Abstract
Nickel ditelluride (NiTe2), a recently discovered Type-II Dirac semimetal with topological Dirac fermions near the Fermi energy, is expected to exhibit strong thickness-mediated electronic tunability and intrinsic two-gap superconductivity in the single-layer limit. Realizing such intriguing phenomena requires the fabrication of ultrathin NiTe2 films and an understanding of the underlying physics that is still under debate. By conducting experimental band mappings of ultrathin films prepared with molecular beam epitaxy, we reveal spectroscopic evidence for the dimensionality crossover of single-crystalline ultrathin NiTe2 films as a function of film thickness. As the film thickness increases from one to five layers, the gap in the conical topological surface states closes. Comparisons of experimental to first-principles results also highlight difficulties in fabricating atomically smooth single-layer NiTe2 films. Our results not only provide further impetus for studying emergent phenomena in NiTe2 but also underscore the limitations of fabricating NiTe2 films for device applications.
Similar content being viewed by others
Introduction
Recent years have beheld the emergence of transition metal dichalcogenides (TMDCs) as a rich class of quasi-two-dimensional materials with electronic properties spanning from trivial semiconductors and semimetals to superconductors and topological phases1,2,3. By virtue of the weak van der Waals bonding between layers, these materials can usually be isolated into single-layer phases4,5,6,7,8,9,10,11,12,13,14 and can sometimes be perfect testing grounds for probing phenomena modified from or distinct from the bulk limit, including quantum spin Hall systems6,7, superconductivity8,9,10, charge density wave (CDW) phases11,12,13, and semiconductor-to-semimetal transitions14. Specific cases include a direct gap semiconductor phase in MoS2 and WS2 in the single-layer limit4,5, CDW phases in single-layer TiTe2 and VSe2 distinct from bulk phenomena12,13, and recently, a strong thickness-mediated Lifshitz transition from a semimetal to a semiconductor phase in ultrathin PtTe2 films14. The Ni-based TMDC NiTe2 is also ideal for exploring unusual phenomena in bulk and at reduced dimensions15,16,17,18,19,20,21,22,23,24. Though bulk NiTe2 is not superconducting, ab initio calculations have predicted an intrinsic two-gap superconducting state in single-layer NiTe2 with a transition temperature Tc ~ 5.7 K (ref. 17). In addition, bilayer NiTe2 intercalated with an alkali metal may be a two-gap superconductor with a gap as high as ~3.1 meV and a critical temperature Tc ~ 11.3 K (ref. 17). Moreover, recent work on NiTe2 under high pressure has shown the onset of superconductivity at small pressures and a second superconducting phase at even higher pressures with a transition temperature Tc ~ 7.5 K (ref. 18), implying that NiTe2 is near the threshold of a superconducting instability. Ferromagnetic ordering at low temperatures with a Curie temperature TF ~ 22 K has also been found in NiTe2 nanostructures20, but bulk NiTe2 itself is paramagnetic21.
Furthermore, NiTe2 is a candidate for the Type-II topological Dirac semimetal phase21,22,23,24, in which low-energy excitations of emergent Dirac fermions generate a strongly tilted bulk Dirac cone that breaks Lorentz symmetry21,22,23,24,25,26,27,28,29,30,31. Such symmetry breaking should generate electronic and physical properties distinct from other topological semimetals, including an anisotropic magnetoresistance and chiral anomaly28,29,30,31,32 and unconventional superconductivity21,33. The topological nature of bulk NiTe2 single crystal has been addressed recently through both spin-resolved and conventional angle-resolved photoemission spectroscopy (ARPES), which revealed evidence for a topological Dirac cone with spin-polarized surface states at an energy E ~ −1.4 eV and a Type-II Dirac node near the Fermi level at E = 0 eV (refs. 23,24). The results contrast from the Pt- and Pd-based topological semimetals, which have Type-II Dirac cones located very far from the Fermi level at energies E ~ −0.6 eV to −1.2 eV (refs. 25,26,27,28,29). Thus, in lieu of the Pt- and Pd-based systems, NiTe2 is likely an improved platform for exploiting topological Dirac fermions and other emergent phenomena for the development of spintronic or topological devices. However, to realize such physics, the thickness-dependent electronic band structure of ultrathin NiTe2 films needs to be fully addressed, a prerequisite for revealing the system’s electronic tunability in the ultrathin-film limit and for further assessing the feasibility of fabricating atomically smooth NiTe2 films in a device setting.
Here, we present ARPES band mappings of ultrathin, semimetallic NiTe2 films of nominal thicknesses 1–5 triatomic layers (TL) fabricated using molecular beam epitaxy (MBE) on bilayer-graphene-terminated surfaces, which provide clear spectroscopic evidence of strong thickness-mediated electronic tunability of NiTe2 films. Specifically, our detailed band maps for increasing film thickness show the closing of the hybridization gap in the topological surface Dirac cone already at 5 TL in thickness and simultaneously, the development of linear-like bands near the Fermi level attributable to the lower branches of the Type-II Dirac cone in the bulk limit23,24, both indicative of the dimensionality crossover from the ultrathin-film to bulk-like regimes. Our results also suggest that NiTe2 is a robust semimetal even in the single-layer limit, contrasting from the semiconducting behavior in 1 TL PtTe2 (refs. 14,34). Furthermore, first-principles calculations of NiTe2 based on density functional theory (DFT) are compared with the measured ARPES spectra to confirm the fabrication of single-crystalline NiTe2 films in only the 1 T phase and thus to dismiss the question of another stable phase, such as the pyrite lattice35,36,37, appearing in our results. However, we discover that atomically smooth NiTe2 films grown with MBE on bilayer graphene are seemingly unstable in the ultrathin-film regime, raising potential serious questions about the feasibility of integrating smooth one TL NiTe2 films in a device and highlighting possible difficulties in observing emergent phenomena in 1 and 2 TL systems.
Results and discussion
Growth and characterizations of 1+2 TL and 5 TL 1 T NiTe2
NiTe2 has been suggested to exist in multiple lattice structures, including the 1 T and pyrite lattices (refs. 15,16,17,18,19,20,21,22,23,24,35,36,37) (see Fig. 1a and Supplementary Fig. 1). We confirm that NiTe2 can adopt in theory four distinct phases: 1 T, 2H, pyrite, and marcasite, whose lattice structures and corresponding bulk Brillouin zones all appear in Supplementary Fig. 1. Table 1 summarizes each of their normalized energy per unit cell, which reveals that the 1 T phase has the lowest energy, followed by the marcasite and pyrite lattices, and is thus the most energetically stable phase. Figure 1a presents the atomic lattice structure for 1 TL of 1 T NiTe2, which contains three triangular atomic layers of Te and Ni stacked in the order Te-Ni-Te. The bulk lattice for 1 T NiTe2 is assembled by vertically stacking many of these TLs directly on one another, each separated by a lattice constant c = 5.26 Å, with no other rotational and translational offsets, and van der Waals bonded with neighboring layers. The corresponding (001)-projected surface Brillouin zone is displayed in Fig. 1b. In this work, ultrathin 1 T NiTe2 films with thicknesses N = 1–5 TL are grown on bilayer-graphene-terminated 6H-SiC(0001) surfaces (BLG-SiC). Representative in situ reflection high-energy electron diffraction (RHEED) patterns for a BLG-SiC surface and a 5 TL film are shown in the left and right panels of Fig. 1c, respectively; the sharp diffraction streaks for the 5 TL film are evidence of a highly well-ordered surface.
An overview ARPES spectra and a zoomed-in view of the same band map for a 1+2 TL 1 T NiTe2 film taken along the \({\bar {\Gamma} {\bar{\mathrm{M}}}}\) direction, where “1+2 TL” means a film with a mixture of 1 and 2 TL ARPES signal, are displayed in the left and right panels of Fig. 1d, respectively. The corresponding calculated DFT band structure, consisting of the calculation for a 1 TL film (red curves) superimposed with that of a 2 TL film (blue curves), appears in Fig. 1e. Similar ARPES and theoretical results for a 5 TL film, which we find are in the bulk-like regime, are summarized in Fig. 1f and g, respectively. Evidently, the electronic band structure in Fig. 1d consists of a mixture of 1 and 2 TL signal, though the film thickness based upon the amount of deposition should be 1 TL. Incidentally, reduction of the calibrated film thickness from 1 TL to 0.5 TL in thickness, the former being the result shown in Fig. 1d, yields similar ARPES band maps as in Fig. 1d with faint bands arising from a 2 TL film thickness. For example, from the red theoretical curves in Fig. 1e, the band structure of 1 TL 1 T NiTe2 should be a relatively simple, robust semimetal with only three bands crossing the \(\bar \Gamma\) point in the energy range E = 0 to −2 eV and a negative gap of ~−0.50 eV (see, for instance, Supplementary Fig. 4), quite unlike its Pt-based counterpart that is semiconducting at this thickness14,34. However, in the ARPES results in Fig. 1d, an additional weak band crosses at the \(\bar \Gamma\) point at E ~ −0.5 eV (indicated by a red arrow in Fig. 1d), which can be ascribed to that of a 2 TL film thickness (compare to the blue curves in Fig. 1e). Furthermore, as the bands disperse along the \({\bar\Gamma \bar{\mathrm{M}}}\) direction away from the \(\bar \Gamma\) point, additional bands not belonging to the 1 TL system can be duly assigned to those of a 2 TL film. The situation for the 5 TL sample is a bit different from the 1 + 2 TL system (Fig. 1f, g). Generally speaking, the first-principles calculation result in Fig. 1g is more representative of the 5 TL ARPES map in Fig. 1f with the effects of any layer mixing less obvious at this thickness and is thus in accord with our expected thickness calibration. In other words, our results suggest that it is difficult to prepare a uniform 1 T NiTe2 thin film on BLG-SiC, implying enhanced interlayer coupling relative to the Pt-based topological semimetals14. Since we observe 1 + 2 TL and 5 TL band structures in our ARPES results (see Fig. 1d, f), though we expect 1 TL and 5 TL signals, respectively, based on our thickness calibration, the surface energy of the BLG-SiC substrate, while conducive for fabricating other single-layer TMDC films6,7,10,11,12,13,14, may be too low for forming a uniform 1 TL 1 T NiTe2 film. Rather, the next TL starts forming over the first TL well before the BLG-SiC surface is fully covered. Clean layer-resolved evolution of the band structure using ARPES at film thicknesses such as 1 and 2 TL may thus be potentially problematic, which can complicate observation of emergent phenomena, such as two-gap superconductivity, in this thickness regime and possibly integration of 1 T NiTe2 in a device setting.
Gap opening in topological states at reduced thickness
Despite these difficulties in realizing pure 1 TL and 2 TL systems, the results highlight a clear departure in the electronic band structures between films grown at low coverages and those in the bulk-like limit, which arises from quantum confinement along the surface normal. In particular, the band dispersions of the conical topological surface states (TSS) (refs. 23,24), labeled as TSS in Fig. 1d, f, are modified as the thickness is reduced from 5 TL to 1+2 TL. Figure 2a displays the ARPES spectra taken along \({\bar\Gamma \bar{\mathrm{M}}}\) (left panel) and the same map zoomed-in around the TSS (right panel) for a 1+2 TL 1 T NiTe2 film; the corresponding second-derivative maps are displayed in Fig. 2b, whereas similar ARPES and second-derivative spectra for the 5 TL film appear in Fig. 2c and d, respectively. These results are very clear: At 1+2 TL in thickness, a hybridization gap of Eg ~ 0.1 eV opens in the conical TSS (right panels of Fig. 2a, b), typical of ultrathin topological films driven by quantum-mechanical coupling between the film’s two boundaries38,39, but for a 5 TL film, the gap in these surface states is not present within the experimental energy resolution (right panels of Fig. 2c, d). Furthermore, in the ARPES spectra for the 5 TL sample, linear bands that seemingly connect at or slightly above the Fermi level (identified by the label DB in the right panel of Fig. 1f) are present near the zone center, which in the bulk limit, are attributable to the lower branches of a bulk Type-II Dirac cone23,24, but for the 1+2 TL film, these bands are entirely absent. The ARPES map for the 5 TL sample is also much more complicated than the 1+2 TL film at the zone center, with a dense set of upside–down U-shaped bands appearing near the \(\bar \Gamma\) point in the energy range E = −0.25 to −1 eV (Fig. 1f, g); these bands are mostly lacking in the 1+2 TL case (Fig. 1d, e). Generally, the results for the 5 TL sample are consistent with those previously reported for bulk 1 T NiTe2 single crystal with a Type-II Dirac node near the Fermi energy23,24, though the film has not reached the bulk limit as evidenced by the discretization of the bulk occupied states into quantum well bands in the ARPES and theoretical results.
Dimensionality crossover in the band maps of 1 T NiTe2 films
The thickness dependence of 1 T NiTe2 films from the ultrathin-film to bulk-like limit is of fundamental interest to reveal how the band structure of 1 T NiTe2 evolves into a bulk Type-II Dirac semimetal system with topologically protected nontrivial states. ARPES band maps and their second-derivative spectra for ultrathin 1 T NiTe2 films of nominal thicknesses N = 1–5 TL taken along the \({\bar\Gamma \bar{\mathrm{M}}}\) direction are summarized in Fig. 3a and b, respectively. Figure 3c displays the corresponding DFT calculations, whereas ARPES maps in Fig. 3d are overlaid with the same theoretical results to foster further comparisons. A similar data set for the thickness-dependent band structure along the \({\bar\Gamma \bar{\mathrm{K}}}\) direction appears in Fig. 4. Some general comments about the bulk-like and ultrathin-film regimes are warranted for these results. None of these band maps show any evidence of other phases aside from 1 T NiTe2 (see Supplementary Figs. 3 and 4), and all of these thin-film samples are semimetallic. For all thicknesses <5 TL, the conical TSS at E ~ −1.45 eV in the 5 TL system are gapped. As the thickness increases from 1 to 5 TL, this hybridization gap becomes smaller and first closes at 5 TL in thickness, signaling the onset of the bulk-like limit. A 5 TL film is thus the critical thickness for realizing such a topologically protected surface Dirac cone with spin-polarized surface states23,24. As discussed previously, the 5 TL film also shows incipient hints of the lower branches of the Type-II Dirac cone (Figs. 1f, 3, and 4). When the film thickness is reduced from 5 TL to 4 TL, this structure mostly disappears, with fewer bands crossing the Fermi level near the zone center (compare Figs. 1f, 3, and 4); no bands cross the \(\bar \Gamma\) point very close to the Fermi level for the 1+2 TL and 3 TL samples, and the structure for the Type-II Dirac cone is entirely absent. Such observations alone are indicative of the strong thickness-mediated tunability of the band structure for 1 T NiTe2.
The discussion can be generalized even further for other occupied bands in this system. Per the results in Figs. 3 and 4, an increase in the 1 T NiTe2 film thickness from one thickness to the next necessarily results in the multiplication of quantum well bands, which is well-known in noble metallic films40. For example, in the spectra in Figs. 3a, b and 4a, b, we see that the number of upside–down U-shaped bands at the zone center in the energy range E = −0.2 to −1 eV increases by exactly one as the thickness is tuned from 3 TL to 4 TL. However, increasing the thickness to 5 TL results in an even denser set of these U-shaped bands, and though resolvable, it starts becoming more difficult to count these bands separately as the film is approaching the bulk limit. Corresponding statements for band counting can be duly noted for occupied bands away from the \(\bar \Gamma\) point. Similar evolution of the band structure has been reported for the Pt-based topological semimetals14. However, unlike their Pt-based counterparts14, for all NiTe2 thin films measured here, the second-derivative ARPES maps (Figs. 2b, d, 3b, and 4b) tend to exhibit a very small amount of signal from the next layer owing to the presence of other minor thicknesses arising from the growth process, though such an effect is less apparent as the film thickness increases to 4 TL or 5 TL. Nevertheless, when these observations are taken into account, the calculation results are in general agreement with the measured ARPES spectra, with minor discrepancies not unusual from first-principles calculations.
Synchrotron Fermi surface maps for 3–5 TL 1 T NiTe2 films
At last, Fig. 5a and b display the measured Fermi surface maps and their corresponding second derivatives for N = 3–5 TL 1 T NiTe2 thin films, respectively; the calculated Fermi surface maps are shown in Fig. 5c for comparison. Superficially, the three sets of experimental Fermi surface contours for 1 T NiTe2 near the zone center are similar to one another in this thickness regime, but there are clear notable differences. One particular change occurs within a small, seemingly circular pocket centered about the \(\bar \Gamma\) point, which is indicated by a white arrow in each second-derivative map in Fig. 5b. Within this circle, another small circular pocket develops prominently as the thickness increases from 3 TL to 4 TL (indicated by a red arrow in the 4 TL map in Fig. 5b). Upon further increase to 5 TL in thickness, it is replaced by an even tinier pocket or dot (designated by a yellow arrow in the 5 TL map in Fig. 5b). Aside from these changes, the Fermi surface contours themselves become denser and thus more complex with increasing film thickness, as expected for films at larger thicknesses. At some point, these contours should converge to the bulk Fermi surface map, modulated by ARPES matrix element effects.
These changes are further illuminating in regards to the thickness-mediated crossover of 1 T NiTe2 from the ultrathin-film to a bulk-like limit reminiscent of the Type-II Dirac semimetal phase. From Figs. 3 and 4, no bands are present near the zone center at the Fermi level for a 3 TL film, but when the thickness is increased to 4 TL, another set of hole-like bands centered about the \(\bar \Gamma\) point develops. Evidently, this should correspondingly cause a smaller hole pocket to arise in the Fermi surface map, which is indeed seen in the 4 TL maps in Fig. 5 (indicated by the red arrow in the middle panel of Fig. 5b). A further increase in the film thickness to 5 TL causes the bands near the Fermi level at the \(\bar \Gamma\) point to become very dense, such that the Fermi level now crosses a tiny conical band very close to its apex (see right panel of Fig. 1f and also Figs. 3 and 4). The experimental Fermi surface map for the 5 TL sample should have a very tiny pocket or dot at the zone center, which is evident in the experimental result for the 5 TL film in Fig. 5 (identified by the yellow arrow in the right panel of Fig. 5b). In other words, the results for the Fermi surface maps provide additional confirmation of the crossover from the ultrathin-film to bulk-like limit as the film thickness is increased and thus corroborate with our analysis related to Figs. 3 and 4.
Discussion
Our comprehensive experimental and theoretical efforts demonstrate that we have successfully fabricated ultrathin films of 1 T NiTe2 with thicknesses N = 1–5 TL on BLG-SiC using MBE, a system expected to exhibit emergent, intrinsic superconductivity in the 1 TL limit and also a topological Type-II Dirac fermion phase in bulk. By employing DFT first-principles calculations, we completely dismiss any mixture of other phases, including pyrite and marcasite NiTe2, in our ARPES band maps. These results together are spectroscopic evidence for the strong thickness-mediated electronic tunability of 1 T NiTe2, revealing the crossover from the ultrathin-film to bulk-like limit with incipient hints of the Type-II Dirac semimetal phase with bulk Dirac fermions near the Fermi level. Our experimental ARPES maps specifically show that the hybridization gap in the topological surface Dirac cone at an energy E ~ −1.45 eV first closes at 5 TL in thickness. Nevertheless, despite these successes, we discover that as-grown ultrathin 1 T NiTe2 films favor growing in an approximately layer-by-layer manner on BLG-SiC, suggesting enhanced interlayer coupling in this system relative to the Pt-based topological semimetals. Finally, DFT calculations and the measured ARPES spectra are in good agreement with one another. Future studies into this system may wish to instead employ local probes, such as scanning tunneling spectroscopy (STS), to characterize the electronic structure of ultrathin 1 T NiTe2 films further and to confirm or refute superconductivity in the 1 TL 1 T NiTe2 system. For such works, substrates other than BLG-SiC may also be more conducive for growth of atomically smooth 1 TL 1 T NiTe2 films, which would engender further assessments regarding the fabrication and suitability of 1 TL films for technological applications. We overall expect that these findings help complete the picture for ultrathin films whose bulk phase is a Type-II Dirac semimetal and also underline potential difficulties in employing MBE-grown 1 T NiTe2 films in a device setting.
Methods
Sample preparation of 1 T NiTe2 films
Prior to growth of ultrathin NiTe2 films via MBE at the University of Illinois, 6H-SiC(0001) substrates were degassed at ~500 °C for a couple hours and then flash annealed to ~1300 °C for more than 50 cycles, yielding well-ordered bilayer-graphene-terminated surfaces41. High-purity Ni and Te were co-evaporated from an electron-beam evaporator (Ni) and an effusion cell (Te) onto a BLG-SiC surface maintained at 280 °C. The film growth rate was 1 TL (1 TL ≈ 0.5 nm) every ~50 min. Following the film growth, sample quality was confirmed in situ using RHEED and ARPES. Photoemission measurements at the University of Illinois were performed at 30 K using a Scienta Omicron VUV5k He discharge lamp coupled with a Scienta R4000 hemispherical analyzer. Each NiTe2 film was capped with a 10-nm-thick Te film to preserve surface integrity upon removal from the ARPES system. These samples were taken to Beamline 10.0.1.1 (HERS) at the Advanced Light Source (ALS) for additional ARPES characterizations. They were decapped in ultra-high vacuum by heating under Te flux to ~300 °C just prior to the measurements. The synchrotron results were obtained at a sample temperature of ~80 K and an overall energy resolution better than 15 meV. In addition to the results outlined in the main discussion, constant energy contour maps E(kx, ky) obtained at synchrotron for 1 T NiTe2 thin films of thicknesses 3–5 TL are briefly considered in Supplementary Note 5 and Supplementary Fig. 22, whereas additional analysis and processing of data taken at the University of Illinois are detailed in Supplementary Note 6 and Supplementary Figs. 23–25.
First-principles calculations
First-principles calculations were conducted in the DFT framework42 as implemented in the Vienna ab initio simulation package43; the projected augmented wave approach was employed with an energy cutoff of 400 eV (refs. 44,45). To replicate the experimental lattice constants, the optB86b-vdW functional46 for the van der Waals correction was used for the structural relaxation, such that the residual force on each atom was <10−3 eV/Å; the self-consistent convergence criterion was set to 10−5 eV. Thin films were modeled as a periodic array of finite-layer systems, each separated from one another by a vacuum gap of 15.0 Å. For thin films, the first Brillouin zone was sampled by employing Γ-centered Monkhorst-Pack (ref. 47) k-space meshes of 24 × 24 × 1, whereas for bulk structures, k-space meshes of 24 × 24 × 12, 24 × 24 × 6, and 24 × 24 × 18 for the 1 T, 2H, and orthorhombic (pyrite and marcasite) structures were utilized, respectively. SOC was included in the theoretical band structures presented, unless indicated otherwise. The lattice structures and select theoretical band structure results for 1 T, 2H, pyrite, and marcasite phases of NiTe2 are considered in Supplementary Note 1 and Supplementary Figs. 1–4. Additional calculations that employ the generalized gradient approximation (GGA) with a Hubbard-like onsite Coulomb repulsion correction (GGA+U) (refs. 48,49) and the metaGGA SCAN functional50 for 1 T NiTe2 thin films are codified in Supplementary Note 2 and Supplementary Figs. 5–10. Theoretical discussions relevant to the recently predicted superconductivity and magnetic ordering in 1 TL 1 T NiTe2 (refs. 17,19) and the spin polarization of the TSS as a function of film thickness are outlined in Supplementary Notes3 and 4, respectively, the results of which are further detailed in Supplementary Figs. 11–21 and Supplementary Tables 1–3.
Data availability
All data needed to evaluate the conclusions in the paper are included in the paper and/or the Supplementary Information. Additional data related to this paper may be requested from T.C.C. (tcchiang@illinois.edu) and F.C.C. (fchuang@mail.nsysu.edu.tw).
References
Manzeli, S., Ovchinnikov, D., Pasquier, D., Yazyev, O. V. & Kis, A. 2D transition metal dichalcogenides. Nat. Rev. Mater. 2, 17033 (2017).
Han, G. H., Duong, D. L., Keum, D. H., Yun, S. J. & Lee, Y. H. Van der Waals metallic transition metal dichalcogenides. Chem. Rev. 118, 6297–6336 (2018).
Ataca, C., Şahin, H. & Ciraci, S. Stable, single-layer MX2 transition-metal oxides and dichalcogenides in a honeycomb-like structure. J. Phys. Chem. C. 116, 8983–8999 (2012).
Mak, K. F., Lee, C., Hone, J., Shan, J. & Heinz, T. F. Atomically thin MoS2: a new direct-gap semiconductor. Phys. Rev. Lett. 105, 136805 (2010).
Zhao, W. et al. Evolution of electronic structure in atomically thin sheets of WS2 and WSe2. ACS Nano 7, 791–797 (2013).
Chen, P. et al. Large quantum-spin-Hall gap in single-layer 1T’ WSe2. Nat. Commun. 9, 2003 (2018).
Tang, S. et al. Quantum spin Hall state in monolayer 1T’-WTe2. Nat. Phys. 13, 683–687 (2017).
Liu, D. et al. Electronic origin of high-temperature superconductivity in single-layer FeSe superconductor. Nat. Commun. 3, 931 (2012).
Miyata, Y., Nakayama, K., Sugawara, K., Sato, T. & Takahashi, T. High-temperature superconductivity in potassium-coated multilayer FeSe thin films. Nat. Mater. 14, 775–779 (2015).
Ugeda, M. M. et al. Characterization of collective ground states in single-layer NbSe2. Nat. Phys. 12, 92–97 (2016).
Chen, P. et al. Charge density wave transition in single-layer titanium diselenide. Nat. Commun. 6, 8943 (2015).
Chen, P. et al. Emergence of charge density waves and a pseudogap in single-layer TiTe2. Nat. Commun. 8, 516 (2017).
Chen, P. et al. Unique gap structure and symmetry of the charge density wave in single-layer VSe2. Phys. Rev. Lett. 121, 196402 (2018).
Lin, M. K. et al. Dimensionality-mediated semimetal-semiconductor transition in ultrathin PtTe2 films. Phys. Rev. Lett. 124, 036402 (2020).
Zhao, B. et al. Synthetic control of two-dimensional NiTe2 single crystals with highly uniform thickness distributions. J. Am. Chem. Soc. 140, 14217–14223 (2018).
Shi, J. et al. Two-dimensional metallic NiTe2 with ultrahigh environmental stability, conductivity, and electrocatalytic activity. ACS Nano 14, 9011–9020 (2020).
Zheng, F. et al. Emergent superconductivity in two-dimensional NiTe2 crystals. Phys. Rev. B 101, 100505(R) (2020).
Feng, Z. et al. Evidences for pressure-induced two-phase superconductivity and mixed structures of NiTe2 and NiTe in type-II Dirac semimetal NiTe2-x (x = 0.38 ± 0.09) single crystals. Mater. Today Phys. 17, 100339 (2021).
Aras, M., Kılıç, Ç. & Ciraci, S. Magnetic ground state in FeTe2, VS2, and NiTe2 monolayers: antiparallel magnetic moments at chalcogen atoms. Phys. Rev. B 101, 054429 (2020).
Dulal, R. P. et al. Nanostructures of type-II topological Dirac semimetal NiTe2. J. Vac. Sci. Technol. B 37, 042903 (2019).
Xu, C. et al. Topological Type-II Dirac fermions approaching the Fermi level in a transition metal dichalcogenide NiTe2. Chem. Mater. 30, 4823–4830 (2018).
Liu, Q. et al. Nontopological origin of the planar Hall effect in the type-II Dirac semimetal NiTe2. Phys. Rev. B 99, 155119 (2019).
Ghosh, B. et al. Observation of bulk states and spin-polarized topological surface states in transition metal dichalcogenide Dirac semimetal candidate NiTe2. Phys. Rev. B 100, 195134 (2019).
Mukherjee, S. et al. Fermi-crossing Type-II Dirac fermions and topological surface states in NiTe2. Sci. Rep. 10, 12957 (2020).
Bahramy, M. S. et al. Ubiquitous formation of bulk Dirac cones and topological surface states from a single orbital manifold in transition-metal dichalcogenides. Nat. Mater. 17, 21–28 (2018).
Clark, O. J. et al. Fermiology and superconductivity of topological surface states in PdTe2. Phys. Rev. Lett. 120, 156401 (2018).
Noh, H. J. et al. Experimental realization of Type-II Dirac fermions in a PdTe2 superconductor. Phys. Rev. Lett. 119, 016401 (2017).
Yan, M. et al. Lorentz-violating type-II Dirac fermions in transition metal dichalcogenide PtTe2. Nat. Commun. 8, 257 (2017).
Zhang, K. et al. Experimental evidence for type-II Dirac semimetal in PtSe2. Phys. Rev. B 96, 125102 (2017).
Politano, A. et al. 3D Dirac plasmons in the Type-II Dirac semimetal PtTe2. Phys. Rev. Lett. 121, 086804 (2018).
Zheng, W. et al. Detailed study of the Fermi surfaces of the type-II Dirac semimetallic candidates XTe2 (X=Pd, Pt). Phys. Rev. B 97, 235154 (2018).
Udagawa, M. & Bergholtz, E. J. Field-selective anomaly and chiral mode reversal in Type-II Weyl materials. Phys. Rev. Lett. 117, 086401 (2016).
Alidoust, M., Halterman, K. & Zyuzin, A. A. Superconductivity in type-II Weyl semimetals. Phys. Rev. B 95, 155124 (2017).
Villaos, R. A. B. et al. Thickness dependent electronic properties of Pt dichalcogenides. NPJ 2D Mater. Appl. 3, 2 (2019).
Chia, X., Sofer, Z., Luxa, J. & Pumera, M. Unconventionally layered CoTe2 and NiTe2 as electrocatalysts for hydrogen evolution. Chem. Eur. J. 23, 11719–11726 (2017).
Bensch, W. et al. Anionic polymeric bonds in nickel ditelluride: Crystal structure, and experimental and theoretical band structure. J. Solid State Chem. 121, 87–94 (1996).
Jobic, S., Brec, R. & Rouxel, J. Anionic polymeric bonds in transition metal ditellurides. J. Solid State Chem. 96, 169–180 (1992).
Liu, Y., Bian, G., Miller, T., Bissen, M. & Chiang, T. C. Topological limit of ultrathin quasi-free-standing Bi2Te3 films grown on Si(111). Phys. Rev. B 85, 195442 (2012).
Zhang, Y. et al. Crossover of the three-dimensional topological insulator Bi2Se3 to the two-dimensional limit. Nat. Phys. 6, 584–588 (2010).
Chiang, T. C. Photoemission studies of quantum well states in thin films. Surf. Sci. Rep. 39, 181–235 (2000).
Wang, Q. et al. Large-scale uniform bilayer graphene prepared by vacuum graphitization of 6H-SiC(0001) substrates. J. Phys. Condens. Matter 25, 095002 (2013).
Hohenberg, P. & Kohn, W. Inhomogeneous electron gas. Phys. Rev. 136, B864–B871 (1964).
Kresse, G. & Hafner, J. Ab initio molecular dynamics for liquid metals. Phys. Rev. B 47, 558(R)–561(R) (1993).
Blöchl, P. E. Projector augmented-wave method. Phys. Rev. B 50, 17953–17979 (1994).
Kresse, G. & Joubert, D. From ultrasoft pseudopotentials to the projector augmented-wave method. Phys. Rev. B 59, 1758–1775 (1999).
Klimeš, J., Bowler, D. R. & Michaelides, A. Chemical accuracy for the van der Waals density functional. J. Phys. Condens. Matter 22, 022201 (2010).
Monkhorst, H. J. & Pack, J. D. Special points for Brillouin-zone integrations. Phys. Rev. B 13, 5188–5192 (1976).
Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized gradient approximation made simple. Phys. Rev. Lett. 77, 3865–3868 (1996).
Dudarev, S. L., Botton, G. A., Savrasov, S. Y., Humphreys, C. J. & Sutton, A. P. Electron-energy-loss spectra and the structural stability of nickel oxide: An LSDA+U study. Phys. Rev. B 57, 1505–1509 (1998).
Sun, J., Ruzsinszky, A. & Perdew, J. P. Strongly constrained and appropriately normed semilocal density functional. Phys. Rev. Lett. 115, 036402 (2015).
Acknowledgements
This work was supported by the U.S. Department of Energy (DOE), Office of Science (OS), Office of Basic Energy Sciences, Division of Materials Science and Engineering, under grant no. DE-FG02-07ER46383 (T.C.C.). F.C.C. acknowledges support from the National Center for Theoretical Sciences and the Ministry of Science and Technology of Taiwan under grants no. MOST-107-2628-M-110-001-MY3. He is also grateful to the National Center for High-Performance Computing for computer time and facilities. This research used resources of the ALS, which is a DOE Office of Science User Facility under Contract No. DE-AC02-05CH11231.
Author information
Authors and Affiliations
Contributions
J.A.H., M.K.L., and T.C.C., with the aid of Y.L., performed the MBE growths. L.Y.F. and F.C.C. with R.A.B.V. performed the first-principles calculations. J.A.H., M.K.L., and T.C.C., with the help of R.Y.L., P.C., and S.K.M., conducted the synchrotron measurements and/or ARPES characterizations at the University of Illinois. J.A.H., M.K.L., and T.C.C. analyzed the data. J.A.H. and T.C.C. wrote the paper. T.C.C., F.C.C., J.A.H., L.Y.F., M.K.L., and R.A.B.V. interpreted the data. J.A.H., L.Y.F., and M.K.L. contributed equally and are co-first authors; T.C.C. and F.C.C. are the corresponding authors. T.C.C. led the experimental group; F.C.C. led the theory group. T.C.C. organized the project.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Hlevyack, J.A., Feng, LY., Lin, MK. et al. Dimensional crossover and band topology evolution in ultrathin semimetallic NiTe2 films. npj 2D Mater Appl 5, 40 (2021). https://doi.org/10.1038/s41699-021-00218-z
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41699-021-00218-z
- Springer Nature Limited