Concurrent wafer-level measurement of longitudinal and transverse effective piezoelectric coefficients (<i>d</i>33,f and <i>e</i>31,f) by double beam laser interferometry

Sivaramakrishnan, Subramanian; Mardilovich, Peter; Schmitz-Kempen, Thorsten; Tiedke, S.

doi:10.1063/1.5019568

Cited by 29 publications

(17 citation statements)

References 17 publications

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“…The inverse piezoelectric effect was measured with a triangular voltage input at 211 Hz. Due to systematic errors arising from non-neglectable substrate deformation during measurements of the inverse piezoelectric effect, [21] a correction factor of 0.85 was multiplied with the measured strain response (see supporting information). Polarization inversion was initiated through a unipolar 0.1 Hz sine wave with a peak value of -200 V over 60s.…”

Section: Methodsmentioning

confidence: 99%

AlScN: A III-V semiconductor based ferroelectric

Fichtner

Wolff

Lofink

et al. 2019

Journal of Applied Physics

490

379

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Ferroelectric switching is unambiguously demonstrated for the first time in a III-V semiconductor based material: Al1-xScxN -A discovery which could help to satisfy the urgent demand for thin film ferroelectrics with high performance and good technological compatibility with generic semiconductor technology which arises from a multitude of memory, micro/nano-actuator and emerging applications based on controlling electrical polarization. The appearance of ferroelectricity in Al1-xScxN can be related to the continuous distortion of the original wurtzite-type crystal structure towards a layered-hexagonal structure with increasing Sc content and tensile strain, which is expected to be extendable to other III-nitride based solid solutions. Coercive fields which are systematically adjustable by more than 3 MV/cm, high remnant polarizations in excess of 100 µC/cm² which constitute the first experimental estimate of the previously inaccessible spontaneous polarization in a IIInitride based material, an almost ideally square-like hysteresis resulting in excellent piezoelectric linearity over a wide strain interval from -0.3% to +0.4% as well as a 2 paraelectric transition temperature in excess of 600°C are confirmed. This intriguing combination of properties is to our knowledge as of now unprecedented in the field of polycrystalline ferroelectric thin films and promises to significantly advance the commencing integration of ferroelectric functionality to micro-and nanotechnology, while at the same time providing substantial insight to one of the central open questions of the III-nitride semiconductors -that of their actual spontaneous polarization.

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Section: Methodsmentioning

confidence: 99%

AlScN: A III-V semiconductor based ferroelectric

Fichtner

Wolff

Lofink

et al. 2019

Journal of Applied Physics

490

379

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“…The permittivity and dielectric loss of the films can be obtained by measurement using impedance analyzer. To measure the piezoelectric coefficient of the films, a direct measurement approach based on double-beam interferometer was often used, the main characteristic of which is to discriminate the true film expansion from the bimorph-like binding of the sample [42,47]. In addition, many indirect measurement techniques based on cantilever structures [37], surface-acoustic-wave (SAW) resonators [48], and bulk-acoustic-wave (BAW) resonators [38] were also demonstrated to be effective to extract the piezoelectric coefficients.…”

Section: Thin-film Characterization Techniquesmentioning

confidence: 99%

Mechanical-Resonance-Enhanced Thin-Film Magnetoelectric Heterostructures for Magnetometers, Mechanical Antennas, Tunable RF Inductors, and Filters

Dong

Spetzler

et al. 2019

Materials

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The strong strain-mediated magnetoelectric (ME) coupling found in thin-film ME heterostructures has attracted an ever-increasing interest and enables realization of a great number of integrated multiferroic devices, such as magnetometers, mechanical antennas, RF tunable inductors and filters. This paper first reviews the thin-film characterization techniques for both piezoelectric and magnetostrictive thin films, which are crucial in determining the strength of the ME coupling. After that, the most recent progress on various integrated multiferroic devices based on thin-film ME heterostructures are presented. In particular, rapid development of thin-film ME magnetometers has been seen over the past few years. These ultra-sensitive magnetometers exhibit extremely low limit of detection (sub-pT/Hz1/2) for low-frequency AC magnetic fields, making them potential candidates for applications of medical diagnostics. Other devices reviewed in this paper include acoustically actuated nanomechanical ME antennas with miniaturized size by 1–2 orders compared to the conventional antenna; integrated RF tunable inductors with a wide operation frequency range; integrated RF tunable bandpass filter with dual H- and E-field tunability. All these integrated multiferroic devices are compact, lightweight, power-efficient, and potentially integrable with current complementary metal oxide semiconductor (CMOS) technology, showing great promise for applications in future biomedical, wireless communication, and reconfigurable electronic systems.

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“…To prepare samples for electrical characterization, Pt top electrodes were DC sputtered through a shadow mask. The diameter of the electrode holes on the shadow mask was 0.675 mm which is approximately equivalent to overall film/substrate thickness [28,29]. It should be noted that the actual diameter of the sputtered platinum electrodes may be slightly larger/smaller than the size of the holes on the shadow mask.…”

Section: Methodsmentioning

confidence: 99%

Impact of process conditions on chemical solution deposited BNKT thin film electromechanical properties

et al. 2021

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Phase pure perovskite (1-x)Bi1/2Na1/2TiO3 – xBi1/2K1/2TiO3 (BNKT) thin films were successfully prepared via an inverse mixing order chemical solution deposition method and the impact of process conditions on film properties were observed. Process conditions evaluated included crystallization temperature and time, ramp rate, pyrolysis temperature, and cation excess. Properties measured included crystal structure, dielectric constant, dielectric loss, piezoelectric response, and ferroelectric response. A few notable trends were observed. A subtle impact on piezoelectric response was observed in films prepared using different ramp rates: 100 C per second films (d33,f = 60 ± 5 pm/V at 1 kHz), 75 °C per second films (d33,f = 55 ± 5 pm/V) and 150 C per second films (d33,f = 50 ± 5 pm/V). Films prepared using a 75 °C per second ramp rate displayed slightly higher dielectric loss (tan δ = 0.09 at 1 kHz) than films prepared using a 100 °C per second ramp rate (tan δ = 0.07 at 1 kHz) or 150 °C per second ramp rate (tan δ = 0.05 at 1 kHz). Pyrolysis temperatures greater than 350 °C are necessary to burn off organics and maximize film dielectric constant. Dielectric constant increased from 450 ± 50 at 1 kHz to 600 ± 50 at 1 kHz by increasing pyrolysis temperature from 300 to 400 °C. Excess cation amounts (for compositional control) were also evaluated and it was found films with higher amounts of Na and K excess compared to bismuth excess displayed an increase in d33,f of about 10 pm/V compared to films prepared with equivalent Bi and Na and K excess amounts. Article highlights Impact of processing conditions on inverse mixing order chemical solution deposited bismuth based thin films. Dielectric, piezoelectric, and ferroelectric properties of thin film bismuth sodium titanate-bismuth potassium titanate thin films. Developing lead-free piezoelectric actuator materials.

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Concurrent wafer-level measurement of longitudinal and transverse effective piezoelectric coefficients (d33,f and e31,f) by double beam laser interferometry

Cited by 29 publications

References 17 publications

AlScN: A III-V semiconductor based ferroelectric

AlScN: A III-V semiconductor based ferroelectric

Mechanical-Resonance-Enhanced Thin-Film Magnetoelectric Heterostructures for Magnetometers, Mechanical Antennas, Tunable RF Inductors, and Filters

Impact of process conditions on chemical solution deposited BNKT thin film electromechanical properties

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