magnetotransport in a compensated semimetal at the atomic scale

Cited by 149 publications

References 32 publications

Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe₅

Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe₅

Direct Observation of a Long-Range Field Effect from Gate Tuning of Nonlocal Conductivity

Epitaxial Stitching and Stacking Growth of Atomically Thin Transition‐Metal Dichalcogenides (TMDCs) Heterojunctions

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Tuning magnetotransport in a compensated semimetal at the atomic scale

Cited by 149 publications

References 32 publications

Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe5

Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe5

Direct Observation of a Long-Range Field Effect from Gate Tuning of Nonlocal Conductivity

Epitaxial Stitching and Stacking Growth of Atomically Thin Transition‐Metal Dichalcogenides (TMDCs) Heterojunctions

Contact Info

Product

Resources

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Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe₅

Observation of Optical and Electrical In-Plane Anisotropy in High-Mobility Few-Layer ZrTe₅