Your search keyword '"ACOUSTIC surface waves"' showing total 7,525 results

101. Multi-Parameter Characterization of Liquid-to-Ice Phase Transition Using Bulk Acoustic Waves.

Author

Smirnov, Andrey, Anisimkin, Vladimir, Voronova, Natalia, Kashin, Vadim, and Kuznetsova, Iren

Subjects

*PHASE transitions, *SOUND waves, *ACOUSTIC surface waves, *DISTILLED water

Abstract

The detection of the liquid-to-ice transition is an important challenge for many applications. In this paper, a method for multi-parameter characterization of the liquid-to-ice phase transition is proposed and tested. The method is based on the fundamental properties of bulk acoustic waves (BAWs). BAWs with shear vertical (SV) or shear horizontal (SH) polarization cannot propagate in liquids, only in solids such as ice. BAWs with longitudinal (L) polarization, however, can propagate in both liquids and solids, but with different velocities and attenuations. Velocities and attenuations for L-BAWs and SV-BAWs are measured in ice using parameters such as time delay and wave amplitude at a frequency range of 1–37 MHz. Based on these measurements, relevant parameters for Rayleigh surface acoustic waves and Poisson's modulus for ice are determined. The homogeneity of the ice sample is also detected along its length. A dual sensor has been developed and tested to analyze two-phase transitions in two liquids simultaneously. Distilled water and a 0.9% solution of NaCl in water were used as examples. [ABSTRACT FROM AUTHOR]

Published

2024

102. Efficient Generation of Plasma‐Activated Aerosols with High Concentrations of Reactive Species via Silicon Dioxide Coated Surface Acoustic Wave Devices.

Author

Chew, Nicholas S. L., Roudini, Mehrzad, Winkler, Andreas, Ooi, Chien W., Yeo, Leslie Y., and Tan, Ming K.

Subjects

*ACOUSTIC surface wave devices, *MICROBIOLOGICAL aerosols, *SILICA, *ACOUSTIC surface waves, *AEROSOLS, *SURFACE coatings

Abstract

An effective method to deliver plasma‐activated water onto contaminated surfaces is with a surface acoustic wave (SAW) nebulizer that can efficiently produce plasma‐activated aerosols. While higher reactive species concentrations in the plasma‐activated aerosols promote more efficient bacterial inactivation and hence reduce the amount of aerosols needed to completely eradicate the bacteria colonies, higher concentrations of reactive species themselves are found to lead to lower nebulization rates due to the increased electrical conductivity of the solution. To circumvent this problem, it is shown that coating the SAW substrate with a thin insulating layer of silicon dioxide (SiO2) can significantly mitigate the nebulization rate reduction. Specifically, when the electrical conductivity increases from 0.25 to 4.0 mS cm−1, the 62% drop in the nebulization rate is observed with the uncoated SAW devices is substantially reduced to 19% simply with the SiO2 coating. This can be attributed to the synergistic effects of increased wettability and the suppression of the electrical body force acting on the liquid film. The concomitant increase in the bacterial colony reduction from 17% to 76% demonstrates this solution to be a facile yet effective way of enhancing the efficiency for spray‐based bacterial inactivation on contaminated surfaces. [ABSTRACT FROM AUTHOR]

Published

2024

103. Temperature Characteristics of Rayleigh Wave and Leaky Surface Acoustic Wave Propagating in Langasite and its Application in Temperature Sensor.

Author

Yang, Y., Peng, B., Huang, F., Zhu, J., He, Z., He, P., and Zhang, W.

Subjects

*ACOUSTIC surface waves, *HIGH temperatures, *TEMPERATURE sensors, *DEBYE temperatures, *RESONANCE, *RAYLEIGH waves, *RAYLEIGH model

Abstract

A SAW resonator based on langasite (LGS) substrate with (0°, 138.5°, 116.6°) cut was designed and fabricated. Simulation and experimental results demonstrate that the resonator has two resonance modes, one Rayleigh wave and the other leaky surface acoustic wave (LSAW). The temperature dependent resonance frequencies of both Rayleigh wave and LSAW had been studied. The results show that the turnover temperature of LSAW mode is below absolute zero, namely, the resonance frequency of LSAW changes monotonically in rather wide temperature range, such as from cryogenic to ultrahigh temperatures. Real-time temperature measurement shows that the temperature sensor based on the LSAW mode can effectively monitor the environment temperature, as the thermocouple does. Our work suggests that the LSAW temperature sensor has great application potential in aerospace field for wide temperature range sensing. [ABSTRACT FROM AUTHOR]

Published

2024

104. Investigation of the Properties of Surface Acoustic Waves in a Lithium Niobate Single Crystal with a Silicon Dioxide Film by the Finite-Element Method.

Author

Balysheva, O. L., Koigerov, A. S., and Rakshaev, B. Ts.

Subjects

*SILICA films, *ACOUSTIC surface waves, *LITHIUM niobate, *FINITE element method, *SINGLE crystals, *SILICON crystals

Abstract

Characteristics of surface acoustic waves in lithium niobate single crystal/silicon dioxide film structures, which are used to increase the thermal stability of acoustoelectric devices on single-crystal substrates, have been calculated. The simulation has been performed by the finite-element method using the COMSOL software, and the velocity, electromechanical coupling coefficient, and temperature coefficient of frequency in the structures with lithium niobate of different cuts have been calculated. A good agreement is observed between the results obtained and the data in the literature. The obtained parameters are of practical importance for developing various acoustoelectric devices. [ABSTRACT FROM AUTHOR]

Published

2024

105. SAW Humidity Sensing with rr-P3HT Polymer Films.

Author

Jakubik, Wiesław, Wrotniak, Jarosław, Caliendo, Cinzia, Benetti, Massimiliano, Cannata, Domenico, Notargiacomo, Andrea, Stolarczyk, Agnieszka, and Kaźmierczak-Bałata, Anna

Subjects

*POLYMER films, *SURFACE acoustic wave sensors, *ACOUSTIC surface waves, *QUARTZ, *HUMIDITY, *ATOMIC force microscopy, *POLYMERIC membranes

Abstract

In the present paper the humidity sensing properties of regioregular rr-P3HT (poly-3-hexylthiophene) polymer films is investigated by means of surface acoustic wave (SAW) based sensors implemented on LiNbO3 (1280 Y-X) and ST-quartz piezoelectric substrates. The polymeric layers were deposited along the SAW propagation path by spray coating method and the layers thickness was measured by atomic force microscopy (AFM) technique. The response of the SAW devices to relative humidity (rh) changes in the range ~5–60% has been investigated by measuring the SAW phase and frequency changes induced by the (rh) absorption in the rr-P3HT layer. The SAW sensor implemented onto LiNbO3 showed improved performance as the thickness of the membrane increases (from 40 to 240 nm): for 240 nm thick polymeric membrane a phase shift of about −1.2 deg and −8.2 deg was measured for the fundamental (~78 MHz operating frequency) and 3rd (~234 MHz) harmonic wave at (rh) = 60%. A thick rr-P3HT film (~600 nm) was deposited onto the quartz-based SAW sensor: the sensor showed a linear frequency shift of ~−20.5 Hz per unit (rh) changes in the ~5–~50% rh range, and a quite fast response (~5 s) even at low humidity level (~5% rh). The LiNbO3 and quartz-based sensors response was assessed by using a dual delay line system to reduce unwanted common mode signals. The simple and cheap spray coating technology for the rr-P3HT polymer films deposition, complemented with fast low level humidity detection of the tested SAW sensors (much faster than the commercially available Michell SF-52 device), highlight their potential in a low-medium range humidity sensing application. [ABSTRACT FROM AUTHOR]

Published

2024

106. On a stabilization of the Ingard-Myers impedance boundary condition and its time domain implementation.

Author

Hu, Fang Q and Nark, Douglas M

Subjects

*ACOUSTIC surface waves, *BOUNDARY element methods, *FINITE differences, *MACH number, *DISPERSION relations, *KELVIN-Helmholtz instability, *SOUND wave scattering

Abstract

It has been well-known that the Ingard-Myers impedance condition, while simple to apply, is subject to the hydrodynamic Kelvin-Helmholtz-type instability due to its use of a vortex sheet in modeling the flow at the liner boundary. Recently, in the development of a time domain boundary element method for acoustic scattering by treated surfaces, it was found that by neglecting a certain second-order spatial derivative term in the Ingard-Myers formulation, the hydrodynamic instability can be avoided. The present paper aims to provide further analysis of this modified condition, hereby referred to as the Truncated Ingard-Myers Impedance Boundary Condition (TIMIBC). It will be shown, based on the dispersion relations of linear waves, that the instability intrinsic to the Ingard-Myers condition is eliminated in the proposed new formulation. Quantitative assessments on the accuracy of the TIMIBC for scattering of acoustic waves by lined surfaces are carried out, and its effectiveness is demonstrated by a numerical example. It is found that the TIMIBC provides a good approximation to the original Ingard-Myers condition for flows of low to mid subsonic Mach numbers. As such, the proposed TIMIBC can offer a practical solution for overcoming the intrinsic instability associated with the Ingard-Myers condition. Moreover, time domain implementation of the TIMIBC is also discussed and illustrated with a numerical example using a finite difference scheme. In particular, a minimization procedure for finding the poles and coefficients of a broadband multipole expansion for the impedance function is formulated by which, unlike the commonly used vector-fitting method, passivity of the model is ensured. [ABSTRACT FROM AUTHOR]

Published

2024

107. Drilling, Fracturing, and Characterizing Enhanced Geothermal Systems.

Author

McLennan, John, Moore, Joseph N., and England, Kevin

Subjects

GEOTHERMAL resources, HORIZONTAL wells, GAS condensate reservoirs, ACOUSTIC surface waves, ROCK deformation, INJECTION wells, GEOTHERMAL engineering, CARBON sequestration

Abstract

The article focuses on the potential of geothermal energy, particularly through Enhanced Geothermal Systems (EGS), which aim to harness deep Earth heat for electricity and heating/cooling. It discusses the historical context of geothermal technologies, the current state of EGS technology, including challenges and recent innovations, and initiatives like the FORGE project aimed at advancing EGS from experimental stages to commercial viability.

Published

2024

108. Embedded real-time ultrasound-based multi-touch system.

Author

Bilodeau, Maxime, Moriot, Jérémy, Fréchette-Viens, Joëlle, Bouchard, Raphaël, Boulais, Philippe, Quaegebeur, Nicolas, and Masson, Patrice

Subjects

PIEZOELECTRIC ceramics, ZIRCONATES, CAPACITIVE sensors, ACOUSTIC surface waves, ENERGY consumption

Abstract

In this paper, an active ultrasound-based touchscreen technology is presented for real-time monitoring of multiple contacts on a glass panel of 20 × 19 cm. Both fundamental Lamb wave modes are generated by sending a linear chirp between 50 and 100 kHz to a single piezoelectric ceramic lead zirconate titanate. Measurement is performed using four piezoelectric ceramic lead zirconate titanate elements, and real-time localization and detection are performed on a system on module i.MX 8 M Nano. Results show that Lamb waves can be used for real-time multi-touch detection and localization on both sides of the panel. Moreover, the prototype developed allows for relative pressure measurement. [ABSTRACT FROM AUTHOR]

Published

2024

109. A blueprint for truncation resonance placement in elastic diatomic lattices with unit cell asymmetrya).

Author

Al Ba'ba'a, Hasan B., Yousef, Hosam, and Nouh, Mostafa

Subjects

BAND gaps, THEORY of wave motion, METAMATERIALS, ACOUSTIC surface waves, WAVENUMBER

Abstract

Elastic periodic lattices act as mechanical filters of incident vibrations. By and large, they forbid wave propagation within bandgaps and resonate outside them. However, they often encounter "truncation resonances" (TRs) inside bandgaps when certain conditions are met. In this study, we show that the extent of unit cell asymmetry, its mass and stiffness contrasts, and the boundary conditions all play a role in the TR location and wave profile. The work is experimentally supported via two examples that validate the methodology, and a set of design charts is provided as a blueprint for selective TR placement in diatomic lattices. [ABSTRACT FROM AUTHOR]

Published

2024

110. Surface and bulk acoustic wave resonators based on aluminum nitride for bandpass filters.

Author

Xian-Hu Zha, Jing-Ting Luo, Ran Tao, and Chen Fu

Subjects

ACOUSTIC resonators, ACOUSTIC surface waves, ALUMINUM nitride, BANDPASS filters, INSERTION loss (Telecommunication)

Abstract

Bandpass filters with high frequency and wide bandwidth are indispensable parts of the fifth-generation telecommunication technologies, and currently, they are mainly based on surface and bulk acoustic wave resonators. Owing to its high mechanical strength, excellent stability at elevated temperatures, good thermal conductivity, and compatibility with complementary metal-oxide-semiconductor technology, aluminum nitride (AlN) becomes the primary piezoelectric material for high-frequency resonators. This review briefly introduces the structures and key performance parameters of the acoustic resonators. The common filter topologies are also discussed. In particular, research progresses in the piezoelectric AlN layer, electrodes, and substrates of the resonators are elaborated. Increasing the electromechanical coupling constant is the main concern for the AlN film. To synthesize AlN in single-crystalline or poly-crystalline with a high intensity of (0002) orientation, and alloy the AlN with other elements are two effective approaches. For the substrates and bottom electrodes, lattice and thermal expansion mismatch, and surface roughness are critical for the synthesis of a high-crystal-quality piezoelectric layer. The electrodes with low electrical resistance, large acoustic-impedance mismatch to the piezoelectric layer, and low density are ideal to reduce insertion loss. Based on the research progress, several possible research directions in the AlN-based filters are suggested at the end of the paper. [ABSTRACT FROM AUTHOR]

Published

2024

111. Acoustic Effects of Uneven Polymeric Layers on Tunable SAW Oscillators.

Author

Nicolae, Ionut, Bojan, Mihaela, and Viespe, Cristian

Subjects

ACOUSTIC surface waves, ACOUSTIC resonance, SAWS, RESONANCE, SURFACE acoustic wave sensors, ACOUSTIC vibrations

Abstract

Surface acoustic wave (SAW) sensors in tunable oscillator configuration, with a deposited polymeric layer, were used to investigate the layer's impact on the oscillator's resonant frequency. The SAW oscillators were tuned by means of variable loop amplification. Full-range amplification variation led to a resonant frequency increase of ~1.7 MHz due to the layer's nonlinear reaction. The layer's morphology and location resulted in a specific resonant frequency–amplitude dependence. Five types of layers were used to test the causal linkage between the layers' morphological parameters or positioning and the SAW oscillator's resonant frequency. The frequency variation trend is almost linear, with a complex minute variation. Small amplitude sigmoids occur at certain attenuation values, due to layer acoustic resonances. Multiple sigmoids were linked with layer resonances of different orders. A good correlation between the layer's thickness and resonance position was found. [ABSTRACT FROM AUTHOR]

Published

2024

112. Material Damping Estimation within Low-, Medium- and High-Frequency Ranges.

Author

Tonazzi, Davide, Meziane, Anissa, Culla, Antonio, Biateau, Christine, Pepe, Gianluca, and Massi, Francesco

Subjects

ACOUSTIC surface waves, APPLIED mechanics, STATISTICAL energy analysis, THEORY of wave motion, STRUCTURAL health monitoring, ROLLING friction, ACOUSTIC wave propagation

Published

2024

113. Ultrasound: A new strategy for artificial synapses modulation.

Author

Yuan, Junru, Li, Yi, Wang, Meng, Huang, Xiaodi, Zhang, Tao, Xue, Kan‐Hao, Yuan, Junhui, Ou‐Yang, Jun, Yang, Xiaofei, Miao, Xiangshui, and Zhu, Benpeng

Subjects

ACOUSTIC surface waves, ACTION potentials, ULTRASONIC imaging, SCHOTTKY barrier, VOLTAGE

Abstract

Due to its non‐invasive nature, ultrasound has been widely used for neuromodulation in biological systems, where its application influences the synaptic weights and the process of neurotransmitter delivery. However, such modulation has not been emulated in physical devices. Memristors are ideal electrical components for artificial synapses, but up till now they are hardly reported to respond to ultrasound signals. Here we design and fabricate a HfOx‐based memristor on 64°Y‐X LiNbO3 single crystal substrate, and successfully realize artificial synapses modulation by shear‐horizontal surface acoustic wave (SH‐SAW). It is a prominent short‐term resistance modulation, where ultrasound has been shown to cause resistance drop for various resistance states, which could fully recover after the ultrasound is shut off. The physical mechanism illustrates that ultrasound induced polarization potential in the HfOx dielectric layer acts on the Schottky barrier, leading to the resistance drop. The emulation of neuron firing frequency modulation through ultrasound signals is demonstrated. Moreover, the joint application of ultrasound and electric voltage yields fruitful functionalities, such as the enhancement of resistance window and synaptic plasticity through ultrasound application. All these promising results provide a new strategy for artificial synapses modulation, and also further advance neuromorphic devices toward system applications. [ABSTRACT FROM AUTHOR]

Published

2024

114. On propagation behavior of shear wave in piezoelectric-sandwiched structure.

Author

Saroj, Pradeep Kumar

Subjects

SHEAR waves, ACOUSTIC surface waves, PHASE velocity, THEORY of wave motion, PIEZOELECTRIC devices, PIEZOELECTRICITY, ELASTIC waves

Abstract

This paper delves into the analysis of shear wave propagation with a sandwiched structure comprising a piezoelectric layer and an elastic layer, with a transversely isotropic layer in between. The frequency equation has been derived following Biot's theory. The dimensionless phase velocities numerical values are computed and visually depicted to demonstrate their dependencies on anisotropy, piezoelectricity, initial stress and porosity in a comparative manner. The explicit demonstration of the relationship between each parameter and the geometry has been presented. The observation shows that as porosity in the medium increases, the phase velocity also increases. Furthermore, the existence of medium anisotropy results in a decrease in the phase velocity of shear waves. Moreover, a correlation is observed where higher tensile initial stress within the medium leads to a corresponding reduction in the phase velocity of shear waves. We conclude that considered parameters (viz. piezoelectricity, anisotropy, porosity, initial stress and thickness of layers) affect the velocity profile of the shear waves significantly. This study holds practical significance in the development of innovative-layered composites, surface acoustic wave (SAW) devices and sensors utilizing intelligent piezoelectric devices for engineering purposes. [ABSTRACT FROM AUTHOR]

Published

2024

115. Particle distributions in Lamb wave based acoustofluidics.

Author

Zhang, Chuanchao, Chen, Xian, Wei, Wei, Chen, Xuejiao, Li, Quanning, and Duan, Xuexin

Subjects

LAMB waves, ACOUSTIC radiation force, ACOUSTIC surface waves, ACOUSTIC streaming, PARTICLE motion, DRAG force, GRANULAR flow

Abstract

Acoustic streaming enabled by a Lamb wave resonator (LWR) is efficient for particle trapping and enrichment in microfluidic channels. However, because Lamb waves combine the features of bulk acoustic waves and surface acoustic waves, the resulting acoustic streaming in the LWR occurs in multiple planes, and the particle flow behavior in this acoustofluidic system is largely unknown. Reported here are numerical simulations and laboratory experiments conducted to investigate the boundary conditions for particle motion inside a microvortex induced by an LWR. Upon dynamic capture, the particles' trajectories become orbital paths within an acoustic vortex. The suspended particles encounter two distinct acoustic phenomena, i.e., the drag force resulting from acoustic streaming and the acoustic radiation force, which exert forces in various directions on the particles. When the acoustic radiation force and the fluid drag force are dominant for large and small particles in a mixed solution, respectively, the large particles reside within the vortex while the small particles remain at its periphery. Conversely, when the acoustic radiation force is dominant for both types of particles, the distribution pattern is reversed. ARTICLE HIGHLIGHTS: HIGHLIGHTS • A Lamb wave resonator (LWR) was fabricated and used for particle manipulation, and upon analyzing the forces acting on the particles, two distinct distribution patterns are found. • Particles in the acoustic streaming are dominated by different forces depending on their size and the frequency of the LWR. • An LWR with a frequency of 370 MHz was used, and this frequency induces a potent acoustic flow in the LWR that is suitable for particle manipulation. [ABSTRACT FROM AUTHOR]

Published

2024

116. Concentration of Microparticles/Cells Based on an Ultra-Fast Centrifuge Virtual Tunnel Driven by a Novel Lamb Wave Resonator Array.

Author

Wei, Wei, Wang, Zhaoxun, Wang, Bingnan, Pang, Wei, Yang, Qingrui, and Duan, Xuexin

Subjects

LAMB waves, ACOUSTIC surface waves, TISSUE engineering, MICROFLUIDIC devices, RESONATORS, CENTRIFUGES, ENERGY dissipation

Abstract

The µTAS/LOC, a highly integrated microsystem, consolidates multiple bioanalytical functions within a single chip, enhancing efficiency and precision in bioanalysis and biomedical operations. Microfluidic centrifugation, a key component of LOC devices, enables rapid capture and enrichment of tiny objects in samples, improving sensitivity and accuracy of detection and diagnosis. However, microfluidic systems face challenges due to viscosity dominance and difficulty in vortex formation. Acoustic-based centrifugation, particularly those using surface acoustic waves (SAWs), have shown promise in applications such as particle concentration, separation, and droplet mixing. However, challenges include accurate droplet placement, energy loss from off-axis positioning, and limited energy transfer from low-frequency SAW resonators, restricting centrifugal speed and sample volume. In this work, we introduce a novel ring array composed of eight Lamb wave resonators (LWRs), forming an Ultra-Fast Centrifuge Tunnel (UFCT) in a microfluidic system. The UFCT eliminates secondary vortices, concentrating energy in the main vortex and maximizing acoustic-to-streaming energy conversion. It enables ultra-fast centrifugation with a larger liquid capacity (50 μL), reduced power usage (50 mW) that is one order of magnitude smaller than existing devices, and greater linear speed (62 mm/s), surpassing the limitations of prior methods. We demonstrate successful high-fold enrichment of 2 μm and 10 μm particles and explore the UFCT's potential in tissue engineering by encapsulating cells in a hydrogel-based micro-organ with a ring structure, which is of great significance for building more complex manipulation platforms for particles and cells in a bio-compatible and contactless manner. [ABSTRACT FROM AUTHOR]

Published

2024

117. Finite element simulation and experimental study of laser-generated surface acoustic waves on determining mechanical properties of thin film.

Author

Zhang, Li, Xiao, Xia, Qi, Haiyang, Liu, Zhuo, Zhang, Jinsong, and Chen, Long

Subjects

*ACOUSTIC surface waves, *THIN films, *YOUNG'S modulus, *NONDESTRUCTIVE testing, *FINITE element method, *THERMOGRAPHY

Abstract

The laser-generated surface acoustic wave (LSAW) nondestructive testing (NDT) technique is a promising method to characterize the mechanical properties of thin films. In this study, based on the thermoelastic mechanism, a finite element method (FEM) is put forward to simulate the LSAW in the film/substrate structure, and the effect of the temporal and spatial distribution of the Gaussian pulse laser on the Rayleigh-type SAW signals is revealed. For the SiO2 and low dielectric constant (low-k) dense Black Diamond™ (SiOC:H, BD) films with the thickness of 500 and 1000 nm, the typical displacement waveforms of SAW at a series of probing points along the propagation direction are obtained. By analyzing the full width at half maximum (FWHM) of the signal, the optimal NDT experimental conditions for laser are determined with the minimum possible pulse rising time and the linewidth less than 10 μm. Based on the FEM simulation result, the LSAW NDT experiment is carried out and the dispersion curve of SAW is calculated to characterize Young's modulus of the SiO2 and low-k samples. It is found that the experimental results are in good agreement with the simulation results. This study verifies the validity of FEM simulation of LSAW in layered structures containing thin film and that the laser parameters determined by FEM fit perfectly in characterizing the mechanical properties of thin films. [ABSTRACT FROM AUTHOR]

Published

2022

118. Simultaneous determination of Young's modulus and Poisson's ratio in metals from a single surface using laser-generated Rayleigh and leaky surface acoustic waves.

Author

Canfield, Ryan, Ziaja-Sujdak, Aleksandra, Pitre, John J., O'Donnell, Matthew, Ambrozinski, Lukasz, and Pelivanov, Ivan

Subjects

*ACOUSTIC surface waves, *YOUNG'S modulus, *POISSON'S ratio, *RAYLEIGH waves, *ELASTIC constants, *LONGITUDINAL waves, *THEORY of wave motion

Abstract

Material elastic moduli are used to assess stiffness, elastic response, strength, and residual life. Ultrasound (US) measurements of propagation wave speeds (for longitudinal and shear waves) are now primary tools for non-destructive evaluation (NDE) of elastic moduli. Most US techniques measure the time-of-flight of through-transmission signals or reflected signals from the back wall. In both cases, an independently determined sample thickness is required. However, US methods are difficult for complex (non-flat) samples. When the local thickness is unknown, the propagation speed cannot be determined. On the other hand, the propagation speed of Rayleigh waves can be calculated without knowledge of sample thickness, but another independent measurement is still required to compute both Young's modulus and Poisson's ratio. We present a comprehensive theoretical background, numerical simulations, and experimental results that clearly show that when the material density is assumed known, both elastic constants of an isotropic metal sample can be determined with laser-ultrasound by tracking two types of surface propagating waves without any sample contact (both signal excitation and detection are performed optically). In addition to a conventional surface, or Rayleigh, acoustic wave, a leaky surface wave can also be launched with nanosecond laser pulses in the thermoelastic regime of excitation (i.e., without material ablation) close to the source that propagates along the sample surface with speed close to that of bulk longitudinal waves. Samples can be of arbitrary shape and their thickness need not be measured. [ABSTRACT FROM AUTHOR]

Published

2022

119. Polarization retention dependence of imprint time within LiNbO3 single-crystal domain wall devices.

Author

Zhang, Wen Di, Zhuang, Xiao, Jiang, Jun, and Jiang, An Quan

Subjects

*HYSTERESIS loop, *ACOUSTIC surface waves, *PYROELECTRIC detectors, *PHOTOVOLTAIC effect, *ACOUSTIC filters, *CHARGE injection, *SILICON films

Abstract

Ferroelectric LiNbO3 single crystals have wide applications in surface acoustic wave filters, pyroelectric sensors, and electro-optic modulators. Large-area LiNbO3 single-crystal thin films integrated on silicon are promising for high density integration of ferroelectric domain-wall resistance switching memories and transistors. However, the short-time operation of the memory often suffers from poor polarization retention due to the built-in imprint voltage. Here, we observed the strong polarization orientation-dependent imprint effect within either out-of-plane or in-plane LiNbO3 thin-film capacitors. The imprint effect can shift domain switching hysteresis loops toward positive/negative voltages seriously with written negative/positive polarizations that occur within a characteristic imprint time of 5.1 ms–360 s. Once the write time of the memory is shorter than the imprint time, the inverted domain is unstable and switches back into its previous orientation automatically after the termination of a write operation. However, the write failure can be avoided if the write time is longer than the imprint time, and the written domain can be deeply protected by the imprint field. A model of polarization-dependent charge injection at the interface is developed to explain the time-dependent imprint effect. For a mesa-like LiNbO3 memory cell in contact with two side electrodes fabricated at the film surface, the imprint time can be greatly shortened below 30 ns with the extension of one side electrode over the cell surface to screen the tail of the switched domain, enabling ferroelectric domain-wall resistance switching devices in excellent retention and high operation speeds. [ABSTRACT FROM AUTHOR]

Published

2022

120. Analysis of the acoustoelectric response of SAW gas sensors using a COM model.

Author

Yuan, Yang, Yang, Tao, Chen, Xi, Yu, Linglang, Hou, Xiaoxiao, Zhang, Guangzu, Dong, Wen, Lu, Zixiao, Li, Honglang, Reindl, Leonhard, and Luo, Wei

Subjects

SURFACE acoustic wave sensors, GAS detectors, ACOUSTIC surface waves, ACOUSTOELECTRIC effects, ENERGY futures

Abstract

Surface acoustic wave (SAW) gas sensors based on the acoustoelectric effect exhibit wide application prospects for in situ gas detection. However, establishing accurate models for calculating the scattering parameters of SAW gas sensors remains a challenge. Here, we present a coupling of modes (COM) model that includes the acoustoelectric effect and specifically explains the nonmonotonic variation in the center frequency with respect to the sensing film's sheet conductivity. Several sensing parameters of the gas sensors, including the center frequency, insertion loss, and phase, were experimentally compared for accuracy and practicality. Finally, the frequency of the phase extremum (FPE) shift was determined to vary monotonically, and the range of selectable test points was wide, making the FPE an appropriate response parameter for leveraging in SAW gas sensors. The simulation results of the COM model were highly consistent with the experimental results. Our study is proposed to provide theoretical guidance for the future development of gas SAW sensors. [ABSTRACT FROM AUTHOR]

Published

2024

121. Synthesis and characterization of nitrogen-doped-MWCNT@cobalt oxide for nerve agent simulant detection.

Author

Lama, Sanjeeb, Choi, Hyeong-Seon, Ramesh, Sivalingam, Lee, Young Jun, and Kim, Joo Hyung

Subjects

*NERVE gases, *MULTIWALLED carbon nanotubes, *ACOUSTIC surface waves, *QUARTZ crystal microbalances, *HYBRID materials, *ORGANOPHOSPHORUS pesticides, *NITROGEN, *PHOSPHONATES

Abstract

Organophosphorus nerve agents are toxic compounds that disrupt neuromuscular transmission by inhibiting the neurotransmitter enzyme, acetylcholinesterase, leading to rapid death. A hybrid composite was synthesized using a hydrothermal process for the early detection of dimethyl methyl phosphonate (DMMP), a simulant of the G-series nerve agent, sarin. Quartz crystal microbalance (QCM) and surface acoustic wave (SAW) sensors were used as detectors. Nitrogen-doped multiwalled carbon nanotubes (N-MWCNTs), cobalt oxide (Co3O4), and N-MWCNT@Co3O4 were compared to detect DMMP concentrations of 25–150 ppm. At 25 ppm, the differential frequencies (Δf) of the N-MWCNT, Co3O4, and N-MWCNT@Co3O4 sensors were 5.8, 2.3, and 99.5 Hz, respectively. The selectivity results revealed a preference for the DMMP rather than potential interference. The coefficients of determination (R2) of the N-MWCNT, Co3O4, and N-MWCNT@Co3O4 sensors for detecting 25–150 ppm DMMP were 0.983, 0.986, and 0.999, respectively. The response times of the N-MWCNT, Co3O4, and N-MWCNT@Co3O4 sensors for detecting 100 ppm DMMP were 25, 27, and 34 s, respectively, while the corresponding recovery times were 85, 105, and 181 s. The repeatability results revealed the reversible adsorption and desorption phenomena for the fixed DMMP concentration of 100 ppm. These unique findings show that synthesized materials can be used to detect organophosphorus nerve agents. [ABSTRACT FROM AUTHOR]

Published

2024

122. FEM Modeling Strategies: Application to Mechanical and Dielectric Sensitivities of Love Wave Devices in Liquid Medium.

Author

Rube, Maxence, Tamarin, Ollivier, Choudhari, Asawari, Sebeloue, Martine, Rebiere, Dominique, and Dejous, Corinne

Subjects

*HONEY, *FINITE element method, *LIQUID dielectrics, *DIELECTRIC properties, *ACOUSTIC surface waves, *DIELECTRICS

Abstract

This paper presents an extended work on the Finite Element Method (FEM) simulation of Love Wave (LW) sensors in a liquid medium. Two models are proposed to simulate the multiphysical response of the sensor. Both are extensively described in terms of principle, composition and behavior, making their applications easily reproducible by the sensor community. The first model is a Representative Volume Element (RVE) simulating the transducer and the second focuses on the sensor's longitudinal (OXZ) cut which simulates the multiphysical responses of the device. Sensitivity of the LW device to variations in the rheological and dielectric properties of liquids is estimated and then compared to a large set of measurements issued from LW sensors presenting different technological characteristics. This integral approach allows for a deeper insight into the multiphysical behavior of the LW sensor. This article also explores the advantages and drawbacks of each model. Both are in good accordance with the measurements and could be used for various applications, for which a non-exhaustive list is proposed in the conclusion. [ABSTRACT FROM AUTHOR]

Published

2024

123. Ultrasonic manipulation of particles and cell aggregates with simultaneous acoustic visualization.

Author

Ortega-Sandoval, Mario E., Cox, Luke, Franklin, Amanda, Lavelle, Martha, Armstrong, James P. K., and Drinkwater, Bruce W.

Subjects

*ACOUSTIC surface waves, *SOUND waves, *ACOUSTIC field, *DATA visualization, *PRINTED circuits

Abstract

Acoustical tweezers can manipulate inanimate particles as well as living cells in liquid in 2D using surface acoustic waves and in 3D using bulk acoustic waves. Here, we demonstrate a MHz twin-trap device for underwater manipulation of particles and cell aggregates and show that it operates effectively within a Petri dish and a plastic tube. We also describe a method to visualize in real time the acoustic field using a contained layer of small, high-density particles, which allows the trap to be seen in the same image as the manipulated particle. The device used was made with simple components, integrated onto a printed circuit board, and requires a single electrical channel for excitation. As a result, this device has the potential to be widely implemented in applications such as micro-organism manipulation, in vivo manipulation, and drug delivery. [ABSTRACT FROM AUTHOR]

Published

2024

124. Transport of skyrmions by surface acoustic waves.

Author

Shuai, Jintao, Lopez-Diaz, Luis, Cunningham, John E., and Moore, Thomas A.

Subjects

*ACOUSTIC surface waves, *SKYRMIONS, *AUTOMOBILE racetracks, *PERPENDICULAR magnetic anisotropy, *MAGNETIC films, *THIN films, *LOGIC devices

Abstract

Magnetic skyrmions in thin films with perpendicular magnetic anisotropy are promising candidates for magnetic memory and logic devices, making the development of ways to transport skyrmions efficiently in a desired trajectory of significant interest. Here, we investigate the transport of skyrmions by surface acoustic waves (SAWs) via several modalities using micromagnetic simulations. We show skyrmion pinning sites created by standing SAWs at anti-nodes and skyrmion Hall-like motion without pinning driven by traveling SAWs. We also show how orthogonal SAWs formed by combining a longitudinal traveling SAW and a transverse standing SAW can be used for the 2D positioning of skyrmions. Our results also suggest SAWs offer a viable approach to the transport of multiple skyrmions along a multichannel racetrack. [ABSTRACT FROM AUTHOR]

Published

2024

125. Quasi-Bessel surface acoustic wave for dynamic acoustic manipulation.

Author

Shi, Jingyao, Zhang, Chunqiu, Li, Pengqi, Peng, Benxian, Li, Xinjia, Liu, Xiufang, and Zhou, Wei

Subjects

*ACOUSTIC surface waves, *SOUND waves, *ACOUSTIC field, *INTERDIGITAL transducers, *BESSEL beams, *DIELECTROPHORESIS, *SOUND design

Abstract

Acoustic manipulation using surface acoustic wave has aroused widespread interest in life sciences, biomedical, and bioanalytical chemistry. Acoustic manipulation for different applications requires different acoustic fields. Bessel beams are non-diffractive and re-constructable, bringing possibility and versatility of acoustic manipulation integrated on microfluidic chips. To date, there are a few studies on constructing Bessel surface acoustic waves. Moreover, there is still a lack of dynamic acoustic manipulation using Bessel surface acoustic waves propagating along a surface of piezoelectric substrate with simple and high-precision devices. Here, we design a device with two omnidirectional equifrequency interdigital transducers to form a quasi-Bessel surface acoustic wave by means of coherent interference. The proposed device avoids influences of anisotropy on its operating frequency, making its quasi-Bessel beam accurately and stably conform to the predetermined design acoustic field. This acoustic field could control micrometer to submicrometer particles and dynamically move particles along lateral direction and axial direction of the propagation of quasi-Bessel beam. A phenomenon similar to negative force appeared when the two-micron spherical particles were manipulated. The quasi-Bessel beam formed by our device can provide a versatile movement for on-chip acoustic manipulation. [ABSTRACT FROM AUTHOR]

Published

2024

126. Metamaterial control of the surface acoustic wave streaming jet.

Author

Pouya, C and Nash, G R

Subjects

*ACOUSTIC surface waves, *ACOUSTIC streaming, *JET streams, *SPEED of sound, *RAYLEIGH waves

Abstract

The phenomenon of surface acoustic wave (SAW) streaming, where a streaming jet is created, occurs when an SAW propagating on the surface of a solid interacts with water, and underpins the increasingly important area of SAW microfluidics. A key characteristic of the streaming jet is the Rayleigh angle, i.e. the angle at which the jet is formed relative to the surface normal of the solid, which is determined by the ratio of the velocity of the acoustic wave in the fluid and in the solid. Although the ability to dynamically tune this angle would offer a novel tool for microfluidic control, the SAW velocity is normally fixed by the characteristics of the solid and liquid material properties. In this paper we show, using finite element method modelling, that changing the SAW Rayleigh wave phase velocity by patterning a metamaterial array, consisting of square annular holes, onto the surface of an SAW device can change the acoustic streaming Rayleigh angle by approximately a factor of two, in good agreement with calculations based on the change in velocity. [ABSTRACT FROM AUTHOR]

Published

2024

127. Coherent optical coupling to surface acoustic wave devices.

Author

Iyer, Arjun, Kandel, Yadav P., Xu, Wendao, Nichol, John M., and Renninger, William H.

Subjects

ACOUSTIC surface wave devices, ACOUSTIC surface waves, MATERIALS science, QUALITY factor, ELECTROMECHANICAL effects

Abstract

Surface acoustic waves (SAW) and associated devices are ideal for sensing, metrology, and hybrid quantum devices. While the advances demonstrated to date are largely based on electromechanical coupling, a robust and customizable coherent optical coupling would unlock mature and powerful cavity optomechanical control techniques and an efficient optical pathway for long-distance quantum links. Here we demonstrate direct and robust coherent optical coupling to Gaussian surface acoustic wave cavities with small mode volumes and high quality factors (>105 measured here) through a Brillouin-like optomechanical interaction. High-frequency SAW cavities designed with curved metallic acoustic reflectors deposited on crystalline substrates are efficiently optically accessed along piezo-active directions, as well as non-piezo-active (electromechanically inaccessible) directions. The precise optical technique uniquely enables controlled analysis of dissipation mechanisms as well as detailed transverse spatial mode spectroscopy. These advantages combined with simple fabrication, large power handling, and strong coupling to quantum systems make SAW optomechanical platforms particularly attractive for sensing, material science, and hybrid quantum systems. Surface acoustic wave devices enable modern electronics and are desirable for quantum systems. Here the authors access and control these devices optically, enabling high acoustic quality factors, materials spectroscopy, and hybrid quantum systems. [ABSTRACT FROM AUTHOR]

Published

2024

128. A review of surface acoustic wave sensors: mechanisms, stability and future prospects.

Author

Tang, Zhaozhao, Wu, Wenyan, Yang, Po, Luo, Jingting, Fu, Chen, Han, Jing-Cheng, Zhou, Yang, Wang, Linlin, Wu, Yingju, and Huang, Yuefei

Subjects

*SURFACE acoustic wave sensors, *ACOUSTIC surface waves

Abstract

Purpose: Surface acoustic wave (SAW) sensors have attracted great attention worldwide for a variety of applications in measuring physical, chemical and biological parameters. However, stability has been one of the key issues which have limited their effective commercial applications. To fully understand this challenge of operation stability, this paper aims to systematically review mechanisms, stability issues and future challenges of SAW sensors for various applications. Design/methodology/approach: This review paper starts with different types of SAWs, advantages and disadvantages of different types of SAW sensors and then the stability issues of SAW sensors. Subsequently, recent efforts made by researchers for improving working stability of SAW sensors are reviewed. Finally, it discusses the existing challenges and future prospects of SAW sensors in the rapidly growing Internet of Things-enabled application market. Findings: A large number of scientific articles related to SAW technologies were found, and a number of opportunities for future researchers were identified. Over the past 20 years, SAW-related research has gained a growing interest of researchers. SAW sensors have attracted more and more researchers worldwide over the years, but the research topics of SAW sensor stability only own an extremely poor percentage in the total researc topics of SAWs or SAW sensors. Originality/value: Although SAW sensors have been attracting researchers worldwide for decades, researchers mainly focused on the new materials and design strategies for SAW sensors to achieve good sensitivity and selectivity, and little work can be found on the stability issues of SAW sensors, which are so important for SAW sensor industries and one of the key factors to be mature products. Therefore, this paper systematically reviewed the SAW sensors from their fundamental mechanisms to stability issues and indicated their future challenges for various applications. [ABSTRACT FROM AUTHOR]

Published

2024

129. Ultrasonic surface acoustic wave elastography: A review of basic theories, technical developments, and medical applications.

Author

Masud, Abdullah Al and Liu, Jingfei

Subjects

*ACOUSTIC surface waves, *ELASTOGRAPHY, *ACOUSTIC wave propagation, *TISSUE mechanics, *ULTRASONIC imaging, *ULTRASONICS

Abstract

Physiological and pathological changes in tissues often cause changes in tissue mechanical properties, making tissue elastography an effective modality in medical imaging. Among the existing elastography methods, ultrasound elastography is of great interest due to the inherent advantages of ultrasound imaging technology, such as low cost, portability, safety, and wide availability. However, most current ultrasound elastography methods are based on the bulk shear wave; they can image deep tissues but cannot image superficial tissues. To address this challenge, ultrasonic elastography methods based on surface acoustic waves have been proposed. In this paper, we present a comprehensive review of ultrasound‐based surface acoustic wave elastography techniques, including their theoretical foundations, technical implementations, and existing medical applications. The goal is to provide a concise summary of the state‐of‐the‐art of this field, hoping to offer a reliable reference for the further development of these techniques and foster the expansion of their medical applications. [ABSTRACT FROM AUTHOR]

Published

2024

130. Irreversible Bonding of Polydimethylsiloxane‐Lithium Niobate using Oxygen Plasma Modification for Surface Acoustic Wave based Microfluidic Application: Theory and Experiment.

Author

He, Chunhua, Yao, Jinhui, Yang, Canfeng, Wang, Jianxin, Sun, Bo, Liao, Guanglan, Shi, Tielin, and Liu, Zhiyong

Subjects

*ACOUSTIC surface waves, *QUARTZ crystal microbalances, *OXYGEN plasmas, *BOND prices, *LITHIUM niobate, *THERMAL expansion

Abstract

Acoustic microfluidic chips, fabricated by combining lithium niobate (LiNbO3) with polydimethylsiloxane (PDMS), practically find applications in biomedicine. However, high‐strength direct bonding of LiNbO3 substrate with PDMS microchannel remains a challenge due to the large mismatching of thermal expansion coefficient at the interface and the lack of bonding theory. This paper elaborately reveals the bonding mechanisms of PDMS and LiNbO3, demonstrating an irreversible bonding method for PDMS‐LiNbO3 heterostructures using oxygen plasma modification. An in‐situ monitoring strategy by using resonant devices is proposed for oxygen plasma, including quartz crystal microbalance (QCM) covered with PDMS and surface acoustic wave (SAW) fabricated by LiNbO3. When oxygen plasma exposure occurs, surfaces are cleaned, oxygen ions are implanted, and hydroxyl groups (‐OH) are formed. Upon interfaces bonding, the interface will form niobium‐oxygen‐silicon covalent bonds to realize an irreversible connection. A champion bonding strength is obtained of 1.1 MPa, and the PDMS‐LiNbO3 acoustic microfluidic chip excels in leakage tests, withstanding pressures exceeding 60 psi, outperforming many previously reported devices. This work addresses the gap in PDMS‐LiNbO3 bonding theory and advances its practical application in the acoustic microfluidic field. [ABSTRACT FROM AUTHOR]

Published

2024

131. An Influence of Actuator Gluing on Elastic Wave Excited in the Structure.

Author

Ziaja, Dominika and Jurek, Michał

Subjects

*ACOUSTIC surface waves, *ELASTIC wave propagation, *ELASTIC waves, *GLUE, *STRUCTURAL engineering, *CIVIL engineering

Abstract

In this article, the practical issues connected with guided wave measurement are studied: (1) the influence of gluing of PZT plate actuators (NAC2013) on generated elastic wave propagation, (2) the repeatability of PZT transducers attachment, and (3) the assessment of the possibility of comparing the results of Laser Doppler Vibrometry (LDV) measurement performed on different 2D samples. The consideration of these questions is crucial in the context of the assessment of the possibility of the application of the guided wave phenomenon to structural health-monitoring systems, e.g., in civil engineering. In the examination, laboratory tests on the web of steel I-section specimens were conducted. The size and shape of the specimens were developed in such a way that they were similar to the elements typically used in civil engineering structures. It was proved that the highest amplitude of the generated wave was obtained when the exciters were glued using wax. The repeatability and durability of this connection type were the weakest. Due to this reason, it was not suitable for practical use outside the laboratory. The permanent glue application gave a stable connection between the exciter and the specimen, but the generated signal had the lowest amplitude. In the paper, the new procedure dedicated to objective analysis and comparison of the elastic waves propagating on the surface of different specimens was proposed. In this procedure, the genetic algorithms help with the determination of a new coordinate system, in which the assessment of the quality of wave propagation in different directions is possible. [ABSTRACT FROM AUTHOR]

Published

2024

132. A high-performance surface acoustic wave sensing technique.

Author

Wu, Mengmeng, Liu, Xiao, Wang, Renfei, Lin, Xi, and Liu, Yang

Subjects

*ACOUSTIC surface waves, *ACOUSTIC surface wave devices, *SPEED of sound, *RADIO frequency, *ACOUSTIC wave propagation

Abstract

We present a superheterodyne-scheme demodulation system that can detect the amplitude and phase shift of weak radio frequency signals with extraordinarily high stability and resolution. As a demonstration, we introduce a process to measure the velocity of the surface acoustic wave using a delay-line device from 30 K to room temperature, which can resolve <0.1 ppm velocity shift. Furthermore, we investigate the possibility of using this surface acoustic wave device as a calibration-free, high sensitivity, and fast response thermometer. [ABSTRACT FROM AUTHOR]

Published

2024

133. Rotation effects on propagation of shear horizontal surface waves in piezomagnetic-piezoelectric semiconductor layered structures.

Author

Yang, Lei, Zappino, Enrico, Carrera, Erasmo, and Du, Jianke

Subjects

*ROTATIONAL motion, *CENTRIFUGAL force, *ACOUSTIC surface waves, *CORIOLIS force, *CARRIER density, *SEMICONDUCTORS

Abstract

• The influence of rotation on shear horizontal waves in a multiferroic composite semiconductor is studied. • As with semiconductor properties, the rotation will also cause dispersion and attenuation of shear horizontal waves. • Regardless of rotation or non-rotation, waves gain can be achieved by applying a biasing electric field. • Our work identifies several critical inflection points such as wave amplitude from attenuation to gain. • The results can be extended to design the surface acoustic wave gyroscopes and smart devices with composite semiconductor. In this work, the propagation characteristics of shear horizontal waves in a piezomagnetic and piezoelectric semiconductor layered structure with rotation are studied. The dispersion equation of shear horizontal waves in the rotating multiferroic composite semiconductor is obtained in the framework of coupled field theory including Coriolis and centrifugal forces. By solving the dispersion equation in complex domain, the influence of rotation on the shear horizontal waves is deeply analyzed, and the effects of steady-state carrier concentration and biasing electric field in the presence and absence of rotation are obtained, respectively. Similar to the semiconductor properties, the results show that the rotation will also cause dispersion and attenuation of shear horizontal waves. Besides, the wave speed decreases with the increase of the angular rate and the frequency shift occurs. The rotation sensitivity at long wavelengths near the surface is greater than those at short wavelengths deep into the half-space. Importantly, the increase in wave speed and amplitude gain can be achieved by applying an appropriate biasing electric field regardless of rotation or non-rotation. Specially, several critical points such as attenuation from large to small with rotation, wave speed from decrease to increase and wave amplitude from attenuation to gain in the biasing electric field are obtained. The results could be helpful for the design of surface acoustic wave gyroscopes and piezoelectric semiconductor devices related to magnetic fields. [ABSTRACT FROM AUTHOR]

Published

2024

134. Theoretical Study on Horizontal-Type SAW Device with Dual Function of Sensing and Removal of Non-specific Binding.

Author

CHEN, C., WANG, Y., AO, T., and HUI, D. G.

Subjects

*ACOUSTIC surface wave devices, *ACOUSTIC surface waves, *INTERDIGITAL transducers, *RAYLEIGH waves, *WAVE forces

Abstract

In this paper, a horizontal-type surface acoustic wave device based on electrode width control interdigital transducer/polymethylmethacrylate/54° Y --X LiNbO3 is proposed to achieve the removal of non-specific binding particles by Rayleigh waves and the detection of meningococcus by Love waves. It is proved that the surface acoustic wave force plays a leading role in the removal of non-specific binding, and the frequency of the acoustic wave also affects the removal effect. The advantage of electrode width control interdigital transducer lies not only in overcoming the shortcomings of bidirectional and focused interdigital transducers, but also in improving the utilization of acoustic waves and the sensitivity of the sensor. When non-specific binding particles are removed by Rayleigh waves, the Love wave sensor shows a sensitivity of 330 Hz/(ng/l'L) and a detection limit of 50 pg/µL for meningococcus. [ABSTRACT FROM AUTHOR]

Published

2024

135. Surface acoustic wave spectroscopy for non‐destructive coating and bulk characterization at temperatures up to 600°C enabled by piezoelectric aluminum nitride coated sensor.

Author

Makowski, Stefan, Zawischa, Martin, Schneider, Dieter, Barth, Stephan, Schettler, Sebastian, Hoang, Thanh‐Tung, Bartzsch, Hagen, and Zimmermann, Martina

Subjects

*ACOUSTIC surface waves, *ALUMINUM nitride, *MATERIALS science, *SURFACE coatings, *YOUNG'S modulus, *ALUMINUM foil

Abstract

Surface acoustic wave spectroscopy has been established as non‐destructive and fast method for characterization of mechanical properties of surfaces and bulk materials in both research and industry. The present work shows that by application of a novel and robust aluminum nitride (AlN) coated piezoelectric contact sensor the advantages of the method can be extended from room temperature to at least 600°C. An overview of sensor concepts and applications of the method is discussed first, followed by theoretical and practical considerations for design and coating of a novel temperature stable contact sensor. After fabrication of such a sensor using magnetron sputtering, it was tested in a modified surface acoustic wave spectroscopy setup with an incorporated heating table concerning signal amplitude and frequency range. The AlN coated sensor was found to perform well up to 600°C, with temperature limited by the specification of the heating table. At room temperature, performance was acceptable when compared with a conventional contact sensor using a PVDF piezoelectric foil. Application of the high temperature capabilities of the setup was demonstrated by measuring temperature stability of hydrogen‐free amorphous carbon coatings (a‐C and ta‐C) depending on their sp3 carbon ratio. In another example, high precision temperature dependent measurement of Young's modulus for ultrasonic fatigue test specimen was taken, achieving an accuracy better than 1%. Use of the developed sensor opens up new possibilities in material science for in situ study of temperature depending mechanical properties for coatings and surfaces. [ABSTRACT FROM AUTHOR]

Published

2024

136. An Improved Method to Compute the Mutual Capacitance between Interdigital Transducers in Radio Frequency Surface Acoustic Wave Filters.

Author

Zou, Yali, Yang, Xinyu, Luo, Ping, and Liu, Yuhao

Subjects

ACOUSTIC surface waves, INTERDIGITAL transducers, ACOUSTIC filters, ELECTRIC capacity, BOUNDARY element methods

Abstract

This paper proposes an improved method to calculate the mutual capacitance between interdigital transducer (IDT) electrodes to enhance the accuracy of the traditional coupling-of-modes (COM) model, which is commonly used to simulate surface acoustic wave (SAW) filters and duplexers. In this method, the boundary element method (BEM) is adopted to obtain the capacitance per unit length in a layered medium, while the partial capacitance (PC) method is used to derive the effective relative permittivity of the multi-layered IDT. Numerical results from commercially available software are provided for comparison with the results calculated using the proposed method. The consistent results verify the validity and accuracy of this method, which also demonstrates significantly faster calculation speed compared to commercially available software. Precise electrical response prediction of a dual-mode SAW (DMS) filter can be achieved by applying this method to the COM model, and this ultra-fast calculation method can also be included in filter design optimization. [ABSTRACT FROM AUTHOR]

Published

2024

137. Grooving and Absorption on Substrates to Reduce the Bulk Acoustic Wave for Surface Acoustic Wave Micro-Force Sensors.

Author

Feng, Yang, Yu, Haoda, Liu, Wenbo, Hu, Keyong, Sun, Shuifa, Yang, Zhen, and Wang, Ben

Subjects

SURFACE acoustic wave sensors, ACOUSTIC surface waves, MICROSENSORS, ACOUSTICAL materials, SOUND waves, INTERDIGITAL transducers, THEORY of wave motion

Abstract

Improving measurement accuracy is the core issue with surface acoustic wave (SAW) micro-force sensors. An electrode transducer can stimulate not only the SAW but also the bulk acoustic wave (BAW). A portion of the BAW can be picked up by the receiving transducer, leading to an unwanted or spurious signal. This can harm the device's frequency response characteristics, thereby potentially reducing the precision of the micro-force sensor's measurements. This paper examines the influence of anisotropy on wave propagation, and it also performs a phase-matching analysis between interdigital transducers (IDTs) and bulk waves. Two solutions are shown to reduce the influence of BAW for SAW micro sensors, which are arranged with acoustic absorbers at the ends of the substrate and in grooving in the piezoelectric substrate. Three different types of sensors were manufactured, and the test results showed that the sidelobes of the SAW micro-force sensor could be effectively inhibited (3.32 dB), thereby enhancing the sensitivity and performance of sensor detection. The SAW micro-force sensor manufactured using the new process was tested and the following results were obtained: the center frequency was 59.83 MHz, the fractional bandwidth was 1.33%, the range was 0–1000 mN, the linearity was 1.02%, the hysteresis was 0.59%, the repeatability was 1.11%, and the accuracy was 1.34%. [ABSTRACT FROM AUTHOR]

Published

2024

138. Band 40/41 Surface Acoustic Wave Filters on 42°YX-Lithium Tantalate Substrate with Suppression of Transverse Leakage.

Author

Xiao, Qiang, Gao, Zihang, Chu, Mengqun, Zheng, Zeyu, Du, Xuesong, Hu, Chengji, Pan, Hongzhi, Li, Hualin, Dong, Jiahe, Chen, Zhenglin, Chen, Huazhi, Lu, Chuan, Tang, Mi, Fan, Yanping, and Ma, Jinyi

Subjects

ACOUSTIC surface waves, ACOUSTIC filters, BAND saws, INSERTION loss (Telecommunication), LEAKAGE

Abstract

The transverse leakage of leaky surface acoustic waves (LSAWs) occurs on 42°YX-lithium tantalate substrates (42LT), which increases the insertion loss, narrows the bandwidth and flattens the roll-off of band 40/41 SAW filters and duplexers. In this work, LSAW characteristics with different metal materials and thicknesses are calculated by the finite element method (FEM), which determines the IDT material and thickness used for band 40/41 SAW filter design. To deeply understand transverse leakage and suppress it, the effects of different gap and dummy lengths on transverse leakage are simulated and discussed. Then, a new technique of using a wider dummy without any additional lithographic or depositing processes is proposed to suppress the leakage. Its effectiveness is validated by both simulations and experiments. Then, the technique is extended to applications of band 40 and 41 SAW filters. The experimental results show that with the wider dummy structure, the band 40 and 41 SAW filters achieve a more than 0.2 dB improvement in the insertion loss, a wider bandwidth and a steeper roll-off characteristic. This technique may also be extended to the other band SAW filter applications. [ABSTRACT FROM AUTHOR]

Published

2024

139. Wireless Temperature Measurement for Curved Surfaces Based on AlN Surface Acoustic Wave Resonators.

Author

Liu, Huali, Zhou, Zhixin, and Lou, Liang

Subjects

ACOUSTIC surface waves, ACOUSTIC resonators, CURVED surfaces, SURFACE acoustic wave sensors, FREQUENCY division multiple access, FLEXIBLE printed circuits, COPLANAR waveguides

Abstract

In this paper, we propose a novel method for temperature measurement using surface acoustic wave (SAW) temperature sensors on curved or irregular surfaces. We integrate SAW resonators onto flexible printed circuit boards (FPCBs) to ensure better conformity of the temperature sensor with the surface of the object under test. Compared to traditional rigid PCBs, FPCBs offer greater dynamic flexibility, lighter weight, and thinner thickness, which make them an ideal choice for making SAW devices working for temperature measurements under curved surfaces. We design a temperature sensor array consisting of three devices with different operating frequencies to measure the temperature at multiple points on the surface of the object. To distinguish between different target points in the sensor array, each sensor operates at a different frequency, and the operating frequency bands do not overlap. This differentiation is achieved using Frequency Division Multiple Access (FDMA) technology. Experimental results indicate that the frequency temperature coefficients of these sensors are −30.248 ppm/°C, −30.195 ppm/°C, and −30.115 ppm/°C, respectively. In addition, the sensor array enables wireless communication via antenna and transceiver circuits. This innovation heralds enhanced adaptability and applicability for SAW temperature sensor applications. [ABSTRACT FROM AUTHOR]

Published

2024

140. Rational Design of a Surface Acoustic Wave Device for Wearable Body Temperature Monitoring.

Author

Xie, Yudi, Deng, Minglong, Chen, Jinkai, Duan, Yue, Zhang, Jikai, Mu, Danyu, Dong, Shurong, Luo, Jikui, Jin, Hao, and Kakio, Shoji

Subjects

ACOUSTIC surface wave devices, ACOUSTIC surface waves, SOUND design, INTERDIGITAL transducers, SURFACE acoustic wave sensors, COGNITIVE radio

Abstract

Continuous monitoring of vital signs based on advanced sensing technologies has attracted extensive attention due to the ravages of COVID-19. A maintenance-free and low-cost passive wireless sensing system based on surface acoustic wave (SAW) device can be used to continuously monitor temperature. However, the current SAW-based passive sensing system is mostly designed at a low frequency around 433 MHz, which leads to the relatively large size of SAW devices and antenna, hindering their application in wearable devices. In this paper, SAW devices with a resonant frequency distributed in the 870 MHz to 960 MHz range are rationally designed and fabricated. Based on the finite-element method (FEM) and coupling-of-modes (COM) model, the device parameters, including interdigital transducer (IDT) pairs, aperture size, and reflector pairs, are systematically optimized, and the theoretical and experimental results show high consistency. Finally, SAW temperature sensors with a quality factor greater than 2200 are obtained for real-time temperature monitoring ranging from 20 to 50 °C. Benefitting from the higher operating frequency, the size of the sensing system can be reduced for human body temperature monitoring, showing its potential to be used as a wearable monitoring device in the future. [ABSTRACT FROM AUTHOR]

Published

2024

141. Design and Performance Analysis of a High-temperature Sensor with a Low-temperature Coefficient of Frequency.

Author

Nagmani, Aditya Kumar and Behera, Basudeba

Subjects

ACOUSTIC surface waves, SURFACE acoustic wave sensors, HIGH temperatures, FINITE element method, TEMPERATURE sensors, PLATINUM electrodes

Abstract

A surface acoustic wave (SAW)-based temperature sensor has been designed and simulated using a (0°, 138.5°, 26.6°)-cut lanthanum gallium silicate (LGS; langasite; La3Ga5SiO14) substrate with reduced temperature coefficient of frequency (TCF). At elevated temperatures, a slight temperature variation produces a major change in the resonance frequency of the SAW sensors, resulting in crucial accuracy problems and erroneous outcomes. To overcome these issues, a temperature-compensated sensor is required to be designed. Deposition of SiO2 film onto the substrate is an effective approach for achieving temperature compensation in a sensor design. Accordingly, we designed a SAW resonator by depositing platinum electrodes on LGS substrate material along with a layer of SiO2 film on top. The structure has been simulated using the 3-D finite element model method. The temperature-dependent characteristics of the model have been investigated for different thicknesses of the SiO2 coating layer at elevated temperatures. It was found that the TCF is reduced to 4.3 ppm/°C at 500°C operating temperature with a 1.9-μm-thick SiO2 film. A zero TCF was also achieved for 0.9-μm-thick SiO2 film at an operating temperature of 300°C, which signifies the effective temperature compensation of the model. The simulation results also revealed that the SAW velocity increases while the coupling factor (k2) decreases with increasing SiO2 thickness. This sensor can be used for health monitoring in heavy industries as well as in combustion engines to enhance fuel efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

142. Study on the Fabrication and Acoustic Properties of Near-Stoichiometric Lithium Tantalate Crystal Surface Acoustic Wave Filters.

Author

Si, Jiashun, Xiao, Xuefeng, Huang, Yan, Zhang, Yan, Liang, Shuaijie, Xu, Qingyan, Zhang, Huan, Ma, Lingling, Yang, Cui, and Zhang, Xuefeng

Subjects

ACOUSTIC surface waves, ACOUSTIC filters, CRYSTAL surfaces, LITHIUM, ACOUSTIC wave propagation, INSERTION loss (Telecommunication), PHONONIC crystals

Abstract

Near-stoichiometric lithium tantalate (NSLT) wafers with different Li contents were prepared by vapour transfer equilibrium (VTE) method and fabricated into surface acoustic wave filters. The temperature coefficient of frequency, insertion loss, and bandwidth of the surface acoustic wave filters were tested using a special chip test bench and a network analyzer. The results show that the temperature coefficient of frequency shows a trend of first decreasing and then increasing with the increase in Li content, and the temperature stability of the surface acoustic wave filters is best when the Li content is 49.75%. It is also found that the surface acoustic wave filter fabricated from NSLT wafers has 21.18% lower temperature coefficient of frequency, 7.3% lower insertion loss, and 2.8% lower bandwidth than those fabricated from congruent lithium tantalate wafers. Therefore, NSLT crystals are more suitable for applications in acoustic devices, providing a new idea for performance enhancement of 5G communication devices. [ABSTRACT FROM AUTHOR]

Published

2024

143. Giant nonreciprocity of surface acoustic waves induced by an anti-magnetostrictive bilayer.

Author

Hu, Wenbin, Huang, Mingxian, Wu, Yutong, Jia, Yana, Wang, Wen, and Bai, Feiming

Subjects

*ACOUSTIC surface waves, *SPIN waves, *MAGNETIC moments, *ACOUSTIC devices

Abstract

Lack of nonreciprocity is one of the major drawbacks of solid-state acoustic devices, which has hindered the development of microwave-frequency acoustic isolators and circulators. Here, we report a giant nonreciprocal transmission of shear-horizontal surface acoustic waves (SH-SAWs) on a LiTaO3 substrate coated with a negative–positive magnetostrictive bilayer structure of Ni/Ti/FeCoSiB. Although the static magnetic moments of two layers are parallel, SH-SAWs can excite optical-mode spin waves much stronger than acoustic-mode ones at relatively low frequencies via magnetoelastic coupling. The measured magnitude nonreciprocity exceeds 40 dB (or 80 dB/mm) at 2.333 GHz. In addition, maximum nonreciprocal phase accumulation reaches 188° (376 ° / mm), which is desired for an effective SAW circulator. Our theoretical model and calculations provide an insight into the observed phenomena and demonstrate a pathway for further improvement of nonreciprocal acoustic devices. [ABSTRACT FROM AUTHOR]

Published

2024

144. Comparison of aluminum nitride thin films prepared by magnetron sputter epitaxy in nitrogen and ammonia atmosphere.

Author

Sundarapandian, Balasubramanian, Tran, Dat Q., Kirste, Lutz, Straňák, Patrik, Graff, Andreas, Prescher, Mario, Nair, Akash, Raghuwanshi, Mohit, Darakchieva, Vanya, Paskov, Plamen P., and Ambacher, Oliver

Subjects

*ALUMINUM nitride films, *ACOUSTIC surface waves, *SPUTTER deposition, *ATMOSPHERIC nitrogen, *ALUMINUM nitride, *THIN films, *ATMOSPHERIC ammonia, *MAGNETRON sputtering, *THERMAL conductivity

Abstract

Wurtzite-type aluminum nitride (AlN) thin films exhibiting high thermal conductivity, large grain size, and low surface roughness are desired for both bulk acoustic wave and surface acoustic wave resonators. In this work, we use ammonia (NH3) assisted reactive sputter deposition of AlN to significantly improve these properties. The study shows a systematic change in the structural, thermal, and morphological properties of AlN grown in nitrogen (N2) and N2 + NH3 atmosphere. The study demonstrates that NH3 assisted AlN sputtering facilitates 2D growth. In addition, the study presents a growth model relating the 2D growth to improve the mobility of aluminum (Al) and nitrogen (N) ad-atoms in NH3 atmosphere. Consequently, the thermal conductivity and roughness improve by ≈ 76%, and ≈ 35%, while the grain size increases by ≈ 78%. [ABSTRACT FROM AUTHOR]

Published

2024

145. Harnessing a Vibroacoustic Mode for Enabling Smart Functions on Surface Acoustic Wave Devices ‐ Application to Icing Monitoring and Deicing.

Author

Karimzadeh, Atefeh, Weissker, Uhland, del Moral, Jaime, Winkler, Andreas, Borrás, Ana, González‐Elipe, Agustin R., and Jacob, Stefan

Subjects

*ACOUSTIC surface wave devices, *ACOUSTIC surface waves, *ICE prevention & control, *SOUND waves, *ELECTROMECHANICAL devices, *MICROELECTROMECHANICAL systems, *ACOUSTIC wave propagation, *RADIO waves

Abstract

Microacoustic wave devices are essential components in the radio frequency (RF) electronics and microelectromechanical systems (MEMS) industry with increasing impact in various sensing and actuation applications. Reliable and smart operation of acoustic wave devices at low costs will cause a crucial advancement. Herein, this study presents the enablement of temperature and mechanical sensing capabilities in a Rayleigh‐mode standing surface acoustic wave (sSAW) chip device by harnessing an acoustic shear‐thickness dominant wave (SD) using the same set of electrodes. Most importantly, this mode is excited by switching the polarity of the sSAW transducer electrodes by simple electronics, allowing for direct and inexpensive compatibility with an existing setup. The method in the emergent topic of surface de‐icing is validated by continuously monitoring temperature and liquid–solid water phase changes using the SD mode, and on‐demand Rayleigh‐wave deicing with a negligible energy cost. The flexibility for adapting the system to different scenarios, and loads and the potential for scalability opens the path to impact in lab‐on‐a‐chip, internet of things (IoT) technology, and sectors requiring autonomous acoustic wave actuators. [ABSTRACT FROM AUTHOR]

Published

2024

146. Pulsed surface acoustic waves accelerate wound healing and reveal new parameter limits for cell stimulation in vitro.

Author

Baumgartner, Kathrin, Täufer, Paul, Lienhart, Michelle, Lienhart, Rainer, and Westerhausen, Christoph

Subjects

*ACOUSTIC surface waves, *WOUND healing, *MACHINE learning, *DEEP learning, *CELL nuclei, *IMAGE segmentation, *IMAGE analysis

Abstract

The use of surface acoustic waves (SAW) in cell biology has gained high attention in the past years. Previous works show that SAW treatment of artificial wounds in vitro can accelerate wound healing by up to +135%. However, little is known about the mechanobiology behind these effects, and a stimulation has only been proven for continuous SAW signals so far. We here show that the stimulation efficacy observed in previous studies is preserved for pulsed stimuli applied to Madin-Darby canine kidney (MDCK-II) cells in wound healing assays on SAW chips at a resonance frequency f SAW = 160 MHz. Moreover, for a reproducible and reliable image analysis, we present the SegFormer-based deep learning algorithm Neural Cell Edge Detector for the cell edge segmentation and image binarization, that allows an automated determination of the stimulation efficacy. With these tools, we explore a wider range of applicable SAW intensities up to P in = 21 dBm (128 mW) with a maximum stimulation efficacy of E = 201%. We show that the order of magnitude of the stimulation effect is reproducible under the variation of SAW signal characteristics power P in, duty cycle D and pulse width τ, while the mean energy over time is constant. Below a distinct pulse duration limit τ = 100 ms, no direct stimulation effect was observed. From a mechanobiological point of view, these findings and time scales could narrow down the potentially triggered cellular mechanisms during the stimulation. [ABSTRACT FROM AUTHOR]

Published

2024

147. Coherent surface acoustic wave–spin wave interactions detected by micro-focused Brillouin light scattering spectroscopy.

Author

Kunz, Yannik, Küß, Matthias, Schneider, Michael, Geilen, Moritz, Pirro, Philipp, Albrecht, Manfred, and Weiler, Mathias

Subjects

*ACOUSTIC surface waves, *BRILLOUIN scattering, *SPIN waves, *OPTICAL interference, *SPECTROMETRY, *LIGHT scattering

Abstract

We investigated the interaction of surface acoustic waves and spin waves with spatial resolution by micro-focused Brillouin light scattering spectroscopy in a Co40Fe40B20(10 nm) ferromagnetic layer on a LiNbO3-piezoelectric substrate. We experimentally demonstrate that the magnetoelastic excitation of magnons by phonons is coherent by studying the interference of light scattered off generated magnons and annihilated phonons. We find a pronounced spatial dependence of the phonon annihilation and magnon excitation, which we map as a function of the magnetic field. The coupling efficiency of the surface acoustic waves (SAWs) and the spin waves is characterized by a magnetic field-dependent decay of the SAWs amplitude. [ABSTRACT FROM AUTHOR]

Published

2024

148. Anisotropic attenuation of GHz-frequency acoustic phonons and the Grüneisen tensor in MgO crystal.

Author

Akhmedzhanov, F. R., Makharov, N. M., Lomonosov, A. M., and Temnov, V. V.

Subjects

*ACOUSTIC phonons, *ACOUSTIC surface waves, *ANISOTROPIC crystals, *CRYSTALS, *MAGNESIUM oxide, *PHONONIC crystals, *ANISOTROPY

Abstract

We report on measurements of the anisotropy of velocities and attenuation of GHz-frequency acoustic phonons in a cubic MgO crystal at room temperature. They are used to quantify the strong anisotropy of the Grüneisen parameter and calculate the attenuation anisotropy for Rayleigh surface acoustic waves. These observations constitute important building blocks for better understanding of ultrafast laser-based magneto-acoustic and nonlinear acoustic experiments at ultrahigh frequencies. [ABSTRACT FROM AUTHOR]

Published

2024

149. Surface and bulk acoustic wave resonators based on aluminum nitride for bandpass filters.

Author

Zha, Xian-Hu, Luo, Jing-Ting, Tao, Ran, and Fu, Chen

Subjects

ACOUSTIC surface waves, ACOUSTIC resonators, ALUMINUM nitride, BANDPASS filters, PIEZOELECTRIC materials

Abstract

Bandpass filters with high frequency and wide bandwidth are indispensable parts of the fifth-generation telecommunication technologies, and currently, they are mainly based on surface and bulk acoustic wave resonators. Owing to its high mechanical strength, excellent stability at elevated temperatures, good thermal conductivity, and compatibility with complementary metal-oxide-semiconductor technology, aluminum nitride (AlN) becomes the primary piezoelectric material for high-frequency resonators. This review briefly introduces the structures and key performance parameters of the acoustic resonators. The common filter topologies are also discussed. In particular, research progresses in the piezoelectric AlN layer, electrodes, and substrates of the resonators are elaborated. Increasing the electromechanical coupling constant is the main concern for the AlN film. To synthesize AlN in single-crystalline or poly-crystalline with a high intensity of (0002) orientation, and alloy the AlN with other elements are two effective approaches. For the substrates and bottom electrodes, lattice and thermal expansion mismatch, and surface roughness are critical for the synthesis of a high-crystal-quality piezoelectric layer. The electrodes with low electrical resistance, large acoustic-impedance mismatch to the piezoelectric layer, and low density are ideal to reduce insertion loss. Based on the research progress, several possible research directions in the AlN-based filters are suggested at the end of the paper. [ABSTRACT FROM AUTHOR]

Published

2024

150. A Dual-Mode Surface Acoustic Wave Delay Line for the Detection of Ice on 64°-Rotated Y-Cut Lithium Niobate.

Author

Schulmeyer, Philipp, Weihnacht, Manfred, and Schmidt, Hagen

Subjects

*ACOUSTIC surface waves, *LITHIUM niobate, *DELAY lines, *ICE, *ICING (Meteorology), *RAYLEIGH waves

Abstract

Ice accumulation on infrastructure poses severe safety risks and economic losses, necessitating effective detection and monitoring solutions. This study introduces a novel approach employing surface acoustic wave (SAW) sensors, known for their small size, wireless operation, energy self-sufficiency, and retrofit capability. Utilizing a SAW dual-mode delay line device on a 64°-rotated Y-cut lithium niobate substrate, we demonstrate a solution for combined ice detection and temperature measurement. In addition to the shear-horizontal polarized leaky SAW, our findings reveal an electrically excitable Rayleigh-type wave in the X+90° direction on the same cut. Experimental results in a temperature chamber confirm capability for reliable differentiation between liquid water and ice loading and simultaneous temperature measurements. This research presents a promising advancement in addressing safety concerns and economic losses associated with ice accretion. [ABSTRACT FROM AUTHOR]

Published

2024