Search tips
Search criteria 


Logo of nanoreslettspringer open web sitethis articlemanuscript submissionregistrationjournal front pagespringer open web site
Nanoscale Res Lett. 2012; 7(1): 560.
Published online 2012 October 9. doi:  10.1186/1556-276X-7-560
PMCID: PMC3502568

The intensive terahertz electroluminescence induced by Bloch oscillations in SiC natural superlattices


We report on efficient terahertz (THz) emission from high-electric-field-biased SiC structures with a natural superlattice at liquid helium temperatures. The emission spectrum demonstrates a single line, the maximum of which shifts linearly with increases in bias field. We attribute this emission to steady-state Bloch oscillations of electrons in the SiC natural superlattice. The properties of the THz emission agree fairly with the parameters of the Bloch oscillator regime, which have been proven by high-field electron transport studies of SiC structures with natural superlattices.

Keywords: Terahertz emission, Natural superlattice, Bloch oscillations, Wannier-Stark localization, Transport in high electrical fields, 78.66 Fd; 73.20.Dx


The possibility of oscillating motion of electrons in crystals at high field bias has attracted great interest since it was predicted [1,2]. The Bloch oscillations (BO) with frequency (ν)


where e, h, and a are the electron charge, the Plank constant, and the crystal lattice period, respectively, originate from the acceleration of electrons in an electric field and their Bragg reflection at the Brillouin zone boundary. One important condition must be satisfied to achieve the BO regime, namely:


where l is the electron mean free path, E1 is the width of the allowed electron band (the subscript 1 corresponds to the bottom electron band), and Ft is the threshold electric field of the BO regime. A thorough analysis of the electron localization effect in high electric fields [3] has revealed that the energy continuum splits into the discrete, so-called Wannier-Stark ladder states in the electric field, which are the frequency-domain equivalent of Bloch oscillations. Esaki and Tsu, in their pioneering work on semiconductor superlattices [4], pointed out that BO of electrons in superlattices with narrow minibands can be observable even for modest fields. Photocurrent, photoluminescence, and electroreflectance experiments on biased structures with artificial superlattices of GaAs/AlGaAs [5,6] have proven the existence of the Wannier-Stark localization (WSL) effect in semiconductor superlattices. The most substantial evidence for BO in artificial superlattices was found in experiments with ultrashort light pulses [7-12]. The results of [7-12] demonstrated a few cycles of BO, which, however, were damped after 1 to 2 ps. It was suggested [13] that the fast damping of BO in artificial superlattices originates from electron scattering at the interfaces of heterojunctions and also from breaking the equidistance of the Wannier-Stark levels. The fast decay of BO leaves room for doubts about the possibility of the practical application of this phenomenon [13]. Apparently, the present level of semiconductor technology cannot provide artificial superlattices with sufficient quality suitable for the creation of terahertz (THz) emitters based on BO.

One interesting system demonstrating superperiodicity and potentially having none of the aforementioned drawbacks is a natural superlattice (NSL) in SiC crystals. It is known [14,15] that all SiC polytypes, excluding the cubic 3C-SiC and hexagonal 2H-SiC, exhibit superperiodicity in the direction along the crystal c-axis in a similar way to crystals with artificial superlattices. The superperiodicity is absolutely stable and has precise crystalline parameters [14]. This superperiodicity is self-organized in the main SiC crystal lattice, and the NSL periods, d, for such polytypes as 4H-, 6H-, and 8H-SiC are equal to 5, 7.5, and 10 Å, respectively [14]. The elementary cell of the hexagonal polytype 4H-, 6H-, and 8H-SiC contains 8, 12, and 16 atoms, which is many times higher than the number of atoms in the 2H-SiC polytype elementary cell. Therefore, in accordance with the theory of Brillouin Zones (BZ) [16], the electron spectrum, for example, of the 6H-SiC crystal in the direction of the c-crystal axis should be considered in the extended BZ composed of six classical Brillouin zones of the crystal. In this case, the electron energy is not a continuous function of wave vector but undergoes breakups at certain planes in k-space. It was shown that the major energy breakups occur at 2Π/c and 4Π/c points for 6H-SiC [15], and at 2Π/c, 4Π/c, and 6Π/c points for 8H-SiC, where c is the size of the elementary cell along the c-axis. It explains the appearance of the NSL with the period d = c/2 and the miniband electron spectrum in hexagonal SiC polytypes.

Electron transport studies on SiC structures with the natural superlattices [17,18] have demonstrated pronounced effects of the negative differential conductivity (NDC) caused by the Wannier-Stark localization phenomenon. The threshold fields of the NDC onset at 300 K were found to be Ft ≈ 110 ± 25 kV/cm, Ft ≈ 150 ± 30 kV/cm and Ft ≈ 290 ± 60 kV/cm for the 8H, 6H, and 4H polytypes, respectively [18], which is in good agreement with Equation 2. It is important to note that the observed values of the NDC [18] were two orders of magnitude higher compared with that reported for artificial superlattices (see, for example, [19-21]). These results mean that there is a well-grounded hope of achieving THz emission due to the Bloch oscillations in SiC NSL. This paper reports on the experimental observation and studies of THz electroluminescence (1.5- to 2-THz spectral range) from SiC structures with a natural superlattice. We attribute this emission to the electron Bloch oscillations in the SiC natural superlattice.


Theory of electron transitions in the Wannier-Stark ladder of silicon carbide natural superlattices

The internal quantum yield of the THz emission due to optical transitions between Wannier-Stark levels in the natural superlattice of 6H-SiC was estimated. The band diagram of the 6H-SiC NSL depicted in Figure Figure11 was used for these estimations.

Figure 1
Schematic diagram of Wannier-Stark states. Schematic diagram of Wannier-Stark states in a 6H-SiC natural superlattice at a modest uniform electric field. The solid and dotted curves depict the envelope wave functions corresponding to different steps in ...

The values for the quantum well width and the energy width of the first electron miniband were taken to be consistent with the experimental data [17,18,22,23] on high-field transport in SiC natural superlattices, which have demonstrated the evolution of the fundamental stages of WSL in these systems (the transition from a relatively small field regime of Bloch oscillations to large field regimes: the Stark-phonon resonances between Wannier-Stark ladder levels, the full localization of the lowermost miniband, and inter-miniband resonance transitions between the first and second minibands). The most important results of these transport studies are summarized in Table Table11.

Table 1
Parameters of minizone transport in silicon carbide polytypes

Using the tight-binding approximation developed for such systems by Bouchard and Luban [25], the amplitude of the electron wave function can be expressed by the transfer integrals between the nearest quantum wells V1:

|nright angle bracket=l=Jln2V1eFdul(z),

where Jn is the Bessel function of the first kind, order n, and ul(z) is the wave function of the electron with the energy El = leFd in the ground state of the quantum well. Taking into account Equation 3, it is straightforward to calculate the probability of an optical transition of an electron between two adjacent quantum wells:

τrad1=4e2[variant Planck's over 2pi]ω3Π2d2(c/n)3m2,

where c/n is the speed of light in SiC, [variant Planck's over 2pi]ω = eFd is the energy of the emitted quantum, and m is the electron effective mass. We suppose that the electric field is insufficient for the inter-miniband resonant tunneling of the electrons, and the major nonradiative process is the transition between the nearest Wannier-Stark states with the emission of the longwave acoustic phonons. The corresponding probability of the nonradiative process is

τnonrad1=Ξ22m(eFd)5/2Π3d[variant Planck's over 2pi]3s3ρV1,

where Ξ is the deformation potential constant, s is the speed of sound, and ρ is the SiC material density. The formula (5) is applicable only for a low electric field, which satisfies eFd[double less-than sign]2Πs[variant Planck's over 2pi]d. There are two factors determining the strong dependence of τnonrad1 on the electric field. Firstly, the conservation laws limit the phonon wave vectors to small values in the weak electric fields. Secondly, the electron wave function involves many quantum wells, in this work ( E1eFd40), and the contributions ul(z) from different quantum wells partly compensate each other. The internal quantum yield, η, of the THz emission is


where L is the NSL thickness.

Experimental content

The samples studied in this work were unipolar 6H-SiC n + n n + diode structures. The n epitaxial layer (the base of the diode) was grown by the sublimation on-axis method [26] on a 6H-SiC (0001) Lely substrate, which had Nd Na ≈ 2 × 1018cm−3 and a thickness of 200 μm. The base had a donor concentration of 1015cm−3 < Nd Na < 1016cm−3, and the thickness was varied in the interval of 2 to 4 μm. The 6H-SiC polytype of the epitaxial layer and its acceptable doping homogeneity were confirmed by X-ray diffraction, photoluminescence microscopy, and C-V measurements. The latter measurements were done using auxiliary Schottky barriers created on the n layer surface. The top n + layer with NdNa ≈ 1020cm−3 was fabricated on the n epitaxial layer by ion implantation of nitrogen with subsequent annealing. Finally, the cylindrical mesa-structures with a diameter of 50μm (S = 2.0 × 10−5cm2) and cruciform mesa-structures (S = 3 × 10−5cm2) (Figure (Figure2a)2a) were made by dry etching after photolithography. For a contact, a sputtered and annealed (900°C) nickel film with a thickness of 0.2 μm was used. A common contact area was located on the upper surface of the substrate. Insulator layers were created by proton implantation on the mesa-periphery and on the upper surface of the substrate. In accordance with the aforementioned property of the 6H polytype of SiC crystals, such a diode structure was a natural supperlattice as a whole.

Figure 2
General view of the structures. (a) General view of the structures used for THz measurements. (b) Geometry of the experiment.

The samples suitable for THz electroluminescence experiments were chosen from a number of the prepared mesa-structures by means of analyzing their I-V characteristics at 300 K. The criterion for making this choice was the observation of a mobile high-field domain, which thereby confirmed the development of the WSL effect in the mesa-structure [27]. The small mesa size contributed to a higher yield of high-quality structures. The diode structures selected in this way were used for investigations of the terahertz emission at liquid helium temperatures. Low temperatures are preferable for this kind of experiments because the intensity of electron scattering is reduced. Furthermore, the very low carrier density at helium temperatures and the small thickness of the n layer contributed to a reduction in the probability of domain formation.

For the low-temperature experiments, the samples were placed on an insulating p-type SiC base. After silver wire bonding, the assembly was mounted on the cold finger of an optical cryostat, which was optimized for the THz spectral domain. The geometry of the available structures only permitted the observation of THz radiation though the substrate. Parabolic mirror optics were used to collect the THz emission in the direction normal to the substrate surface within a solid angle of ≈30° (Figure (Figure2b).2b). Polarization of the emission was not expected in this geometry of the experiment, and therefore, all measurements were made in the regime of integrated polarization.

The sample under test was fed with a train of eight pulses, where each pulse in the train was 1 μs in duration with a 950-μs time interval between the pulses. It was paused in 7 μs, after which the next train was begun. Thus, the repetition rate was about 75 Hz. Such a bias was used to minimize lattice heating effects. The duty cycle of the train was 50% at a frequency of 75 Hz. Such a bias was used to minimize lattice heating effects. The spectral measurements were performed with a spectral resolution of 0.6 meV using a Fourier spectrometer operating in the step-scan mode described elsewhere [28]. To eliminate any influence of water vapor absorption, the internal volume of the spectrometer was evacuated down to a residual pressure level of 6 × 10−2 Torr. The THz emission signal was measured using a liquid-helium-cooled silicon bolometer and a lock-in amplifier.

Results and discussion

An intensive THz signal was detected at bias voltages exceeding 190 to 195 V. The existence of such a threshold voltage for the THz emission can be explained by the impurity breakdown in the top n + -SiC layer, which is required for injection of electrons into the NSL. Upon reaching the breakdown of the top layer of the structure, the bias voltage becomes redistributed, and some part of it starts to drop to the base of the structure (n layer). At the same time, the intensity of the THz emission begins to grow almost linearly with increases in current. The I-V characteristic of the 6H-SiC n + nn + diode structures and the dependence of the intensity of THz emission on the current are demonstrated in Figure Figure33 (insert). The current is practically absent at voltages below ≈180 V due to extremely small carrier concentration in the active region of the structure at helium temperatures, and the current appears only as a result of the electron injection from the top n + layer.

Figure 3
Spectra of the THz emission. Spectra of the THz emission from the cruciform SiC mesa-structure at several bias voltages. T ≈ 7 K. The spectra werre corrected for the spectral response of the measurement system, normalized to the emission maximum, ...

Taking into account the precise calibration of the detector used here with the emission of a black body source and also the measured attenuation factor of the experimental instrumentation, we can conclude that the spectrally integrated THz emission peak power for the SiC mesa-structure is about 10μW at 46.2 W of peak pumping power (0.21 A, 220 V). The corresponding external quantum yield of the THz emission is about 0.01 THz photons/electron. Estimations of the internal quantum yield ( Equation 6) of the THz emission for the 6H-SiC structures studied here with a NSL thickness of 2μm result in a value of η=Ld×τrad1/τnonrad12,667×(1.8×105s1/1.3×1010s1)0.04. This value is in reasonable agreement with the experiment if the non-optimality of the experimental geometry is taken into account.

In Figure Figure3,3, a set of THz electroluminescence spectra measured at different amplitudes of the bias voltage are demonstrated. It is seen that the THz emission spectrum consists practically of a single line, the maximum of which evidently shifts to higher frequencies with increases in the bias voltage. The shift in the emission maximum is in the order of 1.5 meV as the bias is varied from 200 to 255 V. The spectrally integrated THz emission power is about 26 μW for the amplitude of the bias voltage of 255 V (see Figure Figure33).

As seen from Figure Figure4,4, the shift of the THz emission peak versus the bias voltage can be well approximated by linear law with a gradient of ≈32μeV/V. It is important to note that the FWHM of the emission line is almost constant and equal to ≈2.9 meV (0.7 THz) as the bias voltage varies from 200 to ≈240 V (Figure (Figure3).3). The shape of the emission spectrum at high bias voltages (255 V and higher) is caused by the superposition of two emission bands. The first of them pertains to the above mentioned series of Bloch emissions at about 6 to 7 meV. The maximum of the second emission band is at about 13 meV. The manifestation of this band can be seen on spectral line at 255 V voltages. We tentatively attribute this band at ≈13 meV to the optical transition of electrons over the next Wannier-Stark ladder state in the high-field-biased NSL of SiC. We have to note that a more detailed theoretical analysis is required for precise interpretation of the experimental findings. At this moment, it is important to underline that similar spectra have been observed for 4H- and 8H-SiC NSL structures, and its spectral features correlate with aforementioned miniband widths and periods of NSL in 4H-, 6H-, and 8H-SiC.

Figure 4
Dependencies of the peak position on the bias voltage. Dependences of the peak position of the THz emission line and the emission line width on the bias voltage. The solid line corresponds to a linear fit of the experimental emission maximum (Emax) versus ...

The experimental data allow the observed THz electroluminescence to be attributed to spontaneous radiation resulting from electron Bloch oscillations in a SiC natural superlattice. Using Equation 1 and the fact of the linear dependence of the emission peak position on the bias voltage for the 6H-SiC structures with NSL, the electric field strength F required for the BO can be estimated. The estimations give F in the order of 8.5 × 104V/cm (at 200 V), which is slightly less than the magnitude of Ft for the BO regime obtained from high-field transport measurement data at 300 K on 6H-SiC (see above). However, the agreement between the electric fields is quite reasonable if an increase of the electron scattering time at 7 K compared to its value at 300 K and a corresponding decrease of the threshold field of the BO regime are taken into account. The value of the electric field F implies that only a small part (less than 10%) of the bias voltage drops on the base of the structure. The main voltage drops are on the top n + layer for supporting of the impurity breakdown, on the substrate, and also partly on the contact regions. Nevertheless, the voltage drop on the nlayer (and hence the electric field F) is proportional to the total bias voltage, and this causes the observed linear dependence of the emission peak on the bias (Figure (Figure4).4). It is necessary to add that the experimental geometry used (Figure (Figure2b)2b) was far from optimal since only a small fraction of the THz emission, mainly propagating along the substrate plane, can be collected in this configuration. Therefore, in the case of an optimal geometry (i.e., observation from the side facet of the structure or from the top and using a diffraction grating deposited on the n + layer), the expected external quantum yield of the THz emission should be higher by some times.

It necessary to point out that Equation 5 also describes the I-V characteristic of the active region of the structure in a regime when the Wannier-Stark ladder states are well formed, and the electron transport is controlled by nonradiative transitions of electrons between the Wannier-Stark levels. In this case, the I-V characteristic should obey the I[proportional, variant]F5/2 dependence and not have a region of NDC. The sharp increase of the current (see Figure Figure1)1) through the structure under the test excludes the existence of high field domains in the structure in the region of the temperatures and electric fields used in our experiment.

We have measured the polarization properties of the THz emission on specially designed n + nn + structures allowing for the emission observation from a side facet. It was found that the emission is linearly polarized along the c-crystal axis (along the electric field), and the polarization degree attains 50% at least.


The previous results on the observation of Wannier-Stark quantization of electrons in silicon carbide NSLs obtained from transport experiments have given a hope of obtaining THz emission in this system. The new experimental data serve as evidence of the existence of steady-state THz radiation induced by Bloch oscillations. The intensive THz emission in the spectral range 1.5 to 2 THz has been found out. The previous papers [13,14,16-18] reported only three to four Bloch oscillation cycles, which were observed using ultrashort laser pulse excitations in different artificial superlattices, where the oscillations were damped after a few picoseconds. The properties of a NSL in SiC crystals allow study-state Bloch oscillations to be achieved under purely electrical excitation. In our opinion, the key factors enabling the achievement of the steady-state Bloch oscillations are the absence of heterointerfaces in SiC NSL and the possibility of electron transport along the sufficiently broad first miniband.

To summarize, THz emission due to electron Bloch oscillations in the steady-state regime has been observed for the first time. The experiments were performed on SiC structures with natural superlattice under electrical pumping. In combination with earlier reported high-field transport data [17,18,22-24] demonstrating the evolution of the fundamental stages of WSL in SiC natural superlattices, the presented results constitute substantial proof of the pronounced Wannier-Stark localization effect in solid-state objects. It is necessary to add that SiC with natural superlattices opens new possibilities for perspective research in the area of high-field transport phenomena. The discovered intensive THz electroluminescence with a variable frequency can find practical applications for electrically tunable THz emitters. The considerable variation of the emission frequency from 0.3 to 3 THz can be attained through the choice of SiC polytype with appropriate parameters for the superlattice: the highest emission frequency can be achieved with 4H-SiC, but for the lowest emission frequency, any polytype can be chosen from the row of 15R-SiC, 21R-SiC, 27R-SiC, 33R-SiC, and so on.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

VS conceived, designed, and coordinated the study, determined the directions of investigations, and wrote the manuscript. AA determined the technology of THz optical investigations and wrote the manuscript. AP carried out the theoretical analysis of THz transition physics in Bloch oscillation regime and wrote the manuscript. AZ carried out the optical measurements. AL carried out the electrical measurements of the experimental structures. PS carried out all cycles of electrical contact fabrication to experimental structures. All authors read and approved the final manuscript.


The authors would like to thank Pr’s N.S. Averkiev, Yu. L. Ivanov, V.V Kveder, and Dr. A.M. Monachov for their fruitful discussions, Dr. A.A. Maltsev for providing us with the necessary crystals with epitaxial layers, and Dr. A.G. Ostroumov for his help in the preparation of the experiment. This work was partially supported by the Russian Foundation of Basic Research and the Program of the Russian Academy of Sciences # 27.


  • Bloch F. Quantum mechanics of electrons in crystal lattices. Z Phys. 1928;52:555–600.
  • Zener C. A theory of the electrical breakdown of solid dielectrics. Proceedings of the Royal Society of London. Series A. 1934;145(855):523–529. doi: 10.1098/rspa.1934.0116. [Cross Ref]
  • Wannier GH. Wave functions and effective Hamiltonian for Bloch electrons in an electric field. Phys Rev. 1960;117(2):432–439. doi: 10.1103/PhysRev.117.432. [Cross Ref]
  • Esaki L, Tsu R. Superlattice and negative differential conductivity in semiconductors. IBM J Res and Dev. 1970;14:61–65.
  • Bleuse J, Bastard G, Voisin P. Electric-field-induced localization and oscillatory electro-optical properties of semiconductor superlattices. Phys Rev Lett. 1988;60(3):220–223. doi: 10.1103/PhysRevLett.60.220. [PubMed] [Cross Ref]
  • Mendez EE, Agulló-Rueda F, Hong JM. Stark localization in GaAs-GaAlAs superlattices under an electric field. Phys Rev Lett. 1988;60:2426–2429. doi: 10.1103/PhysRevLett.60.2426. [PubMed] [Cross Ref]
  • Feldmann J, Leo K, Shah J, Miller DAB, Cunningham JE, Meier T, von Plessen G, Schulze A, Thomas P, Schmitt-Rink S. Optical investigation of Bloch oscillations in a semiconductor superlattice. Phys Rev B. 1992;46:7252–7255. doi: 10.1103/PhysRevB.46.7252. [PubMed] [Cross Ref]
  • Leo K, Bolivar PH, Brüggemann F, Schwedler R, Köhler K. Observation of Bloch oscillations in a semiconductor superlattice. Solid State Commun. 1992;84(10):943–946. doi: 10.1016/0038-1098(92)90798-E. [Cross Ref]
  • Cho GC, Dekorsy T, Bakker HJ, Kurz H, Kohl A, Opitz B. Bloch oscillations in In-Ga-As-P/In-Ga-As-P heterostructures observed with time-resolved transmission spectroscopy. Phys Rev B. 1996;54:4420–4423. [PubMed]
  • Lyssenko VG, Löser F, Hasche T, Leo K, Dignam MM, Köhler K, Valušis G. Direct measurement of the spatial displacement of Bloch-oscillating electrons in semiconductor superlattices. Phys Rev Lett. 1997;79:301–304. doi: 10.1103/PhysRevLett.79.301. [Cross Ref]
  • Waschke C, Roskos HG, Schwedler R, Leo K, Kurz H, Köhler K. Coherent submillimeter-wave emission from Bloch oscillations in a semiconductor superlattice. Phys Rev Lett. 1993;70:3319–3322. doi: 10.1103/PhysRevLett.70.3319. [PubMed] [Cross Ref]
  • Shimada Y, Hirakawa K, Odnoblioudov M, Chao KA. Terahertz conductivity and possible Bloch gain in semiconductor superlattices. Phys Rev Lett. 2003;90:046806. [PubMed]
  • Leo K. Interband optical investigation of Bloch oscillations in semiconductor superlattices. Semicond Sci and Technol. 1998;13(3):249–263. doi: 10.1088/0268-1242/13/3/003. [Cross Ref]
  • Verma AR, Krishna P. Polymorphism and Polytypism in Crystals. Wiley, New York; 1966.
  • Choyke W, Patrick L. Exciton recombination radiation and phonon spectrum of 6H SiC 6H-SiC. Phys Rev. 1962;127:1868–1877. doi: 10.1103/PhysRev.127.1868. [Cross Ref]
  • Jones H. The Theory of Brillouin Zones and Electronic States in Crystals. North-Holland Publishing Company, Amsterdam; 1960.
  • Sankin V, Naumov A. The Wannier-Stark effect and N-shape volt-ampere characteristics in a superlattice of 6H-silicon carbide. Superlattices and Microstruct. 1991;10(3):353–356. doi: 10.1016/0749-6036(91)90340-W. [Cross Ref]
  • Sankin V, Stolichnov I. Negative differential conduction in the Bloch oscillations regime in the hexagonal silicon carbide polytypes 4H, 6H and 8H. Superlattices and Microstruct. 1998;23(5):999–1004. doi: 10.1006/spmi.1996.0571. [Cross Ref]
  • Sibille A, Palmier JF, Wang H, Mollot F. Observation of Esaki-Tsu negative differential velocity in GaAs/AlAs superlattices. Phys Rev Lett. 1990;64:52–55. doi: 10.1103/PhysRevLett.64.52. [PubMed] [Cross Ref]
  • Beltram F, Capasso F, Sivco DL, Hutchinson AL, Chu SNG, Cho AY. Scattering-controlled transmission resonances and negative differential conductance by field-induced localization in superlattices. Phys Rev Lett. 1990;64:3167–3170. doi: 10.1103/PhysRevLett.64.3167. [PubMed] [Cross Ref]
  • Grenzer J, Ignatov AA, Schomburg E, Renk KF, Pavel’ev DG, Koschurinov Y, Melzer B, Ivanov S, Schaposchnikov S, Kop’ev PS. Microwave oscillator based on Bloch oscillations of electrons in a semiconductor superlattice. Ann der Phys. 1995;507(3):184–190. doi: 10.1002/andp.19955070304. [Cross Ref]
  • Sankin V. Strong field electron transport in silicon carbide superlattice. Superlattices and Microstruct. 1995;18(4):309. doi: 10.1006/spmi.1995.1116. [Cross Ref]
  • Sankin V. Wannier-Stark localization in the natural superlattice of silicon carbide polytypes. Semiconductors. 2002;36:717–739. doi: 10.1134/1.1493739. [ doi:10.1134/1.1493739] [Cross Ref]
  • Sankin V, Lepneva A. Electron saturated vertical velocities in silicon carbide polytypes. Mater Sciency Forum. 2000;338-342:769–772.
  • Bouchard AM, Luban M. Bloch oscillations and other dynamical phenomena of electrons in semiconductor superlattices. Phys Rev B: Condens Matter and Mater Phys. 1995;52(7):5105–5123. doi: 10.1103/PhysRevB.52.5105. [PubMed] [Cross Ref]
  • Maksimov A, Mal’tsev A, Yushin N, Nikitina I. Sublimation epitaxy of 6H and 4H-SiC on one-inch silicon carbide single-crystal substrates obtained from bulk ingots. Tech Phys Lett. 1995;21:301–303.
  • Sankin V, Shkrebii P, Savkina N, Kuznetsov N. New Wannier-Stark localization effects in natural 6H-SiC superlattice. JETP Lett. 2003;77:34–38. doi: 10.1134/1.1561978. [ doi:10.1134/1.1561978] [Cross Ref]
  • Andrianov A, Zakhar’in A, Yassievich I, Zinov’ev N. Terahertz electroluminescence under conditions of shallow acceptor breakdown in germanium. JETP Lett. 2004;79:365–367. doi: 10.1134/1.1772432. [ doi:10.1134/1.1772432] [Cross Ref]

Articles from Nanoscale Research Letters are provided here courtesy of Springer