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Spin-resolved band structure of heterojunction Bi-bilayer/3D topological insulator in the quantum dimension regime in annealed Bi2Te2.4Se0.6

  • Scientific Reports 7, Article number: 45797 (2017)
  • doi:10.1038/srep45797
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Two- and three-dimensional topological insulators are the key materials for the future nanoelectronic and spintronic devices and quantum computers. By means of angle- and spin-resolved photoemission spectroscopy we study the electronic and spin structure of the Bi-bilayer/3D topological insulator in quantum tunneling regime formed under the short annealing of Bi2Te2.4Se0.6. Owing to the temperature-induced restructuring of the topological insulator’s surface quintuple layers, the hole-like spin-split Bi-bilayer bands and the parabolic electronic-like state are observed instead of the Dirac cone. Scanning Tunneling Microscopy and X-ray Photoemission Spectroscopy measurements reveal the appearance of the Bi2 terraces at the surface under the annealing. The experimental results are supported by density functional theory calculations, predicting the spin-polarized Bi-bilayer bands interacting with the quintuple-layers-derived states. Such an easily formed heterostructure promises exciting applications in spin transport devices and low-energy electronics.


Topological insulator (TI) phase, realized in materials with strong spin-orbit interaction, became one of the most intriguing topics in condensed matter physics. TIs are bulk band insulators but have the metallic Dirac cone-like edge states protected by time-reversal symmetry. The conception of TIs can be realized in three-dimensional (3D) and two-dimensional (2D) materials1,2. The key feature of the topological surface/edge states is the spin-momentum locking that is extremely useful in relation to possible applications in spintronics and nanoelectronics1,3,4,5,6,7. Noteworthy, 2D TIs have an advantage over 3D TIs in spin transport devices because of the two well-defined directions for moving of electrons via the 1D metallic edge states8,9. Additionally, the contact of 2D and 3D TIs is of particular interest owing to the interplay of 2D and 1D spin transport channels. Such topological heterostructures have been grown and studied in several systems10,11,12,13,14 including graphene15,16,17, which can be turned to topological phase via contact with heavy atoms18.

Recently a single-bilayer Bi (111) ultrathin film has been revealed as the most promising 2D TI, since it has the well localized edge states in contrast to the HgTe quantum well19,20,21. Furthermore, the Bi-bilayer contacted with 3D TI in the quantum dimension regime has recently been proposed to be a platform for topological edge mode-based transistor21. The crystal structure and the in-plane lattice constant is similar for Bi(111) and most of 3D TIs (e.g. Bi2Te3). It allows to grow the epitaxial 2D/3D TIs heterostructures and electronic and spin properties of MBE grown Bi bilayer on 3D TIs have been investigated10,11,12,13,22,23,24. For the fabrication purposes, the relatively easier way to produce the Bi bilayer film on bismuth chalcogenides by the sample annealing have recently been developed in refs 25 and 26. By means of STM authors have measured detailed surface morphology and local density of states and revealed the Bi bilayer formation at the surface of Bi2Te3 as a result of annealing. However, to unveil the topology of the surface and interface states direct electronic and spin structure measurements are required.

In this work, we study the surface restructuring of 3D topological insulator Bi2Te2.4Se0.6 (BTS) under the brief annealing. Scanning tunneling microscopy (STM) and X-ray Photoemission Spectroscopy (XPS) measurements reveal the transformation of the surface quintuple layers (QLs) and appearance of Bi-bilayer terraces as a result of the annealing of the sample up to 400 °C. By means of Spin- and Angle-Resolved Photoemission Spectroscopy (SARPES) we study the alteration of the Dirac cone-like electronic structure near the Fermi level of the annealed BTS. Owing to the evaporation of the Te and Se atoms at the surface, the Dirac cone-like surface state is replaced by the parabolic electron-like band derived from non-destroyed QLs and hole-like Bi-bilayer bands. DFT calculations and spin resolved spectra show the spin polarization of these states, and the effects of hybridization between them.

Results and Discussion

Most of the 3D topological insulators, such as bismuth chalcogenides, are characterized by the layered crystal structure1,27. Thus, Bi2Te3 consists of Bi and Te atomic layers, stacked to each other, forming quintuple layer blocks (QLs) separated by the van der Waals spacing. However, the Bi2Te3 and related binary TIs are naturally n-type compounds with the Fermi level lying in the bulk conduction band. An addition of the third component and using of the fractional stoichiometry leads to the shifting of the Dirac point and tuning of the Fermi level inside the bulk energy gap. In refs 27 and 28 it has been shown that the compound Bi2Te2.4Se0.6 (BTS) exhibits the pronounced Dirac cone-like topological surface states (TSS), with the Dirac point located at the binding energy of 0.3 eV. In this system the Se atoms substitute the Te atoms preferably at the middle layer of QL.

Figure 1a presents the STM image of the pristine fresh cleaved Bi2Te2.4Se0.6 sample. Three large terraces with the steps of 9 Å height are clearly seen, in accordance with the STM measurements of the similar bismuth chalcogenides systems, where typical thickness of QL is of 9–10 Å.

Figure 1
Figure 1

(a) Constant-current STM images of the cleaved pristine surface of Bi2Te2.4Se0.6 (set point values V = +1.32 V, I = 5 pA), (b) 300 °C annealed sample (V = +1.34 V, I = 10 pA) and (c) 400 °C annealed sample (V = +1.34 V, I = 5 pA). (d) Scheme of the Bi-bilayer formation at the surface of Bi2Te2.4Se0.6 under the annealing. Bi and Te/Se layers are shown by red and blue colors, respectively. (e) XPS Bi 5d spectra of the cleaved pristine (top) and annealed at 400 °C Bi2Te2.4Se0.6 (bottom). Data obtained with a photon energy of 120 eV at the normal emission. (f) Height profile along the blue line in (c) revealing the presence of the terraces with different step height due to the Bi-bilayer formation.

At the surface this quintuple-layer structure can be strongly modified by the short annealing of the sample. As noted above, the temperature-induced formation of the Bi-bilayer had been shown at the surface of Bi2Te3 in ref. 25. Possible explanation of the structural modification is the thermal desorption of Te atoms. Similar behavior with a Se atoms desorption have been observed in Bi2Se329. Moreover, according to the phase diagrams, at temperatures of 300–400 °C the Bi-rich compounds, such as Bi4Te3 are more stable30,31.

Structural properties of Bi2Te2.4Se0.6 are the same as for Bi2Te3 and thus, the thermal-induced Bi-bilayer formation can also be expected. The STM image of the Bi2Te2.4Se0.6 surface after the annealing at 300 °C is shown in Fig. 1b. It’s seen that in addition to the large quintuple-layer terraces the holes with the depth of 6 Å appear due to evaporation of Te and Se atoms. The holes with the depth of 9 Å are also visible, that corresponds to the whole quintuple-layer removal. After the annealing at 400 °C the Bi-bilayer terraces become larger and more pronounced, as seen in Fig. 1c.

Schematically the process is shown in Fig. 1d, where the QL terrace consisting of the Bi (red) and Te/Se layers (blue) transforms to the QL and Bi-bilayer terraces. These findings can be verified by the XPS measurements of Bi 5d core levels, shown in Fig. 1e. The spectrum for the pristine sample consists of the only one component for each 5d peak, while after the annealing additional peaks can be seen with the 1 eV shift towards the higher BE. This peaks belong to the Bi-bilayer, in accordance with refs 13 and 32. Noteworthy, under the annealing at 400 °C one can see the complete destroying of the first surface QL with the Bi2 terraces formation and the appearance of the Bi2 areas at the surface of second QL (see the profile in Fig. 1f).

Temperature-induced restructuring of the surface layers results in dramatic changes of the surface band structure. Experimental dispersion relations of the electronic states of the pristine and annealed Bi2Te2.4Se0.6 are shown in Fig. 2. First of all, the parabolic band with the minimum at the BE of 0.65 eV appears instead of the Dirac cone formed by TSS. Similar dispersion relations of the electronic states have been observed for the ultrathin films of 3D topological insulators33 and in Bi4Se313, where QLs are separated by the Bi-bilayers. Such a behaviour is based on the interaction between the two surfaces of 3D TI in quantum tunneling regime34. In our annealed Bi2Te2.4Se0.6 this effect can be explained by: 1) the increase of the van-der-Waals spacing and detachment of the surface QLs from the bulk as a result of the annealing or 2) the formation of the different structural phase at the surface, similar to BiTe and Bi4Te330,31.

Figure 2
Figure 2

(a) ARPES images of the pristine cleaved and (b) 400 °C annealed Bi2Te2.4Se0.6 sample. Data collected using a photon energy of 17 eV and a linear polarization of light. The second derivatives of N(E) are presented for the better visualization of the states dispersion. The red lines present the emission angles, which were used for spin-resolved data in Fig. 3c. (c) Full ARPES 3D mapping in k-space of the 400 °C annealed sample.

Full ARPES k-space map of the electronic states of the annealed BTS near the point is presented in Fig. 2c. The Fermi surface is characterized by hexagonal snowflake shape, with the bunches pointed along the direction. Hexagonal warping of the Dirac cone, observed in a number of 3D TIs27,35 originates from the mixing of the TSS with the bulk conduction band. Owing to the high binding energy of the parabolic band minimum in our annealed system, warping leads to the huge differences of the group velocities at the Fermi level, being 4.6×105 m/s for the and zero for the directions. This structure could give rise to such phenomena as anisotropic spin-polarized transport or density of states singularity in TIs36.

Besides the parabolic QLs-derived band the spectrum of the annealed Bi2Te2.4Se0.6 exhibits the additional broad hole-like state, dispersing from 0.6 eV at k|| = 0.4 Å−1 to 0.1 eV at the point. In accordance with refs 10, 37 and 38 this states can be related to the Bi-bilayer, formed on top of TI. Moreover, at the BE of 0.2–0.4 eV the blurring of the QL and Bi2 derived states dispersions is observable, that can be explained by the hybridization between them.

In order to understand the peculiar behavior of the annealed TI electronic states we have performed ab initio calculations of the Bi-bilayer contacting with the single QL of TI. To treat the atomic structure of Bi2Te2.4Se0.6 Se atoms had been homogeneously distributed over three Te layers within QL in accordance with ref. 27. The calculated band dispersions along the direction are superimposed on the ARPES image of the annealed sample in Fig. 3a. In accordance with the ARPES measurements one can see an electron-like band, localized in QL with the BE of 0.7 eV at the point. The Bi-bilayer states have a hole-like dispersion, and mix with the QL states at the BE region 0.2–0.4 eV.

Figure 3
Figure 3

(a) The ARPES image of annealed Bi2Te2.4Se0.6 sample taken along the direction. The superimposed violet lines represent DFT calculated band structure of the Bi-bilayer on top of Bi2Te2.4Se0.6 QL. (b) The calculated spin resolved band structure with red (yellow) and blue (cyan) symbols corresponding to the in-plane spin polarization of the states localized at the Bi-bilayer (QL). (c) Spin-resolved ARPES spectra taken at the emission angles, corresponding to the red lines in Fig. 2(b), obtained using a photon energy of 17 eV.

The avoided-crossing hybridization effects between the Bi2 and QL states are clearly seen in the calculated band structure. In the experimental image the mixing of the states is less pronouced and the hybridization gaps are much smaller. This difference can be explained by several factors. First, the ARPES spectra include the signal from the bulk bands. The DFT calculated band structure with the inclusion of several Bi2Te3 QL is shown in Fig. 1S in Supporting Infromation. One can see that the bulk states are partially located in the region of avoided-crossing gaps and can blur the resulting experimental dispersions. The second reason of the weaker hybridization between the Bi2 and QL states in the experiment is the presence of the QL terraces without the Bi2 on top (see Fig. 1c). The photoemission spectra contain the signals from terraces both with and without Bi2 and the summed image appears to have a smaller mixing of the states.

The hybridization effects result in the modification of the spin structure of the system. The calculated spin resolved band structure is shown in Fig. 3b. The spin polarization of the QL state and the spin splitting of the Bi states are clearly visible. At the hybridization points, the spin-dependent avoided-crossing effects take place, leading to the modulation of the spin structure.

Figure 3c shows the spectra obtained by means of APRES with spin resolution at the emission angles, corresponding to the gray lines in Fig. 2b. One can distinguish the pronounced spin polarization of the QL and Bi states, which are inverted for the opposite wave vectors, meaning the spin-orbital character. Similar spin structure has been observed for the Bi-bilayer on top of the various substrates12,39. Meanwhile, the spin-dependent hybridization effects in the experiment are less pronounced than in Fig. 3b owing to the several reasons, noted above.

Thus, the Dirac cone in Bi2Te2.4Se0.6 as a result of the annealing is replaced by two hole and electron-like spin polarized bands interacting with each other. This behaviour is strongly different from those in MBE grown Bi bilayer on 3D TIs, where the Dirac cone had not been destroyed after the Bi deposition10,12,22,23,24. We relate the effect of parabolic band appearance instead of the Dirac cone to the detachment of the surface QL as a result of the annealing. In this case the detached QL can be considered as a 3D TI ultrathin film in quantum dimension regime. Noteworthy, after the new cleavage of annealed sample (i.e. deletion of several hundreds microns of the sample) the Dirac cone recovers meaning that the bulk atomic and electronic structure is not affected in any way.


In conclusion, the electronic and spin structure of the annealed topological insulator Bi2Te2.4Se0.6 has been unveiled by means of spin- and angle-resolved PES. STM and XPS measurements reveal the formation of the Bi-bilayer at the surface under the annealing due to the evaporation of the Te/Se atoms from the surface QL. It has been demonstrated that the Bi-bilayer and surface QLs are characterized by the hole-like and electron-like spin-polarized states near the point, respectively. This 2D/3D topological insulators junction can be utilized for device fabrication purposes, such as topological edge-mode transistors or topological p-n junctions. Relatively easy formation way allows to create locally the regions with 2D TI on the surface of 3D TI using controlled annealing, for example by applying tip or laser.


The n-doping samples with stoichiometry of Bi2Te2.4Se0.6 were grown from a presynthesized mixture of Bi2Te3 and Bi2Se3 by a modified vertical Bridgman method40. Monocrystals had been cleaved in ultrahigh vacuum (UHV) conditions (base pressure 1 × 10−10 mbar) before the measurements. The annealing process had been carried out in situ in UHV conditions during 30 min. The crystal quality and surface cleanliness had been verified by low energy electron diffraction and x-ray photoelectron spectroscopy. The experiments were carried out at Helmholtz-Zentrum Berlin (BESSY II) at beamlines UE112-SGM and U125/2-SGM with linearly polarized light with using Scienta R4000 energy analyzer and Mott spin detector operated at 26 keV. The angle of light incidence on the sample under normal emission was 45° relative the surface normal. The diameter of the light spot on the sample was about 50 μm. STM and preliminary ARPES measurements have been carried out in Resource Center of St.-Petersburg State University “Physical methods of surface investigations”. Several tungsten tips for STM measurements were examined with the scanning electron microscope and then a sharp tip was selected and prepared with a focused ion beam at the Interdisciplinary Center for Nanotechnology of Research park of Saint Petersburg State University.

The electronic band calculations for Bi-bilayer ontop of Bi2Te2.4Se0.6 quantuple layer (Fig. 3a) are performed within the density functional theory (DFT) formalism with the generalized gradient approximation (GGA) of Perdew, Burke, and Ernzerhof (PBE)41 to the exchange correlation (XC) potential. We used Hartwigsen-Goedecker-Hutter (HGH)42 relativistic norm-conserving pseudopotentials which include the spin-orbit interaction (SOI). To treat the disordered Bi2Te2.4Se0.6 we employ a virtual crystal approximation (VCA) as implemented in the abinit code43, where the configuration averaged potential of a “gray” atom occupying a site in the Te-Se sublattice is defined as a mixture VVCA = xVTe + (1 − x)VSe of Te () and Se () pseudopotentials.

Additional Information

How to cite this article: Klimovskikh, I. I. et al. Spin-resolved band structure of heterojunction Bi-bilayer/3D topological insulator in the quantum dimension regime in annealed Bi2Te2.4Se0.6. Sci. Rep. 7, 45797; doi: 10.1038/srep45797 (2017).

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The work was partially supported by grant of Saint Petersburg State University for scientific investigations (No We acknowledge the financial support of the University of Basque Country UPV/EHU (Grant No. GIC07-IT-756-13), the Departamento de Educación del Gobierno Vasco and the Spanish Ministerio de Ciencia e Innovación (Grant No. FIS2010-19609-C02-01), the Spanish Ministry of Economy and Competitiveness MINECO (Grant No. FIS2013-48286-C2-1-P) and the Tomsk State University Competitiveness Improvement Program. The calculations were performed on the SKIF-Cyberia supercomputer at Tomsk State University (Russia). The authors also acknowledge support from the Russian-German laboratory at BESSY II and the “German-Russian Interdisciplinary Science Center”(G-RISC) program.

Author information


  1. Saint Petersburg State University, 198504, Saint Petersburg, Russia

    • I. I. Klimovskikh
    • , D. Sostina
    • , A. Petukhov
    • , A. G. Rybkin
    • , S. V. Eremeev
    • , E. V. Chulkov
    • , O. E. Tereshchenko
    • , K. A. Kokh
    •  & A. M. Shikin
  2. Institute of Strength Physics and Materials Science, 634055, Tomsk, Russia

    • S. V. Eremeev
  3. Tomsk State University, 634050, Tomsk, Russia

    • S. V. Eremeev
    •  & E. V. Chulkov
  4. Donostia International Physics Center (DIPC), 20018 San Sebastián/Donostia, Basque Country, Spain

    • E. V. Chulkov
  5. Departamento de Física de Materiales UPV/EHU, Centro de Física de Materiales CFM - MPC and Centro Mixto CSIC-UPV/EHU, 20080 San Sebastián/Donostia, Basque Country, Spain

    • E. V. Chulkov
  6. A.V. Rzhanov Institute of Semiconductor Physics, 630090, Novosibirsk, Russia

    • O. E. Tereshchenko
  7. Novosibirsk State University, 630090, Novosibirsk, Russia

    • O. E. Tereshchenko
    •  & K. A. Kokh
  8. V.S. Sobolev Institute of Geology and Mineralogy, 630090, Novosibirsk, Russia

    • K. A. Kokh


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The measurements were performed by I.I.K., D.S., A.P., A.G.R., O.E.T. and A.M.S. Samples were grown and characterized by O.E.T. and K.A.K. The experimental data analysis was carried out by I.I.K., and A.M.S. DFT calculations were performed by S.V.E. and E.V.C. All authors extensively discussed the results and participated in the manuscript editing. The manuscript was written by I.I.K. and S.V.E.

Competing interests

The authors declare no competing financial interests.

Corresponding author

Correspondence to I. I. Klimovskikh.


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