A Comparative Analysis of BaTiO3/(Ba,Sr)TiO3 and BaTiO3/(Ba,Sr)TiO3/SrTiO3 Artificial Superlattices via Raman Spectroscopy

Maslova, Olga Aleksandrovna; Yuzyuk, Yuri Ivanovich; Ortega, Nora; Kumar, Ashok; Katiyar, Ram; Barannikova, Svetlana Aleksandrovna

doi:10.1590/1980-5373-MR-2018-0389

Abstract

BaTiO₃/Ba₅₀Sr₅₀TiO₃ and BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ superlattices are characterized via Raman spectroscopy. Special attention is paid to a comprehensive analysis of their polarized Raman spectra, especially, within a soft mode (E(1TO)) range. The shift of E(1TO) soft mode is found to be more pronounced for BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ sample than for BaTiO₃/Ba₅₀Sr₅₀TiO₃, presumably owing to stronger 2D compression of BT layers and abruptly increased temperature of transition from ferroelectric to paraelectric phase.

Keywords
BaTiO₃/Ba₅₀Sr₅₀TiO₃; BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ ferroelectric superlattices; soft mode; Raman spectroscopy; strain

1. Introduction

Over the last two decades, the extensive study of structure and properties of artificial ferroelectric superlattices (SLs) ¹1 Tabata H, Tanaka H, Kawai T. Formation of artificial BaTiO3/SrTiO3 superlattices using pulsed laser deposition and their dielectric properties. Applied Physics Letters. 1994;65(15):1970.

2 Marrec FL, Farhi R, El Marssi M, Dellis JL, Karkut G, Ariosa D. Ferroelectric PbTiO3/BaTiO3 superlattices: Growth anomalies and confined modes. Physical Review B. 2000;61(10):R6447.

3 Neaton JB, Rabe KM. Theory of polarization enhancement in epitaxial BaTiO3/SrTiO3 superlattices. Applied Physics Letters. 2003;82(10):1586-1588.

4 Das RR, Yuzyuk YI, Bhattacharya P, Gupta V, Katiyar RS. Folded acoustic phonons and soft mode dynamics in BaTiO3/SrTiO3 superlattices. Physical Review B. 2004;69(13):132302.

5 Diéguez O, Rabe KM, Vanderbilt D. First-principles study of epitaxial strain in perovskites. Physical Review B. 2005;72(14):144101.

6 Nakhmanson SM, Rabe KM, Vanderbilt D. Polarization enhancement in two- and three-component ferroelectric superlattices. Applied Physics Letters. 2005;87(10):102906.

7 Harigai T, Nam SM, Kakemoto H, Wada S, Saito K, Tsurumi T. Structural and dielectric properties of perovskite-type artificial superlattices. Thin Solid Films. 2006;509(1-2):13-17.

8 Stephanovich VA, Luk'yanchuk IA, Karkut MG. Domain-Enhanced Interlayer Coupling in Ferroelectric/Paraelectric Superlattices. Physical Review Letters. 2005;94(4):047601.

9 Lebedev AI. Properties of BaTiO3/BaZrO3 ferroelectric superlattices with competing instabilities. Condensed Matter arXiv. 2013;1304:7596.

10 Bousquet E, Dawber M, Stucki N, Lichtensteiger C, Hermet P, Gariglio S, et al. Improper ferroelectricity in perovskite oxide artificial superlattices. Nature. 2008;452(7188):732-736.

11 Kim L, Jung D, Kim J, Kim YS, Lee J. Strain manipulation in BaTiO3/SrTiO3 artificial lattice toward high dielectric constant and its nonlinearity. Applied Physics Letters. 2003;82(13):2118-2120.

12 Sinsheimer J, Callori SJ, Bein B, Benkara Y, Daley J, Coraor J, et al. Engineering Polarization Rotation in a Ferroelectric Superlattice. Physical Review Letters. 2012;109(16):167601.

13 El Marssi M, Gagou Y, Belhadi J, De Guerville F, Yuzyuk YI, Raevski IP. Ferroelectric BaTiO3/BaZrO3 superlattices: X-ray diffraction, Raman spectroscopy, and polarization hysteresis loops. Journal of Applied Physics. 2010;108(8):084104.

14 Sai N, Meyer B, Vanderbilt D. Compositional Inversion Symmetry Breaking in Ferroelectric Perovskites. Physical Review Letters. 2000;84(24):5636.^-¹⁵15 Lee HN, Christen HM, Chisholm MF, Rouleau CM, Lowndes DH. Strong polarization enhancement in asymmetric three-component ferroelectric superlattices. Nature. 2005;433(7024):395-399. is due to miniaturization of electronic devices that are used in opto- and microelectronics. Strain, caused by a structural mismatch of lattices with different parameters in the plane of conjugation of epitaxial layers, favors high polarization and piezoresponse ¹1 Tabata H, Tanaka H, Kawai T. Formation of artificial BaTiO3/SrTiO3 superlattices using pulsed laser deposition and their dielectric properties. Applied Physics Letters. 1994;65(15):1970.^,³3 Neaton JB, Rabe KM. Theory of polarization enhancement in epitaxial BaTiO3/SrTiO3 superlattices. Applied Physics Letters. 2003;82(10):1586-1588.^,⁶6 Nakhmanson SM, Rabe KM, Vanderbilt D. Polarization enhancement in two- and three-component ferroelectric superlattices. Applied Physics Letters. 2005;87(10):102906.^,¹¹11 Kim L, Jung D, Kim J, Kim YS, Lee J. Strain manipulation in BaTiO3/SrTiO3 artificial lattice toward high dielectric constant and its nonlinearity. Applied Physics Letters. 2003;82(13):2118-2120.^,¹²12 Sinsheimer J, Callori SJ, Bein B, Benkara Y, Daley J, Coraor J, et al. Engineering Polarization Rotation in a Ferroelectric Superlattice. Physical Review Letters. 2012;109(16):167601. that can exceed values typical of materials composing SLs. The unique characteristics of SLs, which are different from their bulk analogues (e.g., the great permittivity that possesses the weak dependence on temperature over a wide range, non-linear electric properties, and particular phase states) are often attributed to the combined influence of strain and electrostatic interplay of layers with different permittivity and polarization in the presence of interfaces between layers ³3 Neaton JB, Rabe KM. Theory of polarization enhancement in epitaxial BaTiO3/SrTiO3 superlattices. Applied Physics Letters. 2003;82(10):1586-1588.^,¹⁰10 Bousquet E, Dawber M, Stucki N, Lichtensteiger C, Hermet P, Gariglio S, et al. Improper ferroelectricity in perovskite oxide artificial superlattices. Nature. 2008;452(7188):732-736.^,¹⁵15 Lee HN, Christen HM, Chisholm MF, Rouleau CM, Lowndes DH. Strong polarization enhancement in asymmetric three-component ferroelectric superlattices. Nature. 2005;433(7024):395-399.. They can even be enhanced via the component’s thickness variation in such structures, which alters the strain of layers ¹1 Tabata H, Tanaka H, Kawai T. Formation of artificial BaTiO3/SrTiO3 superlattices using pulsed laser deposition and their dielectric properties. Applied Physics Letters. 1994;65(15):1970.^,⁷7 Harigai T, Nam SM, Kakemoto H, Wada S, Saito K, Tsurumi T. Structural and dielectric properties of perovskite-type artificial superlattices. Thin Solid Films. 2006;509(1-2):13-17.^,¹¹11 Kim L, Jung D, Kim J, Kim YS, Lee J. Strain manipulation in BaTiO3/SrTiO3 artificial lattice toward high dielectric constant and its nonlinearity. Applied Physics Letters. 2003;82(13):2118-2120..

The use of SLs comprising three alternating layers with different composition expands the range of possible characteristics that can find application in electronics, many thanks to a lack of the inversion center in the symmetry elements of SLs ¹⁴14 Sai N, Meyer B, Vanderbilt D. Compositional Inversion Symmetry Breaking in Ferroelectric Perovskites. Physical Review Letters. 2000;84(24):5636.

15 Lee HN, Christen HM, Chisholm MF, Rouleau CM, Lowndes DH. Strong polarization enhancement in asymmetric three-component ferroelectric superlattices. Nature. 2005;433(7024):395-399.^-¹⁶16 Ogawa Y, Yamada H, Ogasawara T, Arima T, Okamoto H, Kawasaki M, et al. Nonlinear Magneto-Optical Kerr Rotation of an Oxide Superlattice with Artificially Broken Symmetry. Physical Review Letters. 2003;90(21):217403., which is not always the case of bilayer SLs. The differentiation between two types of SLs can be achieved via Raman spectroscopy that is a powerful and non-destructive tool for monitoring phase transitions and lattice dynamics ¹⁷17 Maslova OA, Zakharchenko IN, Bunina OA, Yuzyuk YI, Ortega N, Kumar A, et al. A comparative study of the BaTiO3 film and the BaTiO3/(Ba0.7Sr0.3)TiO3 superlattice using X-ray diffraction and raman spectroscopy. Physics of the Solid State. 2012;54(8):1628-1634.

18 Ortega N, Kumar A, Maslova OA, Yuzyuk YI, Scott JF, Katiyar RS. Effect of periodicity and composition in artificial BaTiO3/(Ba,Sr)TiO3 superlattices. Physical Review B. 2011;83(14):144108.

19 Yuzyuk YI, Almeida A, Chaves MR, Alyoshin VA, Zakharchenko IN, Sviridov EV. Soft Mode in Heteroepitaxial (Ba, Sr)TiO3MgO Thin Films. Physica Status Solidi B. 2000;222(2):535-540.^-²⁰20 Yuzyuk YI. Raman Scattering Spectra of Ceramics, Films, and Superlattices of Ferroelectric Perovskites: A Review. Physics of the Solid State. 2012;54(5):1026-1059. that impact the electric and physical properties of these structures.

The present work is aimed at studying the lattice dynamics of two-layer BaTiO₃/Ba₅₀Sr₅₀TiO₃ (BT/BST) and three-layer BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ (BT/BST/ST) superlattices grown onto MgO substrates via the pulsed laser deposition. A comparative analysis of their polarized Raman spectra, particularly, within the soft-mode (E(1TO)) range, is of particular interest to establish the structural peculiarities caused by misfits of constituting layers.

2. Experimental

BaTiO₃/Ba₅₀Sr₅₀TiO₃ (BT/BST) and BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ (BT/BST/ST) SLs were grown onto (001) single-crystal MgO substrates via the pulsed laser deposition ¹⁸18 Ortega N, Kumar A, Maslova OA, Yuzyuk YI, Scott JF, Katiyar RS. Effect of periodicity and composition in artificial BaTiO3/(Ba,Sr)TiO3 superlattices. Physical Review B. 2011;83(14):144108. by the alternating focus of a laser beam on BT, BST, and ST targets (see a schematic in ²¹21 Tikhonov YA, Zakharchenko IN, Maslova OA, Yuzyuk YI, Ortega N, Kumar A, et al. X-Ray diffraction and Raman spectroscopy studies of superlattices BaTiO3/(Ba0.5,Sr0.5)TiO3/SrTiO3. Physics of the Solid State. 2014;56(3):594-598.). The modulation period Λ of BT/BST layers in a two-layer BT/BST SL was 130 Å (the thickness of individual layers was 65 Å) and that of BT/BST/ST layers in a three-layer BT/BST/ST SL enriched 150 Å (resulting in a 50-Å thickness of the constituting layers). The total thickness of heterostructures was 1 µm.

Raman spectra were excited at room temperature with an argon laser (λ = 514.5 nm) and recorded by an Invia Reflex Renishaw spectrometer equipped with a near-excitation tunable (NExT) filter for the low-frequency spectral range analysis. The exciting radiation was focused atop a sample with a Leica optical microscope in a spot with a diameter of 2 µm. Polarized Raman spectra were collected on samples oriented with respect to crystallographic axes of substrates as X || 100, Y || 010, and Z || 001. Spectra with pronounced E-type soft modes were acquired in the side-view backscattering ¹⁹19 Yuzyuk YI, Almeida A, Chaves MR, Alyoshin VA, Zakharchenko IN, Sviridov EV. Soft Mode in Heteroepitaxial (Ba, Sr)TiO3MgO Thin Films. Physica Status Solidi B. 2000;222(2):535-540., at which the wave vector of the incident beam is parallel to the substrate, and the polarization of incident and scattered light is parallel or perpendicular to the Z axis of the film.

3. Results and Discussion

Figure 1 displays the Raman spectra of both types of SLs in cross- $(Y (ZX) \overset{─}{Y}, Z (YX) \overset{─}{Z})$ (ZX and YX hereinafter) and parallel- $(Y (XX) \overset{─}{Y}, Y (ZZ) \overset{─}{Y})$ and $Z (YY) \overset{─}{Z}$ (XX, ZZ and YY hereinafter) back-scattering geometries.

One can distinguish the lines, which are typical of barium titanate-based ferroelectrics in Raman scattering, among them those denoted as E are permitted for polarizability tensor components of α_zx = α_xz and α_yz = α_zy, while those of A ₁ are Raman-active in the diagonal components of α_xx = α_yy = α_zz, and B ₁ is allowed for α_xx and α_yy components ²²22 Scalabrin A, Chaves AS, Shim DS, Porto SPS. Temperature dependence of the A1 and E optical phonons in BaTiO3. Physica Status Solidi B. 1977;79(2):731-742.. The long-range electrostatic forces make all A ₁ and E modes splitting in transverse (TO) and longitudinal (LO) components. A band indicated as A (~138 cm^-1) is attributed to local distortions of the crystalline structure, which lead to the translation symmetry violation with substituting Sr for Ba in BST layers. It is interpreted as the disorder-induced phonon state density of acoustic transverse (TA) and longitudinal (LA) branches that possess the high density near the Brillouin zone boundary ²³23 Lemanov VV. Concentration dependence of phonon mode frequencies and the Grüneisen coefficients in BaxSr1-xTiO3 solid solutions. Physics of the Solid State. 1997;39(2):318-322., and occurs in all back-scattering geometries of BST films ¹⁷17 Maslova OA, Zakharchenko IN, Bunina OA, Yuzyuk YI, Ortega N, Kumar A, et al. A comparative study of the BaTiO3 film and the BaTiO3/(Ba0.7Sr0.3)TiO3 superlattice using X-ray diffraction and raman spectroscopy. Physics of the Solid State. 2012;54(8):1628-1634.^,²⁴24 Yuzyuk YI, Alyoshin VA, Zakharchenko IN, Sviridov EV, Almeida A, Chaves MR. Polarization-dependent Raman spectra of heteroepitaxial (Ba,Sr)TiO3/MgO thin films. Physical Review B. 2002;65(13):134107.^,²⁵25 Yuzyuk YI, Simon P, Zakharchenko IN, Alyoshin VA, Sviridov EV. Stress effect on the ferroelectric-to-paraelectric phase transition in heteroepitaxial (Ba,Sr)TiO3/(001)MgO thin film studied by Raman scattering and x-ray diffraction. Physical Review B. 2002;66(5):052103.. For both SLs, one observes the depolarization of spectra in cross- and parallel-polarized configurations. Special attention is paid to the behavior of E(1TO) line which is attributed to the transverse optical vibration of soft modes E that split in various components with reducing symmetry of ABO₃-type perovskites, i.e., when perovskite enters the polar phase. This low-frequency ferroelectric mode is highly sensitive to strains emerging in perovskites, especially in thin films and superlattice which are favorable media for misfit strains due to the lattice parameter mismatch between film and substrate, or between constituting layers. The shape and spectral characteristics of E(1TO) mode (full width at half maximum, peak position) in the Raman spectrum will depend on the magnitude of strain in the probed material. As follows from the analysis, E(1TO) soft mode in ZX spectra is underdamped (with a frequency exceeding a width) for both SLs. However, in the case of BT/BST/ST SL its frequency is estimated to be 111 cm^-1 that is substantially greater than a value of 75 cm^-1 for BT/BST SL, whereas the FWHMs are 124 and 111 cm^-1, respectively (see Fig. 2a). Since this mode refers to the displacement of Ti ions relative to the oxygen octahedron in the plane parallel to the substrate, its frequency is sensitive to the two-dimension compression in heterostructures. Its upshift in a three-layer SL means a drastic increase in 2D stress in the latter. As is known from the phenomenological theory²⁶26 Shirokov VB, Yuzyuk YI, Dkhil B, Lemanov VV. Phenomenological theory of phase transitions in epitaxial BaTiO3 thin films. Physical Review B. 2007;75(22):224116.^,²⁷27 Shirokov VB, Yuzyuk YI, Dkhil B, Lemanov VV. Phenomenological theory of phase transitions in epitaxial BaxSr1-xTiO3 thin films. Physical Review B. 2009;79(14):144118., this should lead to a rise in transition temperature from the ferroelectric to the paraelectric state and to the appropriate changes in electric and physical properties that are determined by the 2D compression of layers.

Another curious observation is that YX spectrum of BT/BST/ST is visually silent in comparison with a quite well-resolved YX spectrum for BT/BST SL (see Fig.1). According to the Raman selection rules ²²22 Scalabrin A, Chaves AS, Shim DS, Porto SPS. Temperature dependence of the A1 and E optical phonons in BaTiO3. Physica Status Solidi B. 1977;79(2):731-742., a lack of modes in this back-scattering geometry is characteristic of c-domain BST films with the tetragonal symmetry of the unit cell.

The E(TO) soft mode leakage from ZX spectra also arises in diagonal back-scattering geometries (Fig. 1). Furthermore, the maxima of A₁(2TO), A₁(3TO) and В₁ modes in ZZ spectrum of BT/BST/ST SL are upshifted, enriching 298, 530 and 317 cm^-1 against 261, 521 and 294 cm^-1 in ZZ spectrum of BT/BST SL, respectively (see Fig. 2b). Another important feature is the emergence of the interference gap at ~160 cm^-1 in XX spectrum of BT/BST/ST SL. Typically, this spectral peculiarity arises in ZZ configuration of the tetragonal crystal ²²22 Scalabrin A, Chaves AS, Shim DS, Porto SPS. Temperature dependence of the A1 and E optical phonons in BaTiO3. Physica Status Solidi B. 1977;79(2):731-742. as a result of the interaction of two А₁(ТО) modes and also occurs in c-domain BST films²⁴24 Yuzyuk YI, Alyoshin VA, Zakharchenko IN, Sviridov EV, Almeida A, Chaves MR. Polarization-dependent Raman spectra of heteroepitaxial (Ba,Sr)TiO3/MgO thin films. Physical Review B. 2002;65(13):134107.^,²⁸28 Lebedev AI. Dielectric, piezoelectric, and elastic properties of BaTiO3/SrTiO3 ferroelectric superlattices from first principles. Journal of Advanced Dielectrics. 2012;2(1):1250003.. However, its presence in XX geometry is unexpected for the mentioned systems. Moreover, small-depth gaps are also observed at ~90 cm^-1 in parallel-polarized spectra of BT/BST/ST SL, by analogue with those at 160 cm^-1 (see Fig. 2c), but their origin is still unclear.

Figure 1
Room-temperature Raman spectra of BT/BST/ST and BT/BST SLs in different back-scattering geometries.

Figure 2
Room-temperature а) ZX and b) ZZ Raman spectra of BT/BST/ST and BT/BST SLs. The dashed lines designate the shifts of maxima of а) Е(1ТО) and b) A₁(TO) soft modes in Raman spectra of BT/BST/ST SL in comparison with BT/BST SL. c) Parallel-polarized Raman spectra of BT/BST/ST. The dashed contours show the interference gaps.

Based on the results for both SLs, one can assume that, for a two-layer BT/BST SL, strain caused by the lattice parameter mismatch of the constituting layers induce the slope of the resulting polar axis in the unit cells of SL. As earlier established, the symmetry was lowering from tetragonal of BT/ST structures to orthorhombic or even monoclinic for BT/BST SL ¹⁷17 Maslova OA, Zakharchenko IN, Bunina OA, Yuzyuk YI, Ortega N, Kumar A, et al. A comparative study of the BaTiO3 film and the BaTiO3/(Ba0.7Sr0.3)TiO3 superlattice using X-ray diffraction and raman spectroscopy. Physics of the Solid State. 2012;54(8):1628-1634.^,¹⁸18 Ortega N, Kumar A, Maslova OA, Yuzyuk YI, Scott JF, Katiyar RS. Effect of periodicity and composition in artificial BaTiO3/(Ba,Sr)TiO3 superlattices. Physical Review B. 2011;83(14):144108..

In BT/BST/ST SL, the upshift of E(1TO) component from 75 cm^-1 (for BT/BST SL) to 111 cm^-1 together with a “silent” YX spectrum enables the suggestion that 2D compression in this structure is much greater than in a two-layer SL. Furthermore, as established in ²¹21 Tikhonov YA, Zakharchenko IN, Maslova OA, Yuzyuk YI, Ortega N, Kumar A, et al. X-Ray diffraction and Raman spectroscopy studies of superlattices BaTiO3/(Ba0.5,Sr0.5)TiO3/SrTiO3. Physics of the Solid State. 2014;56(3):594-598., the out-of-plane (c) parameter of BT layers in BT/BST/ST SL exceeds to a large extent that in BT/BST SL (from 4.022 to 4.080 Å). Such an amplification in tetragonality of BT layers in a three-layer SL due to the compression in the conjugation plane with ST layers results in a gain in E(TO) soft mode frequency and in a “silent” YX spectrum. In turn, BST layers should be extended because their c parameter (c_BST = 3.935 Å) is found to be smaller than the bulk value (c_BSTbulk = 3.947 Å), while c parameter of ST layers (c_ST = 3.926 Å) augments in comparison with a bulk value (c_STbulk = 3.905 Å) owing to enlarged volume of the unit cell. According to Tikhonov et al. ²⁹29 Tikhonov YA, Razumnaya AG. Maslova OA, Zakharchenko IN, Yuzyuk YI, Ortega N, et al. Phase transitions in two- and three-component perovskite superlattices. Physics of the Solid State. 2015;57(3):486-490., such a lattice parameter distortion in a three-layer BT/BST-0.5/ST SL shifts the ferroelectric-to-paraelectric phase transition point to 610 K against 540 K for a two-layer SL.

It is worth noting that unit cell parameters of BT, BST and ST layers and, consequently, the behavior of 2D compression in SLs are also sensitive to other competitive factors, such as electrostatic and mechanical interaction between layers, or even the interplay between SL and substrate. Indeed, thermoelastic stresses induced by the substrate exert influence on the behavior of ferroelectric phase transitions emerged in barium titanate-based films. Since the soft mode in BT corresponds to the displacement of Ti ions with respect to the oxygen octahedron, the frequency of this mode depends on the Ti-O bond length. In a tetragonal с-domain thin film, the Е(ТО) soft mode is attributed to the displacement of Ti ions in the plane parallel to the substrate, and the increase in its frequency can be due to the two-dimensional compression that arises in heteroepitaxial films because of the lattice parameter mismatch between BT and MgO. Although we do not specially consider the effect of MgO substrate on our superlattices, it has to be mentioned that the influence of substrate/film interface on the behavior of soft modes, has been clearly demonstrated in ³⁰30 Yuzyuk YI, Katiyar RS, Alyoshin VA, Zakharchenko IN, Markov DA, Sviridov EV. Stress relaxation in heteroepitaxial (Ba,Sr)TiO3/(001)MgO thin film studied by micro-Raman spectroscopy. Physical Review B. 2003;68(10):104104. on a heteroepitaxial (Ba,Sr)TiO₃ thin film grown onto a MgO substrate. For this, one edge of film was ridded from the substrate by selective chemical etching of the film. The subsequent characterization of the film at various points of its surface, including the part liberated from the substrate, revealed the substantial transformation of the E(TO) soft mode, while moving from the part bound to the substrate towards the areas beyond it. The main observation was that, being a well pronounced peak centered at 64 cm^-1 with a width of 57 cm^-1 at the beginning of the laser beam movement, the E(TO) mode becomes a wide wing with a frequency at 35 cm^-1 with a damping above 100 cm^-1 at the area of the film surface free of the substrate. The two-dimensional stress for this film was shown to drop to almost a zero value with approaching the substrate-free area. This allows the conclusion that the two-dimensional compression should vanish in the heteroepitaxial film or SL being partially or totally free of the substrate.

4. Conclusions

BaTiO₃/Ba₅₀Sr₅₀TiO₃ and BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ superlattices were thoroughly inspected via Raman spectroscopy. Special attention was paid to a comprehensive analysis of their polarized Raman spectra, especially, within a soft mode range. For a three-layer BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ system, there was established a more pronounced shift of E(TO) and A₁(TO) soft mode components in comparison with BaTiO₃/Ba₅₀Sr₅₀TiO₃. Spectral peculiarities, found for BaTiO₃/Ba₅₀Sr₅₀TiO₃/SrTiO₃ superlattice, evidenced an abrupt increase in 2D compression of BT layers, being in conjugation with ST ones, as well as more pronounced tetragonality of its unit cell against BaTiO₃/Ba₅₀Sr₅₀TiO₃ structure, presumably owing to substantially risen temperature of transition from ferroelectric to paraelectric phase.

5. Acknowledgments

This work was partially performed within the Program of Fundamental Research of State Academies of Sciences for the period of 2013-2020 and was partially supported by Tomsk State University in the framework of the competitiveness improvement program for two authors (O.A. Maslova and S.A. Barannikova). Experiments carried out at the University of Puerto Rico were supported by the DOD-AFOSR Grant #FA9550-16-1-0295.

6. References

¹
Tabata H, Tanaka H, Kawai T. Formation of artificial BaTiO₃/SrTiO₃ superlattices using pulsed laser deposition and their dielectric properties. Applied Physics Letters 1994;65(15):1970.
²
Marrec FL, Farhi R, El Marssi M, Dellis JL, Karkut G, Ariosa D. Ferroelectric PbTiO₃/BaTiO₃ superlattices: Growth anomalies and confined modes. Physical Review B 2000;61(10):R6447.
³
Neaton JB, Rabe KM. Theory of polarization enhancement in epitaxial BaTiO₃/SrTiO₃ superlattices. Applied Physics Letters 2003;82(10):1586-1588.
⁴
Das RR, Yuzyuk YI, Bhattacharya P, Gupta V, Katiyar RS. Folded acoustic phonons and soft mode dynamics in BaTiO₃/SrTiO₃ superlattices. Physical Review B 2004;69(13):132302.
⁵
Diéguez O, Rabe KM, Vanderbilt D. First-principles study of epitaxial strain in perovskites. Physical Review B 2005;72(14):144101.
⁶
Nakhmanson SM, Rabe KM, Vanderbilt D. Polarization enhancement in two- and three-component ferroelectric superlattices. Applied Physics Letters 2005;87(10):102906.
⁷
Harigai T, Nam SM, Kakemoto H, Wada S, Saito K, Tsurumi T. Structural and dielectric properties of perovskite-type artificial superlattices. Thin Solid Films. 2006;509(1-2):13-17.
⁸
Stephanovich VA, Luk'yanchuk IA, Karkut MG. Domain-Enhanced Interlayer Coupling in Ferroelectric/Paraelectric Superlattices. Physical Review Letters 2005;94(4):047601.
⁹
Lebedev AI. Properties of BaTiO₃/BaZrO₃ ferroelectric superlattices with competing instabilities. Condensed Matter arXiv 2013;1304:7596.
¹⁰
Bousquet E, Dawber M, Stucki N, Lichtensteiger C, Hermet P, Gariglio S, et al. Improper ferroelectricity in perovskite oxide artificial superlattices. Nature 2008;452(7188):732-736.
¹¹
Kim L, Jung D, Kim J, Kim YS, Lee J. Strain manipulation in BaTiO3/SrTiO3 artificial lattice toward high dielectric constant and its nonlinearity. Applied Physics Letters 2003;82(13):2118-2120.
¹²
Sinsheimer J, Callori SJ, Bein B, Benkara Y, Daley J, Coraor J, et al. Engineering Polarization Rotation in a Ferroelectric Superlattice. Physical Review Letters 2012;109(16):167601.
¹³
El Marssi M, Gagou Y, Belhadi J, De Guerville F, Yuzyuk YI, Raevski IP. Ferroelectric BaTiO₃/BaZrO₃ superlattices: X-ray diffraction, Raman spectroscopy, and polarization hysteresis loops. Journal of Applied Physics 2010;108(8):084104.
¹⁴
Sai N, Meyer B, Vanderbilt D. Compositional Inversion Symmetry Breaking in Ferroelectric Perovskites. Physical Review Letters 2000;84(24):5636.
¹⁵
Lee HN, Christen HM, Chisholm MF, Rouleau CM, Lowndes DH. Strong polarization enhancement in asymmetric three-component ferroelectric superlattices. Nature 2005;433(7024):395-399.
¹⁶
Ogawa Y, Yamada H, Ogasawara T, Arima T, Okamoto H, Kawasaki M, et al. Nonlinear Magneto-Optical Kerr Rotation of an Oxide Superlattice with Artificially Broken Symmetry. Physical Review Letters 2003;90(21):217403.
¹⁷
Maslova OA, Zakharchenko IN, Bunina OA, Yuzyuk YI, Ortega N, Kumar A, et al. A comparative study of the BaTiO₃ film and the BaTiO₃/(Ba_0.7Sr_0.3)TiO₃ superlattice using X-ray diffraction and raman spectroscopy. Physics of the Solid State 2012;54(8):1628-1634.
¹⁸
Ortega N, Kumar A, Maslova OA, Yuzyuk YI, Scott JF, Katiyar RS. Effect of periodicity and composition in artificial BaTiO₃/(Ba,Sr)TiO₃ superlattices. Physical Review B 2011;83(14):144108.
¹⁹
Yuzyuk YI, Almeida A, Chaves MR, Alyoshin VA, Zakharchenko IN, Sviridov EV. Soft Mode in Heteroepitaxial (Ba, Sr)TiO₃MgO Thin Films. Physica Status Solidi B 2000;222(2):535-540.
²⁰
Yuzyuk YI. Raman Scattering Spectra of Ceramics, Films, and Superlattices of Ferroelectric Perovskites: A Review. Physics of the Solid State 2012;54(5):1026-1059.
²¹
Tikhonov YA, Zakharchenko IN, Maslova OA, Yuzyuk YI, Ortega N, Kumar A, et al. X-Ray diffraction and Raman spectroscopy studies of superlattices BaTiO₃/(Ba_0.5,Sr_0.5)TiO₃/SrTiO₃ Physics of the Solid State 2014;56(3):594-598.
²²
Scalabrin A, Chaves AS, Shim DS, Porto SPS. Temperature dependence of the A1 and E optical phonons in BaTiO₃ Physica Status Solidi B 1977;79(2):731-742.
²³
Lemanov VV. Concentration dependence of phonon mode frequencies and the Grüneisen coefficients in BaxSr1-xTiO₃ solid solutions. Physics of the Solid State 1997;39(2):318-322.
²⁴
Yuzyuk YI, Alyoshin VA, Zakharchenko IN, Sviridov EV, Almeida A, Chaves MR. Polarization-dependent Raman spectra of heteroepitaxial (Ba,Sr)TiO₃/MgO thin films. Physical Review B 2002;65(13):134107.
²⁵
Yuzyuk YI, Simon P, Zakharchenko IN, Alyoshin VA, Sviridov EV. Stress effect on the ferroelectric-to-paraelectric phase transition in heteroepitaxial (Ba,Sr)TiO₃/(001)MgO thin film studied by Raman scattering and x-ray diffraction. Physical Review B 2002;66(5):052103.
²⁶
Shirokov VB, Yuzyuk YI, Dkhil B, Lemanov VV. Phenomenological theory of phase transitions in epitaxial BaTiO₃ thin films. Physical Review B 2007;75(22):224116.
²⁷
Shirokov VB, Yuzyuk YI, Dkhil B, Lemanov VV. Phenomenological theory of phase transitions in epitaxial BaxSr1-xTiO₃ thin films. Physical Review B 2009;79(14):144118.
²⁸
Lebedev AI. Dielectric, piezoelectric, and elastic properties of BaTiO₃/SrTiO₃ ferroelectric superlattices from first principles. Journal of Advanced Dielectrics 2012;2(1):1250003.
²⁹
Tikhonov YA, Razumnaya AG. Maslova OA, Zakharchenko IN, Yuzyuk YI, Ortega N, et al. Phase transitions in two- and three-component perovskite superlattices. Physics of the Solid State 2015;57(3):486-490.
³⁰
Yuzyuk YI, Katiyar RS, Alyoshin VA, Zakharchenko IN, Markov DA, Sviridov EV. Stress relaxation in heteroepitaxial (Ba,Sr)TiO₃/(001)MgO thin film studied by micro-Raman spectroscopy. Physical Review B 2003;68(10):104104.

Publication Dates

Publication in this collection
14 Nov 2018
Date of issue
2019

History

Received
01 June 2018
Reviewed
28 Aug 2018
Accepted
04 Oct 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[19] ¹⁹
Yuzyuk YI, Almeida A, Chaves MR, Alyoshin VA, Zakharchenko IN, Sviridov EV. Soft Mode in Heteroepitaxial (Ba, Sr)TiO₃MgO Thin Films. Physica Status Solidi B 2000;222(2):535-540.

[20] ²⁰
Yuzyuk YI. Raman Scattering Spectra of Ceramics, Films, and Superlattices of Ferroelectric Perovskites: A Review. Physics of the Solid State 2012;54(5):1026-1059.

[21] ²¹
Tikhonov YA, Zakharchenko IN, Maslova OA, Yuzyuk YI, Ortega N, Kumar A, et al. X-Ray diffraction and Raman spectroscopy studies of superlattices BaTiO₃/(Ba_0.5,Sr_0.5)TiO₃/SrTiO₃ Physics of the Solid State 2014;56(3):594-598.

[22] ²²
Scalabrin A, Chaves AS, Shim DS, Porto SPS. Temperature dependence of the A1 and E optical phonons in BaTiO₃ Physica Status Solidi B 1977;79(2):731-742.

[23] ²³
Lemanov VV. Concentration dependence of phonon mode frequencies and the Grüneisen coefficients in BaxSr1-xTiO₃ solid solutions. Physics of the Solid State 1997;39(2):318-322.

[24] ²⁴
Yuzyuk YI, Alyoshin VA, Zakharchenko IN, Sviridov EV, Almeida A, Chaves MR. Polarization-dependent Raman spectra of heteroepitaxial (Ba,Sr)TiO₃/MgO thin films. Physical Review B 2002;65(13):134107.

[25] ²⁵
Yuzyuk YI, Simon P, Zakharchenko IN, Alyoshin VA, Sviridov EV. Stress effect on the ferroelectric-to-paraelectric phase transition in heteroepitaxial (Ba,Sr)TiO₃/(001)MgO thin film studied by Raman scattering and x-ray diffraction. Physical Review B 2002;66(5):052103.

[26] ²⁶
Shirokov VB, Yuzyuk YI, Dkhil B, Lemanov VV. Phenomenological theory of phase transitions in epitaxial BaTiO₃ thin films. Physical Review B 2007;75(22):224116.

[27] ²⁷
Shirokov VB, Yuzyuk YI, Dkhil B, Lemanov VV. Phenomenological theory of phase transitions in epitaxial BaxSr1-xTiO₃ thin films. Physical Review B 2009;79(14):144118.

[28] ²⁸
Lebedev AI. Dielectric, piezoelectric, and elastic properties of BaTiO₃/SrTiO₃ ferroelectric superlattices from first principles. Journal of Advanced Dielectrics 2012;2(1):1250003.

[29] ²⁹
Tikhonov YA, Razumnaya AG. Maslova OA, Zakharchenko IN, Yuzyuk YI, Ortega N, et al. Phase transitions in two- and three-component perovskite superlattices. Physics of the Solid State 2015;57(3):486-490.

[30] ³⁰
Yuzyuk YI, Katiyar RS, Alyoshin VA, Zakharchenko IN, Markov DA, Sviridov EV. Stress relaxation in heteroepitaxial (Ba,Sr)TiO₃/(001)MgO thin film studied by micro-Raman spectroscopy. Physical Review B 2003;68(10):104104.

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