Raman Signatures of Broken Inversion Symmetry and In‐Plane Anisotropy in Type‐II Weyl Semimetal Candidate TaIrTe₄

Abstract: The layered ternary compound TaIrTe is an important candidate to host the recently predicted type-II Weyl fermions. However, a direct and definitive proof of the absence of inversion symmetry in this material, a prerequisite for the existence of Weyl Fermions, has so far remained evasive. Herein, an unambiguous identification of the broken inversion symmetry in TaIrTe is established using angle-resolved polarized Raman spectroscopy. Combining with high-resolution transmission electron microscopy, an efficient … Show more

“…In general, anisotropic ratio in those devices can be gate tuned from a few times, to several hundreds or even thousands folds, which is much higher than other 2D systems reported. [1,2,4,6,17] Since Γ a in ultra-thin GaTe is rather weak at relatively higher hole doping (say, in the V g = −60 V limit), and becomes significantly enhanced close to the VBM in the vicinity of V g = −30 V, it more or less shows a better electron collimation at higher Γ a values, i.e., electrons tend to flow preferably along a certain direction at those conditions. Considering the deformation potential theory only applied to the band edge (VBM or CBM) and its inability to take care the gate-tunability on electrical transport, [18,19] we calculate IV curve and its gating dependence by combining density functional theory (DFT) calculation with the non-equilibrium Green's function (NEGF) method [20] (See method part), and show calculated field effect IV data at V ds =0.5 V along two perpendicular crystalline directions in Fig.S20.…”

“…Indeed, in the emerging 2D materials, electrical anisotropy has been one of the focuses in recent experimental efforts. [1][2][3][4][5][6][7][8] However, key understandings of the in-plane anisotropic resistance in low-symmetry 2D materials, as well as demonstrations of model devices taking advantage of it, have proven difficult. Here, we show that, in few-layered semiconducting GaTe, electrical conductivity along x and y directions of the 2D crystal can be gate tuned from a ratio of less than one order to as large as 10 3 .…”

“…[11] Recently, low-symmetry two dimensional (2D) materials have attracted significant attentions because of the potential applications of in-plane anisotropic nanoelectronics. [1][2][3][4][5][6][7][8] For example, ultra-thin black phosphorous flake showed an in-plane anisotropic conductance reaching a ratio σ a /σ b of about 1.5, which in principle can be a direction-sensitive sensor. [1] ReS 2 was reported to be another candidate for anisotropic 2D field effect transistor, which exhibited a σ a of almost ten times the value of σ b .…”

Gate tunable giant anisotropic resistance in ultra-thin GaTe

“…In general, anisotropic ratio in those devices can be gate tuned from a few times, to several hundreds or even thousands folds, which is much higher than other 2D systems reported. [1,2,4,6,17] Since Γ a in ultra-thin GaTe is rather weak at relatively higher hole doping (say, in the V g = −60 V limit), and becomes significantly enhanced close to the VBM in the vicinity of V g = −30 V, it more or less shows a better electron collimation at higher Γ a values, i.e., electrons tend to flow preferably along a certain direction at those conditions. Considering the deformation potential theory only applied to the band edge (VBM or CBM) and its inability to take care the gate-tunability on electrical transport, [18,19] we calculate IV curve and its gating dependence by combining density functional theory (DFT) calculation with the non-equilibrium Green's function (NEGF) method [20] (See method part), and show calculated field effect IV data at V ds =0.5 V along two perpendicular crystalline directions in Fig.S20.…”

“…Indeed, in the emerging 2D materials, electrical anisotropy has been one of the focuses in recent experimental efforts. [1][2][3][4][5][6][7][8] However, key understandings of the in-plane anisotropic resistance in low-symmetry 2D materials, as well as demonstrations of model devices taking advantage of it, have proven difficult. Here, we show that, in few-layered semiconducting GaTe, electrical conductivity along x and y directions of the 2D crystal can be gate tuned from a ratio of less than one order to as large as 10 3 .…”

“…[11] Recently, low-symmetry two dimensional (2D) materials have attracted significant attentions because of the potential applications of in-plane anisotropic nanoelectronics. [1][2][3][4][5][6][7][8] For example, ultra-thin black phosphorous flake showed an in-plane anisotropic conductance reaching a ratio σ a /σ b of about 1.5, which in principle can be a direction-sensitive sensor. [1] ReS 2 was reported to be another candidate for anisotropic 2D field effect transistor, which exhibited a σ a of almost ten times the value of σ b .…”

Gate tunable giant anisotropic resistance in ultra-thin GaTe

“…25,26 Since then, the polarizationdependent absorption, [26][27][28][29][30][31] Raman spectroscopy, [32][33][34] photoluminescence, [35][36][37] and the in-plane anisotropic electronic, 26,38,39 thermal, 40,41 and mechanical 42 properties of BP have been intensively studied. Ignited by BP, other inplane anisotropic 2D materials, from semimetals (T d WTe 2 , 43 1 T' MoTe 2,44,45 and ZrTe 5 46 TaIrTe 4 , 47,48 ) to semiconductors (group IV monochalcogenides, 49 Ta 2 NiS 5 , 50 GaTe, 51 group IVB trichalcogenides, 52 group IV-group V compounds, 53 70 TlSe, 71 ) (Table 1) and so on were explored. After developing for few years, the in-plane anisotropic 2D materials have becoming one of the most attractive research interests in the scientific field.…”

Emerging in‐plane anisotropic two‐dimensional materials

“…[6,[30][31][32][33][34] Figure 4a shows Raman spectra for parallel polarization (PP, top) and cross polarization (CP, bottom) configurations. [6,[30][31][32][33][34] Figure 4a shows Raman spectra for parallel polarization (PP, top) and cross polarization (CP, bottom) configurations.…”

Mo₆S₃Br₆: An Anisotropic 2D Superatomic Semiconductor