Ultrafast Electric Field-Induced Phase Transition in Bulk Bi0.5Na0.5TiO3 under High-Intensity Terahertz Irradiation

Man, Zhenyong; McKinnon, R.A.; Viola, Giuseppe; Yang, Bin; Zhang, Dou; orcid,; Reece, Michael J.; Abrahams, Isaac; Yan, Haixue

doi:10.1021/acsphotonics.0c01559

Cited by 8 publications

(13 citation statements)

References 26 publications

(28 reference statements)

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“…In a number of studies it was shown that THz radiation can also efficiently manipulate properties of materials, for example inducing subpicosecond changes of the macroscopic polarisation in organic ferroelectrics, [130] a phase transition in atomic caesium vapor, [131] an ultrafast phase transition from weak polar (Cc) to strong polar (R3c) phases in ferroelectric Bi 0.5 Na 0.5 TiO 3 , [132] a THz-driven irreversible topological phase transition in two-dimensional MoTe 2, [133] and a THz induced insulator-to-metal transtion in VO 2 -based metamaterials. [134] In most of these examples reasonably strong THz fields were used.…”

Section: Future Researchmentioning

confidence: 99%

Nonlinear Optical Properties and Applications of Fluorenone Molecular Materials

Semin

Duan

et al. 2021

Advanced Optical Materials

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Fluorenone molecular materials provide an excellent platform to engineer new materials that are very promising for photonic and optoelectronic applications, such as very efficient optical second harmonic (SHG) and terahertz (THz) generation, light emitting diodes, biomarkers, solar cells, and sensors. More recently, there have been a lot of research efforts dedicated towards the nonlinear optical (NLO) properties of these fluorenone materials because of their unique combination of chemical, structural, and optical properties. This review addresses the state of the art of this very interesting and potent class of molecular materials. In particular, the NLO susceptibilities, their potential for optical SHG and THz generation and their two‐photon luminescence properties and how to optimize these by rational design are reviewed. Flexibility and easiness of modification of their molecular properties combined with their structural polymorphism enable a variety of applications. Perspectives and future research directions for these fluorenone materials are also presented.

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Section: Future Researchmentioning

confidence: 99%

Nonlinear Optical Properties and Applications of Fluorenone Molecular Materials

Semin

Duan

et al. 2021

Advanced Optical Materials

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“…Therefore, the higher dielectric permittivity and loss of the Non‐LTD 1700 ceramics can be attributed to a possible long distance between

Y_{Z r}^{'}

and

V_{O}^{. .}

in the oxygen vacancy associated (

Y_{Z r}^{'} - V_{O}^{. .}

) dipoles. Zhang et al 20 . have shown that a longer dipole (e.g., a longer distance between

Y_{Z r}^{'}

and

V_{O}^{. .}

in our samples) may produce a higher permittivity under the same AC electric field.…”

Section: Resultsmentioning

confidence: 56%

“…43 Therefore, the higher dielectric permittivity and loss of the Non-LTD 1700 ceramics can be attributed to a possible long distance between 𝑌 ′ 𝑍𝑟 and 𝑉 .. 𝑂 in the oxygen vacancy associated (𝑌 ′ 𝑍𝑟 − 𝑉 .. 𝑂 ) dipoles. Zhang et al 20 have shown that a longer dipole (e.g., a longer distance between 𝑌 ′ 𝑍𝑟 and 𝑉 .. 𝑂 in our samples) may produce a higher permittivity under the same AC electric field. The long 𝑌 ′ 𝑍𝑟 − 𝑉 .. 𝑂 distance is also related to a loosely packed structure of dipoles in the ceramic sintered at 1700…”

mentioning

confidence: 63%

“…Previously, THz technology has been used to analyze biomolecules and biomaterials as it can stimulate low‐energy processes such as intra‐ and intermolecular vibrations 15–18 . THz radiation is accessible to a variety of physical properties of ceramics, such as complex refractive index and complex dielectric permittivity, making it possible to probe phase transitions of polar ceramics by the simultaneous measurement of the temperature dependencies of the dielectric permittivity and dielectric loss 19,20 . However, in bioceramics, the application of THz technology has been rarely reported.…”

Section: Introductionmentioning

confidence: 99%

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Terahertz probing of low‐temperature degradation in zirconia bioceramics

et al. 2021

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ZrO2‐based ceramics are widely used in biomedical applications due to its color, biocompatibility, and excellent mechanical properties. However, low‐temperature degradation (LTD) introduces a potential risk for long‐term reliability of these materials. The development of innovative nondestructive techniques, which can explore LTD in zirconia‐derived compounds, is strongly required. Yttria stabilized zirconia, 3Y‐TZP, is one of the well‐developed ZrO2‐based ceramics with improved resistance to LTD for dental crown and implant applications. Here, 3Y‐TZP ceramic powders were pressed and sintered to study the LTD phenomenon by phase transition behavior. The LTD‐driven tetragonal‐to‐monoclinic phase transition was confirmed by XRD. XPS analysis demonstrated that induced LTD reduced the oxygen vacancies which supports these findings. It is proved that after the degradation, the 3Y‐TZP ceramics show the decreased dielectric permittivity at terahertz frequencies due to the crystallographic phase transformation. Terahertz nondestructive probe is a promising method to investigate LTD in zirconia ceramics.

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“…The suppression of the phase transition was mainly attributed to kinetic effects and partially to the self-heating of the sample, whose temperature exponentially increased with increasing frequency and further prevented a long-range ferroelectric state to be established [221]. However, recent experiments have demonstrated that the application of THz electric field pulses of about 155 kV/cm intensity at 200 K for a time duration as short as 20 ps on BNT ceramics produces detectable changes in reflectivity, which are due to a structural transition from the monoclinic weakly polar phase Cc to the strongly polar phase R3c [222]. Although, the extent of the THz field-induced transition is lower than that driven under DC poling conditions, these results indicate that the BNT structure is also able to transform under THz irradiation [222].…”

Section: Frequency/rate Dependence Of Electric Field-induced Transfor...mentioning

confidence: 99%