Theory of ferroelectric phase transition in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi mathvariant="normal">SrTiO</mml:mi></mml:mrow><mml:mrow><mml:mn>3</mml:mn></mml:mrow></mml:msub></mml:mrow></mml:math>induced by isotope replacement

Yamada, Y.; Todoroki, Norikazu; Miyashita, Seiji

doi:10.1103/physrevb.69.024103

Cited by 43 publications

(40 citation statements)

References 20 publications

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“…Similarly, as in the related impurity system Sr 1-x Ca x TiO 3 (SCT) [23], the softening stops at an energy of about 3 cm 21 , and the result is completely consistent with the data obtained on light scattering [18], hyper-Raman scattering [17], and neutron inelastic scattering [24]. These results suggest that the ferroelectric phase transition is not a purely displacive one, but becomes in part order-disorder controlled in the vicinity of T c : Yamada et al [25] proposed a new model for the ferroelectric phase transition of STO18. The essential feature is described by a 3-state quantum order-disorder system characterizing the degenerated excited states in addition to the ground state of the TiO 6 cluster.…”

Section: Resultssupporting

confidence: 80%

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Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi¹⁸O₃: review and perspective

Itoh

Yagi

Uesu

et al. 2004

Science and Technology of Advanced Materials

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The oxygen isotope exchange of 16 O by 18 O in SrTiO 3 causes a drastic change from paraelectric to ferroelectric, due to the suppression of quantum fluctuation. The phase transition and origin of the huge domain wall response were evaluated by dielectric, magnetic (NMR), and optical measurements (SHG, light scattering). The results obtained corroborate (1) smeared ferroelectric transition at T c due to quenched random field, (2) a quite large dielectric contribution from domain walls, (3) incomplete softening of the transverse optic mode, and (4) a large contribution from the relaxational mode to the phase transition. Quantitative explanations, given to individual results, may give hints to grasp the mechanism for the evolution of ferroelectricity, in which quantum fluctuation and random fields are dominant perturbations. Finally, some of the news studies on the SrTiO 3 were also introduced. q

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Section: Resultssupporting

confidence: 80%

“…The transverse Ising model [27] has been recently used to explain the phase transitional properties of quantum paraelectrics and quantum ferroelectrics. [25,26,28]. RFs were additionally introduced in order to describe the observed domains state properties [29].…”

Section: Resultsmentioning

confidence: 99%

Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi¹⁸O₃: review and perspective

Itoh

Yagi

Uesu

et al. 2004

Science and Technology of Advanced Materials

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“…It shows a small difference with the result reported on STO16 [11]. According to these experimental results about the low energy modes, theoretical and experimental works suggested a nondisplacive phase transition mechanism in STO18 [11,12]. However, quite recently the soft E u mode observed in Ref.…”

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confidence: 59%

“…Since then, the phase transition mechanism of the isotope-exchanged strontium titanate SrTi 18 O 3 (hereafter abbreviated as STO18 and the ordinary one as STO16) has attracted the intense interest of many researchers in order to elucidate its phase transition mechanism related to the quantum fluctuations. The lowest energy phonon mode in STO18 has been searched for and analyzed to elucidate the soft mode dynamics near T c by many authors [7][8][9][10][11]. However, any clear softening behavior has not been reported: By Raman scattering studies, the observation of the Raman inactive soft E u mode has been tried, but the assignment of certain spectral feature to the E u mode has not been convincing and unambiguous.…”

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confidence: 99%

Perfect Softening of the Ferroelectric Mode in the Isotope-Exchanged Strontium Titanate ofSrTiO318Studied by Light Scattering

2006

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The E u mode of the isotope-induced ferroelectric strontium titanate SrTi 18 O 3 shows a perfect softening at the ferroelectric phase transition temperature T c , where the frequency of the underdamped mode approaches completely to zero within the instrumental resolution. The spectra of the Raman inactive soft E u mode have been successfully observed owing to local symmetry breaking and by long-term accumulation of the spectral intensity with a high resolution technique. The mechanism of the phase transition is concluded to be an ideal displacive-type accompanied with perfect softening of the Slater-type polar E u mode. The difference between the soft mode behavior of The perovskite oxide strontium titanate SrTiO 3 has been considered to belong to the typical quantum paraelectrics, because it keeps paraelectricity until T 0 K by the quantum fluctuation that might depress the occurrence of the ferroelectric order [1]. Indeed, at low temperatures below 4 K, the dielectric constant increases considerably but remains finite even near 0 K without any divergent behavior. The dynamics of the ferroelectric soft mode in the quantum paraelectrics also shows no freezing phenomenon, staying with the finite phonon frequency until 0 K according to the Lyddane-Sachs-Teller relationship [2,3]. Since the effect of quantum fluctuation was first suggested in Ref.[1], many intensive studies have been accumulated to elucidate the dynamics of the quantum fluctuation and also the soft mode behavior related to the quantum fluctuation in SrTiO 3 and related materials. There are two types of soft modes in the low frequency region of SrTiO 3 , as listed in the phonon correlation table [4]: the ferroelectric modes E u , A 2u [2 -4] described above and the A 1g , E g modes related to the structural phase transition [5].Recently, the ferroelectric phase transition in SrTiO 3 was discovered at 23 K by exchange of 16 O in SrTiO 3 to its isotope 18 O [6]. Since then, the phase transition mechanism of the isotope-exchanged strontium titanate SrTi 18 O 3 (hereafter abbreviated as STO18 and the ordinary one as STO16) has attracted the intense interest of many researchers in order to elucidate its phase transition mechanism related to the quantum fluctuations. The lowest energy phonon mode in STO18 has been searched for and analyzed to elucidate the soft mode dynamics near T c by many authors [7][8][9][10][11]. However, any clear softening behavior has not been reported: By Raman scattering studies, the observation of the Raman inactive soft E u mode has been tried, but the assignment of certain spectral feature to the E u mode has not been convincing and unambiguous. Inelastic neutron scattering has revealed the temperature dependence of the soft mode of

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“…[10][11][12][13][14] A series of light-scattering experiments on nearly fully exchanged STO18-x has observed the ferroelectric soft E u mode, which softens toward zero-frequency at T c with less damping than in the other perovskite crystals. [15][16][17] In particular, the ideal displacive-type ferroelectric phase transition has been recently reported in Ref.…”

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confidence: 99%

Isotope effect on the soft-mode dynamics ofSrTiO3studied by Raman scattering

et al. 2005

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The oxygen isotope effect on the soft-mode dynamics in quantum paraelectric SrTi͑ O atoms are 0.23 ͓STO18-23͔ and 0.32 ͓STO18-32͔, which are less than the critical value x c ͑=0.33͒. In STO18-32, whose exchange rate is just below x c , the soft E u mode shows hardening behavior in a low-temperature region indicating the onset of local ferroelectric order. On the other hand, the soft E u mode in STO18-23 does not show any hardening behavior until 0 K. The enhancement of the inhomogeneity in the crystal by the exchange of 18 O is concluded to play an essential role in the soft-mode dynamics of the quantum paraelectric and ferroelectric STO18-x. The relation between the soft-mode dynamics and quantum fluctuation is discussed.

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Theory of ferroelectric phase transition inSrTiO3induced by isotope replacement

Cited by 43 publications

References 20 publications

Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi¹⁸O₃: review and perspective

Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi¹⁸O₃: review and perspective

Perfect Softening of the Ferroelectric Mode in the Isotope-Exchanged Strontium Titanate ofSrTiO318Studied by Light Scattering

Isotope effect on the soft-mode dynamics ofSrTiO3studied by Raman scattering

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Theory of ferroelectric phase transition inSrTiO3induced by isotope replacement

Cited by 43 publications

References 20 publications

Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi18O3: review and perspective

Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi18O3: review and perspective

Perfect Softening of the Ferroelectric Mode in the Isotope-Exchanged Strontium Titanate ofSrTiO318Studied by Light Scattering

Isotope effect on the soft-mode dynamics ofSrTiO3studied by Raman scattering

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Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi¹⁸O₃: review and perspective

Phase transition and random-field induced domain wall response in quantum ferroelectrics SrTi¹⁸O₃: review and perspective