Your search keyword '"Acoustic surface waves"' showing total 606 results

1. Plasma-enhanced chemical vapor deposition a-SiOCN:H low-Z thin films for bulk acoustic wave resonators.

Author

Berger, Claudio, Schneider, Michael, Pfusterschmied, Georg, and Schmid, Ulrich

Subjects

*PLASMA-enhanced chemical vapor deposition, *ACOUSTIC resonators, *SOUND waves, *THIN films, *ACOUSTIC surface waves, *ACOUSTIC impedance

Abstract

The 5th generation (5G) wireless telecommunication standards with newly defined frequency bands up to 6 GHz are currently established around the world. While outperforming surface acoustic wave (SAW) filters above 1 GHz, bulk acoustic wave (BAW) resonators in multiplexers for radio-frequency front-end (RFFE) modules continuously face higher performance requirements. In contrast to free-standing bulk acoustic resonators (FBARs), solidly mounted resonator (SMR) technology uses an acoustic Bragg mirror, which has already been successfully applied for several GHz applications. In this work, we investigate the potential of amorphous hydrogenated silicon-oxycarbonitride (a-SiOCN:H) thin films synthesized with low-temperature plasma-enhanced chemical vapor deposition (PECVD) as a low acoustic impedance (low-Z) material. Compared to the state-of-the-art where in Bragg mirrors up to now SiO2 is used as standard, the acoustic impedance ratio against the high-Z material tungsten (W) is enhanced for a better device performance. To limit the expected increase in viscous loss when the acoustic impedance is reduced, to a minimum, predominantly the mass density was reduced while keeping the mechanical elasticity high. By doing so, acoustic impedance values as low as 7.1 MRayl were achieved, thereby increasing the impedance ratio of high-Z to low-Z materials from 8:1 up to 14:1. [ABSTRACT FROM AUTHOR]

Published

2024

2. Acoustic wave devices based on piezoelectric/ferroelectric thin films for high-frequency communication systems and sensing applications.

Author

Xue, Yanmei, Liu, Yuan, Zhou, Changjian, and Zhang, Xiu Yin

Subjects

*ACOUSTIC surface waves, *FERROELECTRIC thin films, *SOUND waves, *FERROELECTRIC materials, *ELECTRONIC equipment

Abstract

Surface acoustic wave (SAW) and bulk acoustic wave (BAW) based radio-frequency (RF) filters dominate in handsets markets mainly because they have miniature size so multiple filters can be used but take up very small board area. Besides, due to their inherent advantages, such as low insertion loss, relatively high resonant frequency, and miniature size, their application in the physical and biochemical sensing fields has also gradually expanded. The successful implementation requires specific knowledge of acoustic wave properties, the working mechanisms, material properties, and device design. So, in this review, we survey the SAW and BAW filter technology by discussing the working principles and the comparison between the operation frequency band allocations. In addition, the approaches to enhance the performance including the selection of single crystal/ferroelectric materials for BAW and the structure design optimization for SAW are introduced with discussions for further improvement. Then, flexible SAW and BAW devices are also presented and their new application opportunities in the fields of skin-like electronics and wearable health monitoring devices can be foreseen. Finally, the potential challenges of high frequency, wide bandwidth, miniaturization, and compatibility with the integrated circuits (IC) manufacturing process are overviewed as well. [ABSTRACT FROM AUTHOR]

Published

2024

3. Modulation of Surface Elastic Waves and Surface Acoustic Waves by Acoustic–Elastic Metamaterials.

Author

Fu, Chang and Ma, Tian-Xue

Subjects

ACOUSTIC surface waves, SOUND waves, METAMATERIALS, MICROELECTRONICS, SEWING

Abstract

Metamaterials enable the modulation of elastic waves or acoustic waves in unprecedented ways and have a wide range of potential applications. This paper achieves the simultaneous manipulation of surface elastic waves (SEWs) and surface acoustic waves (SAWs) using two-dimensional acousto-elastic metamaterials (AEMMs). The proposed AEMMs are composed of periodic hollow cylinders on the surface of a semi-infinite substrate. The band diagrams and the frequency responses of the AEMMs are numerically calculated through the finite element approach. The band diagrams exhibit simultaneous bandgaps for the SEWs and SAWs, which can also be effectively tuned by the modification of AEMM geometry. Furthermore, we construct the AEMM waveguide by the introduction of a line defect and hence demonstrate its ability to guide the SEWs and SAWs simultaneously. We expect that the proposed AEMMs will contribute to the development of multi-functional wave devices, such as filters for dual waves in microelectronics or liquid sensors that detect more than one physical property. [ABSTRACT FROM AUTHOR]

Published

2024

4. Movable surface acoustic wave tweezers: a versatile toolbox for micromanipulation.

Author

Qin, Xianming, Liu, Xianglian, Liu, Shuo, Zhang, Chuanyu, Bai, Ningning, Li, Xue, Wang, Weidong, Liu, Dan, Yang, Qiqi, Yang, Ruiguo, Shen, Yajing, and Wei, Xueyong

Subjects

ACOUSTIC surface waves, ACOUSTIC field, DEGREES of freedom, GENETIC translation, SOUND waves

Abstract

Surface acoustic wave (SAW) tweezers are a promising multifunctional micromanipulation method that controls microscale targets via patterned acoustic fields. Owing to their device structure and bonding process, most SAW tweezers have limitations in terms of controlling the position and motion of the acoustic traps, as they generate an acoustic field with a fixed region and adjust the manipulation effects via signal modulation. To address this challenge, we propose movable SAW tweezers with a multilayer structure, achieving dynamic control of their wave field and acoustic trap positions; we demonstrate their precise manipulation functions, such as translation, in-plane rotation, out-of-plane rotation, and cluster formation, on a wide spectrum of samples, including particles, bubbles, droplets, cells, and microorganisms. Our method not only improves the degree of freedom and working range of SAW tweezers but also allows for precise and selective manipulation of microtargets via microtools and localized wavefields. Owing to their flexibility, versatility, and biocompatibility, the movable SAW tweezers can be a practical platform for achieving arbitrary manipulation of microscale targets and have the potential to play significant roles in biomedical microrobotics. [ABSTRACT FROM AUTHOR]

Published

2024

5. Physical Sensors Based on Lamb Wave Resonators.

Author

Yu, Zixia, Yue, Yongqing, Liang, Zhaozhao, Zhao, Xiaolong, Li, Fangpei, Peng, Wenbo, Zhu, Quanzhe, and He, Yongning

Subjects

ACOUSTIC surface waves, LAMB waves, LONGITUDINAL waves, SOUND waves, PIEZOELECTRICITY

Abstract

A Lamb wave is a guided wave that propagates within plate-like structures, with its vibration mode resulting from the coupling of a longitudinal wave and a shear vertical wave, which can be applied in sensors, filters, and frequency control devices. The working principle of Lamb wave sensors relies on the excitation and propagation of this guided wave within piezoelectric material. Lamb wave sensors exhibit significant advantages in various sensing applications due to their unique wave characteristics and design flexibility. Compared to traditional surface acoustic wave (SAW) and bulk acoustic wave (BAW) sensors, Lamb wave sensors can not only achieve higher frequencies and quality factors in smaller dimensions but also exhibit superior integration and multifunctionality. In this paper, we briefly introduce Lamb wave sensors, summarizing methods for enhancing their sensitivity through optimizing electrode configurations and adjusting piezoelectric thin plate structures. Furthermore, this paper systematically explores the development of Lamb wave sensors in various sensing applications and provides new insights into their future development. [ABSTRACT FROM AUTHOR]

Published

2024

6. Numerical study of surface acoustic wave properties in YBa3(PO4)3 single crystal.

Author

Taziev, Rinat M.

Subjects

*ACOUSTIC surface waves, *INTERDIGITAL transducers, *SINGLE crystals, *COUPLING constants, *SOUND waves

Abstract

New piezoelectric crystals are used in all types of devices (sensors, etc.). They can operate at high ambient temperatures. Surface acoustic wave (SAW) technology allows signals from multifunctional sensor elements to be processed together. Orthophosphate YBa3(PO4)3 is a new piezoelectric crystal. It has cubic symmetry. SAW characteristics such as velocity, steering angle and electromechanical coupling constants are simulated for crystal cuts and propagation directions in the YBa3(PO4)3 crystal. It is shown that the SAW has a large electromechanical coupling coefficient (0.17%) on the Z, X+45°–cut of YBa3(PO4)3. For the Z+45°, X –cut of the crystal, the electromechanical coupling coefficient of the SAW is 0.1%. The frequency dependence of the interdigital transducer conductance on both crystal cuts has only the SAW response and no bulk acoustic wave response. For SAW device applications, both crystal cuts are of potential interest. [ABSTRACT FROM AUTHOR]

Published

2024

7. Electron qubits surfing on acoustic waves: review of recent progress.

Author

Wang, Junliang, Edlbauer, Hermann, Jadot, Baptiste, Meunier, Tristan, Takada, Shintaro, Bäuerle, Christopher, and Sellier, Hermann

Subjects

*ACOUSTIC surface waves, *QUANTUM computing, *INTERDIGITAL transducers, *SOUND waves, *QUANTUM communication

Abstract

The displacement of a single electron enables exciting avenues for nanotechnology with vast application potential in quantum metrology, quantum communication and quantum computation. Surface acoustic waves (SAW) have proven itself as a surprisingly useful solution to perform this task over large distance with outstanding precision and reliability. Over the last decade, important milestones have been achieved bringing SAW-driven single-electron transport from first proof-of-principle demonstrations to accurate, highly-controlled implementations, such as coherent spin transport, charge-to-photon conversion, or antibunching of charge states. Beyond the well-established piezoelectric gallium-arsenide platform, first realisations of acousto-electronic transport have also been carried out on the surface of liquid helium that promises unique stability and coherence. In this review article, we aim to keep track of this remarkable progress in SAW-driven transport of electron qubits by explaining these recent achievements from basic principles, with an outlook on follow-up experiments and near-term applications. [ABSTRACT FROM AUTHOR]

Published

2025

8. Maximum Bandwidth Analysis With a Universal AWLR‐Based Filter Structure.

Author

Tang, Xianli, Jia, Yonghao, Yang, Taojun, Hu, Junyuan, and Lu, Wei‐Bing

Subjects

*ACOUSTIC surface waves, *BANDPASS filters, *ACOUSTIC resonators, *SOUND waves, *MICROWAVE filters

Abstract

The bandwidth enhancement of the acoustic‐wave‐lumped‐element resonator (AWLR)‐based filter has been investigated for a long time. However, few researches are focused on the maximum bandwidth analysis. Based on a universal circuit structure of the AWLR‐based filter, we proposed the maximum bandwidth analysis of the hybrid filter. In the analysis process, the universal filter structure can be transformed into a novel AWLR‐based filter structure by incidentally excluding most of the other structures (including the reported hybrid filter structures) under the defined electrical characteristics. The novel hybrid filter obtains the maximum fractional bandwidth (FBW). Moreover, the proposed calculation results are better than the simulation results without artificial intervention. They are 2.12kt2 and 1.63kt2, respectively. kt2 is the electromechanical coupling coefficient of the acoustic wave resonator (AWR). Third‐order AWLR‐based bandpass filters with five‐type circuit structures have been manufactured and measured. They include the proposed novel AWLR‐based filter and the hybrid filter with the reported structure based on the universal AWLR‐based filter structure. The experimental results indicate that the proposed novel AWLR‐based filter has the maximum FBW. [ABSTRACT FROM AUTHOR]

Published

2024

9. A combination of acoustophoresis and thermophoresis for enriching nanoparticles.

Author

Dong, Jing, Liang, Dongfang, Kabla, Alexandre J., Chen, Xinan, and Yang, Xin

Subjects

*ACOUSTIC surface waves, *NATURAL heat convection, *INFRARED lasers, *SOUND waves, *THERMOPHORESIS

Abstract

Over the past few decades, nanotechnology has seen widespread growth in biomedical applications. Recently, thermophoresis has been proposed as an efficient method to manipulate nanoparticles. However, the enrichment time can be quite long due to the associated convection flow. To address this issue, this paper proposes a novel method that combines the deployment of standing surface acoustic waves (SSAW) and temperate gradients for more efficient nanoparticle enrichment. The enrichment system consists of a microchamber sandwiched by a piezoelectrical substrate top slide, from where infrared light laser heat source and SSAW are introduced, and a sapphire bottom. The SSAW-induced thermoacoustic streaming can be properly controlled to partially cancel the effect of natural heat convection, reducing its adverse impact on thermophoresis and consequently reducing the enrichment time. A numerical model is established, which is verified against experimental observation. A parametric study is then undertaken to examine the influence of the acoustic field on the enrichment time with a laser power of 194 mW. The efficiency and suitability of the coupled system depend on the magnitude and direction of SSAW. With the optimized actuation condition, the enrichment time can be reduced by 61% compared to that of the pure thermophoretic enrichment. Finally, different laser powers are considered, ranging from 194 to 248 mW. Again, around 61% time reduction can be achieved in all the tested cases. The optimum magnitude of the acoustic waves slightly increases with the laser power. This innovative enrichment approach is thus demonstrated to be effective. [ABSTRACT FROM AUTHOR]

Published

2024

10. Development of Highly Efficient Lamb Wave Transducers toward Dual-Surface Simultaneous Atomization.

Author

Gai, Chenhui, Ma, Qinghe, Ning, Jia, Ding, Yizhan, Lei, Yulin, Li, Honggeng, Guo, Chunhua, and Hu, Hong

Subjects

*ACOUSTIC surface waves, *ACOUSTIC vibrations, *SOUND waves, *LIQUID films, *ATOMIZATION, *LAMB waves

Abstract

Highly efficient surface acoustic wave (SAW) transducers offer significant advantages for microfluidic atomization. Aiming at highly efficient atomization, we innovatively accomplish dual-surface simultaneous atomization by strategically positioning the liquid supply outside the IDT aperture edge. Initially, we optimize Lamb wave transducers and specifically investigate their performance based on the ratio of substrate thickness to acoustic wavelength. When this ratio h / λ is approximately 1.25, the electromechanical coupling coefficient of A0-mode Lamb waves can reach around 5.5% for 128° Y-X LiNbO3. We then study the mechanism of droplet atomization with the liquid supply positioned outside the IDT aperture edge. Experimental results demonstrate that optimized Lamb wave transducers exhibit clear dual-surface simultaneous atomization. These transducers provide equivalent amplitude acoustic wave vibrations on both surfaces, causing the liquid thin film to accumulate at the edges of the dual-surface and form a continuous mist. [ABSTRACT FROM AUTHOR]

Published

2024

11. A Method for Extracting Acoustic Water Surface Waves Based on Phase Compensation.

Author

Li, Miaomiao, Liang, Xingdong, Zhang, Yuan, Xin, Jihao, Jiang, Nanyi, Guo, Qichang, Wang, Mingming, Wei, Jiashuo, and Bu, Xiangxi

Subjects

*ACOUSTIC surface waves, *BIT error rate, *SOUND waves, *TELECOMMUNICATION, *COMMUNICATION of technical information

Abstract

With the increasing demand for marine biosensing and water–air collaborative rescue in national production and life, establishing a robust cross-medium communication link has become one of the hotspots. Among them, microwave acoustic cross-medium uplink communication technology has been widely studied for its advantages of being able to be used all day and in all weather, there being no need for relay, and having high concealment. The principle is to extract the frequency of the acoustic water surface waves from the phase history of the radar echoes. However, wave interference can cause discontinuity of the phase history, resulting in difficulty in extracting the acoustic water surface waves and an increase in bit error rate (BER). This article analyses the reasons for the discontinuity of phase history and innovatively proposes a method for extracting acoustic water surface waves based on phase compensation. The discontinuity points of the phase history are compensated based on whether the range bin changes. Then, low-frequency water surface fluctuations and discontinuity points are filtered out through second-order differential joint outlier removal, which can effectively reduce the influence of phase history discontinuity on time–frequency analysis and communication decoding. The effectiveness of the proposed method was verified through simulations and experiments. The experimental results indicate that the BER of the proposed method is 25% of that of the Wavelet–Kalman Filtering method. The proposed method provides a new approach for microwave acoustic cross-medium uplink communication. [ABSTRACT FROM AUTHOR]

Published

2024

12. Observation of acoustic meron textures.

Author

Zhou, Nong, Chen, Wan-Na, Sun, Wen-Jun, Sheng, Zong-Qiang, and Wu, Hong-Wei

Subjects

*ACOUSTIC surface waves, *SPEED of sound, *SOUND waves, *ACOUSTIC vibrations, *RAYLEIGH waves, *VECTOR fields, *ACOUSTIC field

Abstract

Merons, as a member of quasiparticle family characterized by half-integer of the skyrmion topological charge with nontrivial topological textures, are of great interest in various branches of physics. Here, we report the first experimental observation of a meron texture configuration in acoustic waves. A squared metastructure is designed to support the spoof acoustic surface wave, forming meron lattice patterns in the acoustic velocity field vectors. The experimental results indicate that the meron textures can be moved and shaped by tuning the phase and amplitude differences between the excited sound sources, respectively. To demonstrate the topologically protected character of meron against structure defects, we further measure the acoustic pressure and velocity field distributions on a defective surface. The acoustic meron texture not only provides potential applications toward topologically robust ways to manipulate vectorial characteristics of the acoustic waves but also instills confidence for exploring other members of the quasiparticle family, such as the acoustic hopfion in acoustic waves. [ABSTRACT FROM AUTHOR]

Published

2024

13. Developments for SAW-based aerosol generation: Miniaturized, cost-efficient, mass-producible, and reproducible systems.

Author

Roudini, Mehrzad, Patel, Bhumika, and Winkler, Andreas

Subjects

*ACOUSTIC surface waves, *AEROSOLS, *LIQUID films, *SOUND waves, *ACOUSTIC field

Abstract

Surface Acoustic Wave (SAW) aerosol generators, also known as SAW nebulizers or SAW atomizers, are gaining widespread interest in a variety of technical processes due to their ability to produce directed fine mist aerosols with a narrow size distribution and at low shear forces. The interaction of a regulated microscale liquid film with an acoustic wave field on a microfluidic chip surface results in SAW aerosol generation. Future real-world applications require on-chip integrated microfluidic channels for low-cost fabrication of acoustofluidic chips with the required high fluid supply accuracy and reproducibility. In this work, SAW aerosol generation chips employing focused and straight IDTs as well as wafer-scale integrated microfluidic fluid feed channels created by a dry film photoresist multi-stage lamination and lithographic patterning technique were fabricated and validated regarding their performance. The manufactured chips were used with a highly-compact, cost-effective, and easy-to-handle chip holder for experimental studies. Using different SAW chips and liquids, atomization working regimens were determined. The aerosol generator achieved operation at flow rates of 10 μL/min and input power levels of 1 W. The implications of SAW wavelength, IDT type, applied power, liquids, and flow rate on device functionality are explored. Using laser diffraction analysis, it is shown that a simple chip-scale platform is capable of achieving a variable droplet size range. The developed SAW aerosol sources are currently the most advanced demonstrated in the literature and can be used in a variety of technical processes, including mass-spectrometry, olfactory displays, and aerosol-based printing. [ABSTRACT FROM AUTHOR]

Published

2024

14. 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

15. 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

16. 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

17. 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

18. 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

19. Piezoelectric acoustic wave characteristics of Pb(In0.5Nb0.5)O3-Pb(Mg1/3Nb2/3)O3-PbTiO3 single crystal substrate: A comparative study with and without SiO2 overlay.

Author

Zhang, Qiaozhen, Du, Rufan, Li, Baichuan, Liu, Huiling, Zhao, Xiangyong, Chen, Ziyun, and Luo, Haosu

Subjects

*SOUND waves, *ACOUSTIC surface waves, *SINGLE crystals, *QUALITY factor, *TRANSDUCERS, *FERROELECTRIC crystals, *ELECTROMECHANICAL effects, *LEAD titanate

Abstract

This paper investigates the excitation and propagation characteristics of a piezoelectric acoustic wave propagating in a rotated Y-cut X-propagating Pb(In0.5Nb0.5)O3-Pb(Mg1/3Nb2/3)O3-PbTiO3 (PIN-PMN-PT) relaxor-based ferroelectric single crystal substrate. Numerical simulations were performed to evaluate the acoustic wave properties by FEM software COMSOL. For comparison, two types of structures are taken into consideration: one is the traditional metal electrode/YX-PIN-PMN-PT and the other is silicon dioxide (SiO2) overlay/metal electrode/YX-PIN-PMN-PT substrate. It is shown that shear-horizontal (SH)-type piezoelectric boundary acoustic waves (PBAW) exist in the SiO2 overlay/metal electrode/YX-PIN-PMN-PT substrate and offer a fairly large electromechanical coupling factor K2 of 30%. Compared to a surface acoustic wave excited in the metal electrode/YX-PIN-PMN-PT substrate, enlarged phase velocity and significantly improved quality factor (∼3500) are simultaneously obtained for SH-type PBAW, which are promising for electromechanical transducer applications with high performance. [ABSTRACT FROM AUTHOR]

Published

2022

20. Acoustohydrodynamic micromixers: Basic mixing principles, programmable mixing prospectives, and biomedical applications.

Author

Bai, Chenhao, Tang, Xiaoqing, Li, Yuyang, Arai, Tatsuo, Huang, Qiang, and Liu, Xiaoming

Subjects

*ACOUSTIC surface waves, *SOUND waves, *RESEARCH personnel

Abstract

Acoustohydrodynamic micromixers offer excellent mixing efficiency, cost-effectiveness, and flexible controllability compared with conventional micromixers. There are two mechanisms in acoustic micromixers: indirect influence by induced streamlines, exemplified by sharp-edge micromixers, and direct influence by acoustic waves, represented by surface acoustic wave micromixers. The former utilizes sharp-edge structures, while the latter employs acoustic wave action to affect both the fluid and its particles. However, traditional micromixers with acoustic bubbles achieve significant mixing performance and numerous programmable mixing platforms provide excellent solutions with wide applicability. This review offers a comprehensive overview of various micromixers, elucidates their underlying principles, and explores their biomedical applications. In addition, advanced programmable micromixing with impressive versatility, convenience, and ability of cross-scale operations is introduced in detail. We believe this review will benefit the researchers in the biomedical field to know the micromixers and find a suitable micromixing method for their various applications. [ABSTRACT FROM AUTHOR]

Published

2024

21. Anomalies in the magnetostrictive modulation of love surface acoustic waves.

Author

Aguilera, J. D., Loriente, R., Soria, L., Begue, A., Ranchal, R., Gràcia, I., Vallejos, S., Hernando, A., Marín, P., Presa, P. de la, and Matatagui, D.

Subjects

*ACOUSTIC surface waves, *MAGNETICS, *DELAY lines, *SOUND waves, *MAGNETIC fields, *THEORY of wave motion

Abstract

A magnetic surface acoustic wave (SAW) sensor is built by growing a 100 nm galfenol (Fe72Ga28) film by sputtering between the interdigitated transducers of a SAW delay line. Love waves are produced when the shear waves excited on the piezoelectric substrate are guided by a 3.1 μm layer of amorphous SiO2. Due to the magnetostrictive nature of galfenol deposited on top, the application of magnetic fields modulates the propagation of the mechanical excitations along the sensor by the strain coupling. By introducing the delay line in a feedback loop circuit, these changes are studied as resonant frequency variations. Magnetic field cycles of ±40 mT are applied to the sample and the resonant frequency shift is tracked simultaneously. The sensor exhibited hysteretic frequency behavior that depends on the orientation of the applied magnetic field relative to the direction of Love wave propagation. In the configuration in which the wave vector and the applied field form an angle of 45°, the resonant frequency seems to increase with the magnetization induced by the external field. When the wave vector propagation is parallel to the field, two positive peaks appear close to the coercive field of the film, which has not been reported before. This is probably due to a more complex relationship between the acoustic wave and the magnetic state of the film which could be exploited to give rise to new models of magnetic sensors. [ABSTRACT FROM AUTHOR]

Published

2024

22. Influence of Homo- and Hetero-Junctions on the Propagation Characteristics of Radially Propagated Cylindrical Surface Acoustic Waves in a Piezoelectric Semiconductor Semi-Infinite Medium.

Author

Guo, Xiao, Wang, Yilin, Xu, Chunyu, Wei, Zibo, and Ding, Chenxi

Subjects

*ACOUSTIC surface waves, *ACOUSTIC wave propagation, *WAVE amplification, *SOUND waves, *SEMICONDUCTORS, *ACOUSTIC resonators, *ELASTIC deformation

Abstract

This paper theoretically investigates the influence of homo- and hetero-junctions on the propagation characteristics of radially propagated cylindrical surface acoustic waves in a piezoelectric semiconductor semi-infinite medium. First, the basic equations of the piezoelectric semiconductor semi-infinite medium are mathematically derived. Then, based on these basic equations and the transfer matrix method, two equivalent mathematical models are established concerning the propagation of radially propagated cylindrical surface acoustic waves in this piezoelectric semiconductor semi-infinite medium. Based on the surface and interface effect theory, the homo- or hetero-junction is theoretically treated as a two-dimensional electrically imperfect interface in the first mathematical model. To legitimately confirm the interface characteristic lengths that appear in the electrically imperfect interface conditions, the homo- or hetero-junction is equivalently treated as a functional gradient thin layer in the second mathematical model. Finally, based on these two mathematical models, the dispersion and attenuation curves of radially propagated cylindrical surface acoustic waves are numerically calculated to discuss the influence of the homo- and hetero-junctions on the dispersion and attenuation characteristics of radially propagated cylindrical surface acoustic waves. The interface characteristic lengths are legitimately confirmed through the comparison of dispersion and attenuation curves calculated using the two equivalent mathematical models. As piezoelectric semiconductor energy harvesters usually work under elastic deformation, the establishment of mathematical models and the revelation of physical mechanisms are both fundamental to the analysis and optimization of micro-scale surface acoustic wave resonators, energy harvesters, and acoustic wave amplification based on the propagation of surface acoustic waves. [ABSTRACT FROM AUTHOR]

Published

2024

23. SH-BAW devices with abnormal mass-loading effect for chemical sensing.

Author

Shen, Junjie, Chen, Haibo, Shi, Zimeng, Kong, Linghui, Zhang, Yunjing, Li, Lingfeng, Li, Peng, and He, Xingli

Subjects

*ACOUSTIC surface waves, *SURFACE acoustic wave sensors, *DELAY lines, *FINITE element method, *SOUND waves

Abstract

Surface acoustic wave (SAW) devices are promising for chemical and biological sensing applications. This work studies the basic operating principles and the physical behaviors of the "Rayleigh"-SAW and the "Shear Horizontal (SH-)" bulk acoustic wave (BAW), particularly in relation to the chemisorption process. A complete 3D delay line SAW model is developed and performed by the finite element analysis, and a methodology was introduced for characterizing the transmission characteristics (S21) of these devices. Notably, our investigation unveils an intriguing phenomenon in the behavior of SH-BAW in response to loading mass. We observed an anomalous shift in the central frequency, which increases as the chemical adsorbate concentration rises. Leveraging these insights, we designed and constructed a SAW-based gas sensor, and the vinyl-terminated polydimethylsiloxane was synthesized for the detection of chloroform, a challenging pollutant to identify. Through a comparative study, we illustrate distinct responses of Rayleigh-SAW and SH-BAW devices to accumulated loading mass and gaseous contaminants. These experimental results validate and corroborate our simulations. This work demonstrates a unique mass-loading effect exhibited by SH-BAW devices, which differs from the existing theories. These findings offer the opportunity to refine and enhance models for accurately describing the functionality of delay line SAW sensors, thereby contributing to improved sensor reliability. [ABSTRACT FROM AUTHOR]

Published

2023

24. Symmetry and Nonlinearity of Spin Wave Resonance Excited by Focused Surface Acoustic Waves.

Author

Shah, Piyush J., Bas, Derek A., Hamadeh, Abbass, Wolf, Michael, Franson, Andrew, Newburger, Michael, Pirro, Philipp, Weiler, Mathias, and Page, Michael R.

Subjects

ACOUSTIC surface waves, SPIN waves, SOUND waves, WAVES (Physics), RESONANCE, SYMMETRY

Abstract

The use of a complex ferromagnetic system to manipulate GHz surface acoustic waves (SAWs) is a rich current topic under investigation, but the high‐power nonlinear regime is under‐explored. Focused SAWs are introduced, which provide a way to access this regime with modest equipment. The symmetry of the magneto‐acoustic interaction can be tuned by interdigitated transducer design which can introduce additional strain components. Here, the impact of focused acoustic waves versus standard unidirectional acoustic waves in significantly enhancing the magnon‐phonon coupling behavior is compared. Analytical simulation results based on the modified Landau–Lifshitz–Gilbert theory show good agreement with experimental findings. Nonlinear input power dependence of the transmission through the device is also reported. This experimental observation is supported by the micromagnetic simulation using mumax3 to model the nonlinear dependence. These results pave the way for extending the understanding and design of acoustic wave devices for the exploration of acoustically driven spin wave resonance physics. [ABSTRACT FROM AUTHOR]

Published

2023

25. Acousto-optical coupling in two-dimensional air-slot phoxonic crystal heterostructure cavity.

Author

MA ZHEN-MENG, TIAN MIAO, ZHANG LEI, and GAO PEI-FENG

Subjects

*ACOUSTIC surface waves, *SUBSTRATE integrated waveguides, *QUANTUM computing, *SOUND waves, *CRYSTALS, *OPTICAL communications

Abstract

Phoxonic crystal is a periodic artificial structure that can manipulate optical and acoustic waves in the same temporal and spatial domain. It has broad application prospect in optical communication, optical mechanics sensor, quantum computations, phoxonic crystal integrated devices and so on. In this paper, we adopt a silicon-based two-dimensional square lattice structure, which can exhibit wide band gap of phonons and photons simultaneously. Then a periodic rectangular structure is introduced on the surface, the effects of the height and width of the rectangle on the optical and acoustic surface wave modes are analyzed. Based on the mode gap effect, a surface heterostructure composed of rectangles with different heights and widths is constructed. Then two identical surface heterostructures are placed face to face with an air slot in the middle, and connected with silicon substrate on both sides, which form an air slot heterostructure cavity. Five phononic cavity modes and three photonic cavity modes are obtained, the acousto-optical coupling rates between phononic and photonic cavity modes are calculated. The results show that the coupling rate between phononic and photonic cavity mode with the same symmetry and maximum overlap is the largest, and the coupling rates between the combination of phononic cavity modes α and β and photonic cavity modes can be adjusted by changing the phase difference φ of modes α and β. In this paper, the finite element method is used to simulate the calculation. [ABSTRACT FROM AUTHOR]

Published

2023

26. Analysis of Radiation Absorption of Acoustic Lamb Waves in Plates Loaded with Inviscid Nonconducting Liquid.

Author

Ageikin, N. A., Anisimkin, V. I., Voronova, N. V., and Smirnov, A. V.

Subjects

ABSORPTION of sound, ACOUSTIC radiation, RADIATION absorption, ACOUSTIC surface waves, LAMB waves, SOUND waves

Abstract

The dependence of radiation losses in a liquid on the value of displacement component U3 normal to the plate on the surface of a piezoelectric plate for Lamb waves of various orders has been experimentally investigated. The waves whose phase velocity Vn in the plate is greater than velocity Vl of the longitudinal volumetric acoustic wave in the liquid are considered. It is shown that at low values of U3, there is no radiation into the liquid and the value of radiation losses is close to zero even at Vn > Vl, at high values of U3, the value of radiation losses is large and for Lamb waves in the YZ–LiNbO3 plate with a normalized wavelength thickness of 1.75 and a frequency of 16.97 MHz, it reaches a value of 4 dB/mm, comparable to the radiation losses of surface acoustic waves in the same material. [ABSTRACT FROM AUTHOR]

Published

2023

27. Evanescent surface acoustic waves in 1D viscoelastic phononic crystals.

Author

Zhang, Shu-Yan, Wang, Yan-Feng, and Wang, Yue-Sheng

Subjects

*ACOUSTIC surface waves, *PHONONIC crystals, *FINITE element method, *SOUND waves, *CRYSTAL surfaces

Abstract

In this paper, evanescent surface waves propagating in a one-dimensional surface phononic crystal are investigated. The phononic crystal consists of elastic pillars periodically arranged on a viscoelastic substrate. By using the finite element method, the complex band structures and transmission spectra of surface waves are calculated. It is found that the evanescent wave with π phase change of the real part lies inside the resonant bandgap, and no cusp is observed for the minimum imaginary part. With the increase of frequency, the surface waves can be gradually converted to bulk waves. When the pillar height is increased, the generation mechanism of the first bandgap gradually varies from Bragg scattering to local resonance, and the evanescent waves above the sound line can be reconstructed and shifted below the sound line. When the viscosity is introduced, the minimum imaginary part inside the bandgap decreases. However, the corresponding attenuation is strengthened because the contribution of the bulk wave to the transmission gets weak. The work in this paper is relevant to the practical application of surface waves. [ABSTRACT FROM AUTHOR]

Published

2021

28. Acoustoelectric drag current in vanadium oxide films.

Author

Lapa, Pavel N., Kassabian, George, Torres, Felipe, Salev, Pavel, Lee, Min-Han, del Valle, Javier, and Schuller, Ivan K.

Subjects

*VANADIUM oxide, *OXIDE coating, *ACOUSTIC surface waves, *ACOUSTIC wave propagation, *HALL effect, *SOUND waves

Abstract

Two different Mott insulator wires, vanadium dioxide and vanadium sesquioxide, were prepared on the piezoelectric LiNbO3 substrates. Coupling of acoustic waves propagating in LiNbO3 with free carriers in vanadium oxide gives rise to the acoustoelectric effect that manifests itself as the generation of direct electric current by the acoustic wave. According to a phenomenological model, the value of the effect strongly depends on the wires conductivity, which, for the vanadium-oxide films, changes by a few orders of magnitude. We demonstrated that this yields a significant enhancement of the direct current (DC) current generated in the wires at the metal–insulator transition temperatures. The sign of the generated DC voltage is different for excitations by surface and bulk acoustic wave modes, which may happen due to reverse wave propagation at the substrate surface. For each resonance mode, polarities of the generated DC signal are the same in both wires, despite the signs of charge carriers being different for these materials. It was shown that two complementary techniques (acoustoelectric and Hall effect measurements) yield opposite signs of charge carriers in VO2. [ABSTRACT FROM AUTHOR]

Published

2020

29. Formation of binary magnon polaron in a two-dimensional artificial magneto-elastic crystal.

Author

Majumder, Sudip, Drobitch, J. L., Bandyopadhyay, Supriyo, and Barman, Anjan

Subjects

MAGNONS, POLARONS, ACOUSTIC surface waves, SPIN waves, SOUND waves, ROTATIONAL symmetry, CRYSTALS

Abstract

We observed strong tripartite magnon-phonon-magnon coupling in a two-dimensional periodic array of magnetostrictive nanomagnets deposited on a piezoelectric substrate, forming a 2D magnetoelastic "crystal"; the coupling occurred between two Kittel-type spin wave (magnon) modes and a (non-Kittel) magnetoelastic spin wave mode caused by a surface acoustic wave (SAW) (phonons). The strongest coupling occurred when the frequencies and wavevectors of the three modes matched, leading to perfect phase matching. We achieved this condition by carefully engineering the frequency of the SAW, the nanomagnet dimensions and the bias magnetic field that determined the frequencies of the two Kittel-type modes. The strong coupling (cooperativity factor exceeding unity) led to the formation of a new quasi-particle, called a binary magnon-polaron, accompanied by nearly complete (~100%) transfer of energy from the magnetoelastic mode to the two Kittel-type modes. This coupling phenomenon exhibited significant anisotropy since the array did not have rotational symmetry in space. The experimental observations were in good agreement with the theoretical simulations. Unmasking Binary Magnon-Polaron: A New Quasi-Particle This article reveals a study on magnon-phonon coupling in two-dimensional artificial magneto-elastic crystals. Researchers fabricated a 2D periodic array of magnetostrictive nanomagnets on a piezoelectric substrate and observed strong tripartite coupling involving two magnons and a phonon. This coupling transfers all or nearly all of the power from a magneto-elastic mode caused by surface acoustic waves (SAWs) to two Kittel-type spin wave modes. The findings highlight the importance of engineering SAW frequency, magnetic field, and nanomagnet dimensions to ensure near-perfect phase matching between all modes. This discovery could pave the way for future developments in energy-efficient computing, communications, and data storage. A two-dimensional array of magnetostrictive nanomagnets was used to demonstrate strong coupling between two different magnons (kM1′ and kM1′′) mediated by a phonon (kph). The coupling is strong, leading to the formation of a new quasi-particle – binary magnon-polaron. These two different magnons show 180° phase difference which is reminiscent of dark magnon modes. We show that it is possible to engineer this magnon-phonon coupling by choosing the frequency and wavelength of the acoustic wave to match the frequency and wavelength of the spin wave, the latter being controlled by a magnetic field. [ABSTRACT FROM AUTHOR]

Published

2023

30. Surface Acoustic Wave Immunosensor for Detection of Botulinum Neurotoxin.

Author

Grabka, Michał, Jasek, Krzysztof, and Witkiewicz, Zygfryd

Subjects

*ACOUSTIC surface waves, *BOTULINUM A toxins, *BOTULINUM toxin, *SOUND waves, *BIOLOGICAL weapons, *MONOCLONAL antibodies

Abstract

A Love-type acoustic wave sensor (AT-cut quartz substrate, SiO2 guiding layer) with a center frequency of approximately 120 MHz was used to detect a simulant of pathogenic botulinum neurotoxin type A—recombinant of BoNT-A light chain—in liquid samples. The sensor was prepared by immobilizing monoclonal antibodies specific for botulinum neurotoxin via a thiol monolayer deposited on a gold substrate. Studies have shown that the sensor enables selective analyte detection within a few minutes. In addition, the sensor can be used several times (regeneration of the sensor is possible using a low pH buffer). Nevertheless, the detectability of the analyte is relatively low compared to other analytical techniques that can be used for rapid detection of botulinum neurotoxin. The obtained results confirm the operation of the proposed sensor and give hope for further development of this label-free technique for detecting botulinum neurotoxin. [ABSTRACT FROM AUTHOR]

Published

2023

31. Estimation of Characteristics of Nanocrystalline Layer Using the Surface Acoustic Waves.

Author

Skalskyi, V. R., Mokryi, O. M., Zvirko, O. I., Kyryliv, V. I., Romanyshyn, I. M., and Maksymiv, O. V.

Subjects

*ACOUSTIC surface waves, *SPEED of sound, *SOUND waves, *ACOUSTIC wave propagation

Abstract

The effect of the nanocrystalline layer formed by mechanical pulse treatment on the velocity of surface acoustic waves in 65G steel samples was studied. Acoustic waves with frequencies equal to 3; 6 and 9 MHz were used. Different thicknesses of the nanocrystalline layer were obtained by the stepwise grinding method. The method of estimating the acoustic properties of the formed layer based on the velocity of surface acoustic waves in the case when the depth of wave penetration is greater than its thickness was described. An additional measurement of the nanocrystalline layer thickness was carried out using metallographic studies to determine its acoustic characteristics. [ABSTRACT FROM AUTHOR]

Published

2023

32. Surface Acoustic Wave-Based Microfluidic Device for Microparticles Manipulation: Effects of Microchannel Elasticity on the Device Performance.

Author

Mezzanzanica, Gianluca, Français, Olivier, and Mariani, Stefano

Subjects

ACOUSTIC surface waves, MICROFLUIDIC devices, ELASTICITY, SOUND waves, SHEAR waves, FINITE element method

Abstract

Size sorting, line focusing, and isolation of microparticles or cells are fundamental ingredients in the improvement of disease diagnostic tools adopted in biology and biomedicine. Microfluidic devices are exploited as a solution to transport and manipulate (bio)particles via a liquid flow. Use of acoustic waves traveling through the fluid provides non-contact solutions to the handling goal, by exploiting the acoustophoretic phenomenon. In this paper, a finite element model of a microfluidic surface acoustic wave-based device for the manipulation of microparticles is reported. Counter-propagating waves are designed to interfere inside a PDMS microchannel and generate a standing surface acoustic wave which is transmitted to the fluid as a standing pressure field. A model of the cross-section of the device is considered to perform a sensitivity analysis of such a standing pressure field to uncertainties related to the geometry of the microchannel, especially in terms of thickness and width of the fluid domain. To also assess the effects caused by possible secondary waves traveling in the microchannel, the PDMS is modeled as an elastic solid material. Remarkable effects and possible issues in microparticle actuation, as related to the size of the microchannel, are discussed by way of exemplary results. [ABSTRACT FROM AUTHOR]

Published

2023

33. Tunable acoustic resonances: From weak to strong coupling regime.

Author

Günay, Mehmet, Biçer, Ahmet, Korozlu, Nurettin, and Cicek, Ahmet

Subjects

*ACOUSTIC resonance, *ACOUSTIC surface waves, *ACOUSTIC resonators, *OSCILLATIONS, *FANO resonance, *FINITE element method, *RABI oscillations, *HYBRID systems, *SOUND waves

Abstract

Tunable interaction strength between a side-coupled ring resonator and an acoustic waveguide structure is demonstrated. Fano resonances in the weak coupling regime are observed from the interference between a discrete state of the ring resonator and a continuum state of the waveguide. As the distance between the two structures is decreased, a transition from weak to strong coupling regime is obtained, where we observe splitting in the transmission spectrum and Rabi oscillations in the temporal behavior for smaller values. The findings of the finite-element method simulations are supported with the results obtained from a simple theoretical model in which one can explain the dynamics of the hybrid modes. The results can contribute to device applications in acoustic sensors, switches, and surface acoustic wave integrated circuits. [ABSTRACT FROM AUTHOR]

Published

2023

34. Controlling sound waves in gradient spoof-fluid-spoof waveguides.

Author

Dong, Daxing, Li, Weimian, Li, Xiao, Liu, Jiaqing, Liu, Youwen, Ji, Hongli, Xu, Yadong, and Fu, Yangyang

Subjects

*ACOUSTIC surface waves, *ACOUSTIC waveguides, *WAVEGUIDES, *ACOUSTIC wave propagation, *SURFACE waves (Seismic waves), *FANO resonance, *SOUND waves, *BOUND states

Abstract

In this work, we theoretically and experimentally demonstrate that effective trapping, guiding, and manipulation of sound waves can be realized in spoof-fluid-spoof acoustic waveguides with gradient index modulation. Empowered by the abundant mode evolution physics between propagation waves and spoof acoustic surface waves in the gradient waveguide structure, various functional sound propagation phenomena, including broadband transmission, broadband reflection, Fabry–Pérot resonances, and Fano resonances, are unveiled. The underlying principle stems from the interplay of various mechanisms composed of gradient mode conversion, high-order mode resonances, and symmetry-protected bound states in the continuum. These effects can be effectively modulated through the manipulation of the fluid gap and doped defects within the waveguide structure. Our findings can offer possibilities for manipulating sound waves in a versatile manner and holding significant potential for various acoustic applications such as sensing, filtering, insulation, and wavefront engineering. [ABSTRACT FROM AUTHOR]

Published

2023

35. Anisotropy of the Near‐Field Coseismic Ionospheric Perturbation Amplitudes Reflecting the Source Process: The 2023 February Turkey Earthquakes.

Author

Bagiya, Mala S., Heki, K., and Gahalaut, Vineet K.

Subjects

*EARTHQUAKES, *ACOUSTIC surface waves, *SOUND waves, *ELECTRON density, *ELECTRON distribution, *GLOBAL Positioning System, *ANISOTROPY

Abstract

The East Anatolian Fault in southern Turkey ruptured on 6 February 2023, causing a Mw 7.8 earthquake (EQ1), one of the largest strike‐slip events recorded on land. ∼9 hr later, earthquake of Mw 7.7 (EQ2) occurred to the north of EQ1. We investigate here near‐field coseismic ionospheric perturbations (CIP) caused by acoustic waves (AWs) excited by coseismic vertical crustal movements. We find that observed CIP periods were somewhat longer for EQ1 than EQ2. EQ1 also showed azimuthal dependence in CIP amplitudes that cannot be explained by known factors such as geomagnetism and line‐of‐sight geometry. Numerical experiments revealed that CIP by EQ1 can be well reproduced by assuming a suite of sources along the fault that successively ruptured. Small but significant dependence of amplitudes and periods on azimuths were caused by interference of AWs from multiple sources. We also found that CIP amplitudes of strike‐slip earthquakes tend to be lower than dip‐slip earthquakes. Plain Language Summary: Fault dislocations in earthquakes cause vertical movement of the surface and excite acoustic waves (AWs) in the overlying atmosphere which propagate upward with increasing amplitudes. Such waves reach the ionosphere and disturb electron density distribution there, causing disturbances in numbers of electrons along the line‐of‐sights connecting ground GNSS receivers and satellites. So far, such near‐field co‐seismic ionospheric perturbations are modeled by assuming single acoustic pulse from the surface, although large earthquakes often involve ruptures of multiple fault segments spanning hundreds of kilometers. Here we demonstrate that interference of AWs from these multiple sources makes differences in the perturbations amplitudes and periods at GNSS stations in different azimuths from the epicenter. Key Points: Mw 7.8 and Mw 7.7 February 2023 Turkey earthquakes produced typical ionospheric perturbationsFor the first earthquake, we found small but significant difference in the perturbation amplitudes that cannot be explained by known factorsBy assuming multiple sources along the fault and interference of acoustic waves from them, we can explain the observed azimuthal asymmetry [ABSTRACT FROM AUTHOR]

Published

2023

36. Acoustofluidics: A Versatile Tool for Micro/Nano Separation at the Cellular, Subcellular, and Biomolecular Levels.

Author

Zhao, Zhuyang, Yang, Sha, Feng, Liu, Zhang, Ligai, Wang, Jue, Chang, Kai, and Chen, Ming

Subjects

*MICROFLUIDICS, *ACOUSTIC surface waves, *INTERDIGITAL transducers, *NANOPARTICLES, *SOUND waves

Abstract

Separation of micro/nanoparticles, such as cellular, subcellular and biomolecular, has attracted increasing attention because of their remarkable potential applications in various fields, including chemistry, physics, medicine, etc. Among different micro/nanoparticle separation methods, acoustofluidics, which combines acoustics and microfluidics, has drawn the interest of researchers due to its biocompatibility, high efficiency and free labeling. In this review, the basic constitutions, mechanisms, and materials of acoustofluidics are described. Subsequently, sorts of delicately designed acoustofluidic devices, including diverse bulk acoustic wave (BAW) microfluidics and surface acoustic wave (SAW) microfluidics, are discussed, covering principles, advantages, limitations and applications in separation. Besides the introduction of advances of micro/nanoparticle separation in the BAW microfluidics, the SAW microfluidics are elaborated in detail with a focus on various configurations of interdigital transducers (IDTs), comprising straight IDT, slanted‐finger IDT, chirped IDT and focused IDT. Microfluidic systems of the acoustofluidics involve the forms of straight channels, serpentine channels, and droplets. Additionally, besides simply structured acoustofluidics, acoustofluidics integrated with other structures are also mentioned. Finally, the prospects and limitations of acoustofluidics in micro/nanoparticle separation are also discussed. The acoustofluidics reviewed here is envisioned as a versatile tool for micro/nanoparticle separation at the cellular, sub‐cellular, and biomolecular levels. [ABSTRACT FROM AUTHOR]

Published

2023

37. Singular Value Decomposition of the Wave Forward Operator with Radial Variable Coefficients.

Author

Minam Moon, Injo Hur, and Sunghwan Moon

Subjects

ACOUSTIC surface waves, ORTHONORMAL basis, ELECTROMAGNETIC waves, SOUND waves, ACOUSTIC transducers, SINGULAR value decomposition

Abstract

Photoacoustic tomography (PAT) is a novel and promising technology in hybrid medical imaging that involves generating acoustic waves in the object of interest by stimulating electromagnetic energy. The acoustic wave is measured outside the object. One of the key mathematical problems in PAT is the reconstruction of the initial function that contains diagnostic information from the solution of the wave equation on the surface of the acoustic transducers. Herein, we propose a wave forward operator that assigns an initial function to obtain the solution of the wave equation on a unit sphere. Under the assumption of the radial variable speed of ultrasound, we obtain the singular value decomposition of this wave forward operator by determining the orthonormal basis of a certain Hilbert space comprising eigenfunctions. In addition, numerical simulation results obtained using the continuous Galerkin method are utilized to validate the inversion resulting from the singular value decomposition. [ABSTRACT FROM AUTHOR]

Published

2023

38. Asymmetrically aligned focused acoustic waves for enhancing sensing performance of electrochemical microarrays.

Author

Zheng, Tengfei, Liu, Yue, Fu, Yongqing, and Wang, Chaohui

Subjects

*SOUND waves, *ACOUSTIC surface waves, *ACOUSTIC streaming, *SPEED of sound, *ELECTROCHEMICAL sensors, *ACOUSTIC wave propagation

Abstract

Microelectrode-based electrochemical detection methods have been extensively applied in microfluidic sensors, but there are significant challenges for achieving fast and efficient contact between analytes and the microarray electrodes and, thus, enhancing the sensing performance. In this paper, we develop a technique using asymmetrically aligned focused surface acoustic waves (FSAWs) to enhance sensitivity of microarray electrodes detection. Effects of various focusing angles of the FSAW devices on the values and distributions of acoustic wave amplitudes were analyzed using finite element simulations, and torques, which determine the acoustic streaming velocity, were calculated as a function of values and distributions of amplitude. Based on simulation results, the FSAW device with a focusing angle of 30° was used to investigate sensitivity of microarray electrochemical sensors. The maximum value of instantaneous current was increased up to 11 times, researching a current value of 4.3 μA with the applied FSAWs. This developed electrochemical sensing platform shows great potentials for highly sensitive food quality control and biochemical detections. [ABSTRACT FROM AUTHOR]

Published

2023

39. Acoustomicrofluidic Defect Engineering and Ligand Exchange in ZIF‐8 Metal–Organic Frameworks.

Author

Massahud, Emily, Ahmed, Heba, Babarao, Ravichandar, Ehrnst, Yemima, Alijani, Hossein, Darmanin, Connie, Murdoch, Billy J., Rezk, Amgad R., and Yeo, Leslie Y.

Subjects

*METAL-organic frameworks, *ACOUSTIC surface waves, *LIQUID crystals, *CRYSTAL defects, *ACOUSTIC radiation

Abstract

A way through which the properties of metal–organic frameworks (MOFs) can be tuned is by engineering defects into the crystal structure. Given its intrinsic stability and rigidity, however, it is difficult to introduce defects into zeolitic imidazolate frameworks (ZIFs)—and ZIF‐8, in particular—without compromising crystal integrity. In this work, it is shown that the acoustic radiation pressure as well as the hydrodynamic stresses arising from the oscillatory flow generated by coupling high frequency (MHz‐order) hybrid surface and bulk acoustic waves into a suspension of ZIF‐8 crystals in a liquid pressure transmitting medium is capable of driving permanent structural changes in their crystal lattice structure. Over time, the enhancement in the diffusive transport of guest molecules into the material's pores as a consequence is shown to lead to expansion of the pore framework, and subsequently, the creation of dangling‐linker and missing‐linker defects, therefore offering the possibility of tuning the type and extent of defects engineered into the MOF through the acoustic exposure time. Additionally, the practical utility of the technology is demonstrated for one‐pot, simultaneous solvent‐assisted ligand exchange under ambient conditions, for sub‐micron‐dimension ZIF‐8 crystals and relatively large ligands—more specifically 2‐aminobenzimidazole—without compromising the framework porosity or overall crystal structure. [ABSTRACT FROM AUTHOR]

Published

2023

40. The generation of large-amplitude surface acoustic waves induced by a moving laser source.

Author

Li, Zheng, Su, Dashuai, and Sun, Xiaofeng

Subjects

*ACOUSTIC surface waves, *SPEED of sound, *RAYLEIGH waves, *LASERS, *SOUND waves

Abstract

This letter focuses on the non-contact generation of surface acoustic waves by using a continuous wave laser moving along the sample surface. The desired large-amplitude surface acoustic waves can be generated efficiently if the laser moving speed matches the Rayleigh value, which is a typical characteristic of the continuous laser moving excitation method. The different amplitudes of surface acoustic waves were generated at different laser moving speeds, and the largest amplitude occurred when the laser moving speed approached the surface acoustic wave velocity of the material. Subsequently, the influence of laser moving distance on the wave's amplitude under Rayleigh resonance conditions was investigated. The surface acoustic waves' amplitude grew linearly with the laser's moving distance in the elastic range. In brief, this paper provides a novel method to excite large amplitude surface acoustic waves by simply changing the moving speed and moving distance of the light. [ABSTRACT FROM AUTHOR]

Published

2023

41. Sonoprinting nanoparticles on cellular spheroids via surface acoustic waves for enhanced nanotherapeutics delivery.

Author

Rasouli, Reza, Paun, Radu Alexandru, and Tabrizian, Maryam

Subjects

*ACOUSTIC surface waves, *NANOCARRIERS, *ACOUSTIC streaming, *ELECTROPORATION therapy, *SOUND waves, *NANOPARTICLES, *CELL survival

Abstract

Nanotherapeutics, on their path to the target tissues, face numerous physicochemical hindrances that affect their therapeutic efficacy. Physical barriers become more pronounced in pathological tissues, such as solid tumors, where they limit the penetration of nanocarriers into deeper regions, thereby preventing the efficient delivery of drug cargo. To address this challenge, we introduce a novel approach that employs surface acoustic wave (SAW) technology to sonoprint and enhance the delivery of nanoparticles onto and into cell spheroids. Our SAW platform is designed to generate focused and unidirectional acoustic waves for creating vigorous acoustic streaming while promoting Bjerknes forces. The effect of SAW excitation on cell viability, as well as the accumulation and penetration of nanoparticles on human breast cancer (MCF 7) and mouse melanoma (YUMM 1.7) cell spheroids were investigated. The high frequency, low input voltage, and contact-free nature of the proposed SAW system ensured over 92% cell viability for both cell lines after SAW exposure. SAW sonoprinting enhanced the accumulation of 100 nm polystyrene particles on the periphery of the spheroids to near four-fold, while the penetration of nanoparticles into the core regions of the spheroids was improved up to three times. To demonstrate the effectiveness of our SAW platform on the efficacy of nanotherapeutics, the platform was used to deliver nanoliposomes encapsulated with the anti-cancer metal compound copper diethyldithiocarbamate (CuET) to MCF 7 and YUMM 1.7 cell spheroids. A three-fold increase in the cytotoxic activity of the drug was observed in spheroids under the effect of SAW, compared to controls. The capacity of SAW-based devices to be manufactured as minuscule wearable patches can offer highly controllable, localized, and continuous acoustic waves to enhance drug delivery efficiency to target tissues. [ABSTRACT FROM AUTHOR]

Published

2023

42. On‐Chip Tightly Confined Guiding and Splitting of Surface Acoustic Waves Using Line Defects in Phononic Crystals.

Author

Gao, Feng, Benchabane, Sarah, Bermak, Amine, Dong, Shurong, and Khelif, Abdelkrim

Subjects

*ACOUSTIC surface waves, *PHONONIC crystals, *CRYSTAL defects, *LATTICE constants, *SOUND waves

Abstract

Phononic crystals (PnCs) exhibit acoustic properties that are not usually found in natural materials, which leads to the possibility of new devices for the complex manipulation of acoustic waves. In this article, a micron‐scale phononic waveguide constructed by line defects in PnCs to achieve on‐chip, tightly confined guiding, bending, and splitting of surface acoustic waves (SAWs) is reported. The PnC is made of a square lattice of periodic nickel pillars on a piezoelectric substrate. The PnC lattice constant, pillar diameter, and pillar height are set to 10, 7.5, and 3.2 µm, respectively, leading to a complete bandgap centered at 195 MHz. Interdigitated transducers are monolithically integrated on the same substrate for SAW excitation. The guiding, bending, and splitting of SAWs in the phononic waveguide are experimentally observed through measurement of the out‐of‐plane displacement fields using a scanning optical interferometer. The combination of destructive interference due to the Bragg bandgap and the interaction of the propagating wave with the pillars around the channel results in a tight confinement of the displacement field. The proposed phononic waveguides demonstrate the feasibility of precise local manipulation of SAW that is essential for emerging frontier applications, notably for phonon‐based classical and quantum information processing. [ABSTRACT FROM AUTHOR]

Published

2023

43. Acoustic waves in functionally graded rods with periodic longitudinal inhomogeneity.

Author

Kuznetsov, S. V.

Subjects

*SOUND waves, *ACOUSTIC surface waves, *PHASE velocity, *ACOUSTIC wave propagation, *STRAIN energy, *KINETIC energy

Abstract

Acoustic waves in periodic functionally graded (FG) 1 D rods are studied by applying the modified Cauchy formalism previously developed for analyzing dispersion of the surface acoustic waves (SAW) in stratified media. In case of harmonic waves traveling in a semi-infinite rod with harmonic periodicity of acoustic properties several phenomena were observed, including the non-periodic spatial variation of the phase velocity and wave magnitude, but spatially periodic variation of kinetic and strain energy. [ABSTRACT FROM AUTHOR]

Published

2023

44. Nonplanar acoustic metasurface for focusing.

Author

Tang, Hanchuan, Hao, Zhuoqun, and Zang, Jianfeng

Subjects

*ACOUSTIC surface waves, *ACOUSTIC vibrations, *SOUND waves, *METAMATERIALS, *COMPOSITE materials

Abstract

Acoustic metasurfaces have attracted considerable attention in recent years because of their unprecedented manipulation of acoustic waves within subwavelength planar structures. However, planar rigid structures are not compatible with human skin, which possesses dynamically varying and highly unconventional geometries. This limits the applicability of acoustic metasurfaces in a promising industry. In this paper, we describe a nonplanar acoustic metasurface for focusing based on the ability of metasurfaces to impart nontrivial phase shifts. We propose a common mapping method for the pattern design that enables focusing behind the free surface. By cutting hollowed-out patterns on a nonplanar metasurface membrane, forming a specialized transmitted phase distribution, we obtain the approximate constructive interference on the focal spot, thus implementing high-efficiency focusing behind an arbitrary nonplanar metasurface. Specifically, we demonstrate focusing on spherical, conical, and chaotic surfaces and discuss the scope of application of our design rule. Moreover, by applying the pattern to conical surfaces, we design an "umbrella structure" to implement high-efficiency focusing with a dynamic, tunable focal length. The proposed nonplanar metasurface not only expands the application range of metamaterials but also demonstrates the real-world applicability of cutting-edge metamaterial research. [ABSTRACT FROM AUTHOR]

Published

2019

45. Features of the Formation of Sensitive Films Based on Mycelium of Higher Fungi for Surface and Plate Acoustic Waves Gas Sensors.

Author

Smirnov, Andrey, Anisimkin, Vladimir, Krasnopolskaya, Larissa, Guliy, Olga, Sinev, Ilya, Simakov, Viacheslav, Golyshkin, Alexander, Almyasheva, Nailya, Ageykin, Nikita, and Kuznetsova, Iren

Subjects

*ACOUSTIC surface waves, *GAS detectors, *MYCELIUM, *DELAY lines, *SURFACE acoustic wave sensors, *WOOD decay, *SOUND waves, *ACOUSTIC wave propagation

Abstract

A comparative analysis of the responses of two types of acoustic waves (surface SAW and plate APW) with close frequencies and the same type of waves (SAW) with different frequencies toward various liquid vapors (water, acetone, ethanol) was carried out in this paper. Two types of films based on mycelium of higher fungus Ganoderma lucidum (Curtis) P. Karst (G. lucidum) prepared by various methods were used as sensitive coatings. These films were based on G. lucidum mycelium ethanolic (48% v/v) homogenizate (MEGl) and extract (EGl). A film deposition procedure compatible with acoustic devices technology was developed. Various piezoelectric substrates (YX-LiNbO3, 128 YX-LiNbO3) were used for appropriate acoustic delay lines production. It was found that additional SAW and APW attenuation associated with the appearance of mycelium films on the surface of the acoustic waveguide is two times greater for MEGL than for EGL films in the frequency range of 20–80 MHz The changes in acoustic wave amplitude and phase due to vapor absorption were measured and compared with each other, taking into account the differences in geometry of the samples. It was found that the phase response of the SAW delay lines with EGL films is three times higher than one with the presence of MEGL films for water and ethanol vapors. The films used are demonstrated good reproducibility and long-term stability for at least 2 months. Based on the results obtained, it was concluded that MEGl film is not appropriate for use in high frequency SAW delay lines as a sensitive coating. However, both types of the films (MEGl and EGl) could be used as sensitive coatings for low frequency SAW and APW sensors based on corresponding delay lines. Additionally, it was found that the films used are not sensitive to acetone vapor. As a result of the work carried out, a technique for creating sensitive films based on the mycelium of higher fungi compatible with the planar technology of acoustoelectronic delay lines was developed. The possibility of using such films for the development of gas SAW and APW sensors was shown. [ABSTRACT FROM AUTHOR]

Published

2023

46. Observation of localized acoustic skyrmions.

Author

Hu, Ping, Wu, Hong-Wei, Sun, Wen-Jun, Zhou, Nong, Chen, Xue, Yang, Yong-Qiang, and Sheng, Zong-Qiang

Subjects

*SKYRMIONS, *ACOUSTIC surface waves, *DATA warehousing, *ACOUSTIC devices, *ANTENNAS (Electronics), *SOUND waves

Abstract

Recently, acoustic skyrmions have been explored by tailoring velocity vectorial near-field distributions based on the interference of multiple spoof surface acoustic waves, providing new dimensions for advanced sound information processing, transport, and data storage. Here, we theoretically investigate and experimentally demonstrate that a deep-subwavelength spiral metastructure can also generate the acoustic skyrmion configuration. Analyzing the resonant response of the metastructure and observing the spatial profile of the velocity field, we find that the localized skyrmionic modes correspond to eigenmodes of the spiral structure. Thus, the skyrmionic modes do not require carefully tailored external excitation condition and they have multiple resonating frequencies unlike the single skyrmionic mode realized by the interference of multiple waves. We also demonstrate that the topological protected skyrmions supported by the subwavelength metastructure is robust against structure deformations and existence of structure defects. The real-space acoustic skyrmion topology may open new avenues for designing ultra-compact and robust acoustic devices, such as acoustic sensors, acoustic tweezers, and acoustic antennas. [ABSTRACT FROM AUTHOR]

Published

2023

47. Machine learning empowered thin film acoustic wave sensing.

Author

Tan, Kaitao, Ji, Zhangbin, Zhou, Jian, Deng, Zijing, Zhang, Songsong, Gu, Yuandong, Guo, Yihao, Zhuo, Fengling, Duan, Huigao, and Fu, YongQing

Subjects

*SOUND waves, *ACOUSTIC surface waves, *THIN films, *SELF-efficacy, *MACHINE learning, *BIOSENSORS, *OPTICAL interference, *CHEMICAL-looping combustion

Abstract

Thin film-based surface acoustic wave (SAW) technology has been extensively explored for physical, chemical, and biological sensors. However, these sensors often show inferior performance for a specific sensing in complex environments, as they are affected by multiple influencing parameters and their coupling interferences. To solve these critical issues, we propose a methodology to extract critical information from the scattering parameter and combine the machine learning method to achieve multi-parameter decoupling. We used the AlScN film-based SAW device as an example in which the highly c-axis orientated and low stress AlScN film was deposited on silicon substrate. The AlScN/Si SAW device showed a Bode quality factor value of 228 and an electromechanical coupling coefficient of ∼2.3%. Two sensing parameters (i.e., ultraviolet or UV and temperature) were chosen for demonstration, and the proposed machine learning method was used to distinguish their influences. Highly precision UV sensing and temperature sensing were independently achieved without their mutual interferences. This work provides an effective solution for decoupling of multi-parameter influences and achieving anti-interference effects in thin film-based SAW sensing. [ABSTRACT FROM AUTHOR]

Published

2023

48. Acoustofluidic precise manipulation: Recent advances in applications for micro/nano bioparticles.

Author

Li, Wanglu, Yao, Zhihao, Ma, Tongtong, Ye, Zihong, He, Kaiyu, Wang, Liu, Wang, Hongmei, Fu, Yingchun, and Xu, Xiahong

Subjects

*ACOUSTIC surface waves, *SOUND waves, *ACOUSTIC field, *FLUID dynamics, *EXTRACELLULAR vesicles

Abstract

Acoustofluidic technologies that integrate acoustic waves and microfluidic chips have been widely used in bioparticle manipulation. As a representative technology, acoustic tweezers have attracted significant attention due to their simple manufacturing, contact-free operation, and low energy consumption. Recently, acoustic tweezers have enabled the efficient and smart manipulation of biotargets with sizes covering millimeters (such as zebrafish) and nanometers (such as DNA). In addition to acoustic tweezers, other related acoustofluidic chips including acoustic separating, mixing, enriching, and transporting chips, have also emerged to be powerful platforms to manipulate micro/nano bioparticles (cells in blood, extracellular vesicles, liposomes, and so on). Accordingly, some interesting applications were also developed, such as smart sensing. In this review, we firstly introduce the principles of acoustic tweezers and various related technologies. Second, we compare and summarize recent applications of acoustofluidics in bioparticle manipulation and sensing. Finally, we outlook the future development direction from the perspectives such as device design and interdisciplinary. [Display omitted] • The evolution timeline of acoustofluidic technology is stated. • The concept of acoustic field and fluid dynamics in the chip is introduced. • Acoustic tweezers to manipulate the categories of bioparticles were reviewed. • Acoustofluidic chip designing is crucial to controlling the bioparticles' trajectory, size, and shape. • Separating, mixing, enriching, and transporting applications of bioparticles were reviewed. [ABSTRACT FROM AUTHOR]

Published

2024

49. Developing Novel Gas Discharge Emitters of Acoustic Waves in Air for Nondestructive Testing of Materials.

Author

Derusova, Daria A., Nekhoroshev, Vitaly O., Shpil'noi, Victor Y., and Vavilov, Vladimir P.

Subjects

*GLOW discharges, *ELECTRIC discharges, *NONDESTRUCTIVE testing, *SOUND waves, *ACOUSTIC surface waves, *ACOUSTIC wave propagation

Abstract

This study was devoted to the development of novel devices and a methodology intended for generating ultrasonic waves in an air medium by using atmospheric pressure gas discharge. In the proposed electrode system, the discharge process was accompanied by the generation of acoustic waves on the emitter surface and, consequently, in the ambient air. The gas discharge emitter vibrations were analyzed by applying the technique of Scanning Laser Doppler Vibrometry (SLDV). It was shown that the magnitude of displacements matched the corresponding characteristics of classical piezoelectric and magnetostrictive transducers. The use of the Fast Fourier transform procedure supplied amplitude–frequency spectra of vibrations generated by the gas discharge emitter. The amplitude–frequency spectrum analysis showed that the proposed emitter was able to generate acoustic waves in the air with frequencies from 50 Hz to 100 kHz, and such a device can be used for the nondestructive testing (NDT) of materials. The results of the statistical analysis of vibration displacements in the repetitive pulsed mode were discussed. A non-stable characteristic of the vibration displacement of the emitter membrane was demonstrated. The parameters of such instability were associated with the features of gas discharge processes. In the experiments, the proposed gas discharge emitter was used in combination with SLDV for inspecting carbon-fiber-reinforced polymer composites. The experiments demonstrated the possibility of using an air-coupled gas discharge transmitter to generate acoustic waves in NDT applications. [ABSTRACT FROM AUTHOR]

Published

2022

50. A new strategy to minimize humidity influences on acoustic wave ultraviolet sensors using ZnO nanowires wrapped with hydrophobic silica nanoparticles.

Author

Guo, Yihao, Zhou, Jian, Ji, Zhangbin, Liu, Yanghui, Cao, Rongtao, Zhuo, Fengling, Tan, Kaitao, Duan, Huigao, and Fu, Yongqing

Subjects

SOUND waves, ACOUSTIC surface waves, NANOWIRES, ZINC oxide, HUMIDITY, SILICA nanoparticles, HYDROPHOBIC compounds

Abstract

Surface acoustic wave (SAW) technology has been widely developed for ultraviolet (UV) detection due to its advantages of miniaturization, portability, potential to be integrated with microelectronics, and passive/wireless capabilities. To enhance UV sensitivity, nanowires (NWs), such as ZnO, are often applied to enhance SAW-based UV detection due to their highly porous and interconnected 3D network structures and good UV sensitivity. However, ZnO NWs are normally hydrophilic, and thus, changes in environmental parameters such as humidity will significantly influence the detection precision and sensitivity of SAW-based UV sensors. To solve this issue, in this work, we proposed a new strategy using ZnO NWs wrapped with hydrophobic silica nanoparticles as the effective sensing layer. Analysis of the distribution and chemical bonds of these hydrophobic silica nanoparticles showed that numerous C-F bonds (which are hydrophobic) were found on the surface of the sensitive layer, which effectively blocked the adsorption of water molecules onto the ZnO NWs. This new sensing layer design minimizes the influence of humidity on the ZnO NW-based UV sensor within the relative humidity range of 10–70%. The sensor showed a UV sensitivity of 9.53 ppm (mW/cm2)−1, with high linearity (R2 value of 0.99904), small hysteresis (<1.65%) and good repeatability. This work solves the long-term dilemma of ZnO NW-based sensors, which are often sensitive to humidity changes. [ABSTRACT FROM AUTHOR]

Published

2022