Your search keyword '"PIEZOELECTRIC thin films"' showing total 2,550 results

1. Quantitative piezoelectric measurements of partially released Pb(Zr, Ti)O3 structures.

Author

Tipsawat, Pannawit, Zheng, Xiaojun, Tran, Quyen T., Jackson, Thomas N., and Trolier-McKinstry, Susan

Subjects

*PIEZOELECTRIC thin films, *SUBSTRATES (Materials science), *LASER interferometry, *THIN films, *MICROFABRICATION

Abstract

The effective large signal longitudinal piezoelectric coefficient (d 33 , f ∗) of piezoelectric thin films on rigid substrates has been widely investigated. Unclamped piezoelectric thin films are predicted to have a higher d 33 , f ∗ coefficient due to reduced constraints on piezoelectric strain, domain reorientation, and domain wall motion, but quantitative measurements of this coefficient have been limited. This study uses microfabrication techniques along with double-beam laser interferometry (DBLI) to accurately determine the longitudinal piezoelectric coefficient of Pb(Zr,Ti)O3 thin films in partially released piezomicroelectromechanical structures. A two-step backside release process was used: first, deep reactive ion etching to create backside vias and second, wet etching of the ZnO sacrificial layer to release the area beneath the Pb(Zr,Ti)O3 thin films. Post wet etching, optical profilometry showed concavely deformed diaphragms resulting from asymmetrical stress profiles through the diaphragm thickness. DBLI was then used to examine diaphragm deflection under an applied unipolar voltage ranging from 0 to 10 V. Devices with 50% and 75% of the area beneath the top electrode released exhibited large signal d 33 , f ∗ values of 410 ± 6 and 420 ± 8 pm/V, respectively, more than three times higher than the d 33 , f ∗ value of the clamped samples: 126 ± 13 pm/V. The reasons contributing to the large d 33 , f ∗ include (i) the change in stress levels due to the release process, (ii) the elimination of mechanical constraints from substrate clamping, and (iii) enhanced domain reorientation. These findings confirm that substrate declamping significantly boosts the piezoelectric coefficient, bringing d 33 , f ∗ closer to the bulk longitudinal piezoelectric coefficient (d33). [ABSTRACT FROM AUTHOR]

Published

2024

2. Low temperature sputtering deposition of Al1−xScxN thin films: Physical, chemical, and piezoelectric properties evolution by tuning the nitrogen flux in (Ar + N2) reactive atmosphere.

Author

Signore, M. A., Serra, A., Manno, D., Quarta, G., Calcagnile, L., Maruccio, L., Sciurti, E., Melissano, E., Campa, A., Martucci, M. C., Francioso, L., and Velardi, L.

Subjects

*PIEZOELECTRIC thin films, *THIN film deposition, *SPUTTER deposition, *LOW temperatures, *KELVIN probe force microscopy, *RUTHERFORD backscattering spectrometry, *ATMOSPHERIC nitrogen

Abstract

This work investigates the physical properties of Al1−xScxN thin films sputtered at low temperatures by varying the process conditions. Specifically, the films were deposited at room temperature by applying a radio frequency power equal to 150 W to an AlSc alloy (60:40) target, varying the nitrogen flux percentage in the (Ar + N2) sputtering atmosphere (30%, 40%, 50%, and 60%) and keeping constant the working pressure at 5 × 10−3 mbar. The structural and chemical properties of the Al1−xScxN films were studied by x-ray diffraction and Rutherford backscattering spectrometry techniques, respectively. The piezoelectric response was investigated by piezoresponse force microscopy. In addition, the surface potential was evaluated for the first time for Sc-doped AlN thin films by Kelvin probe force microscopy, providing piezoelectric coefficients free from the no-piezoelectric additional effect to the mechanical deformation, i.e., the electrostatic force. By alloying AlN with scandium, the piezoelectric response was strongly enhanced (up to 200% compared to undoped AlN), despite the low deposition temperature and the absence of any other additional energy source supplied to the adatoms during thin film growth, which generally promotes a better structural arrangement of polycrystalline film. This is a strategic result in the field of microelectromechanical systems completely fabricated at low temperatures. [ABSTRACT FROM AUTHOR]

Published

2024

3. Investigation of the large-signal electromechanical behavior of ferroelectric HfO2–CeO2 thin films prepared by chemical solution deposition.

Author

Lübben, Jan, Berg, Fenja, and Böttger, Ulrich

Subjects

*FERROELECTRIC thin films, *CHEMICAL solution deposition, *PIEZOELECTRIC thin films, *FERROELECTRIC materials, *CHEMICAL properties, *ELECTRIC fields

Abstract

In this work, the piezoelectric properties of chemical solution deposition derived ferroelectric HfO2–CeO2 thin films deposited on platinized silicon substrates are investigated. Large-signal strain-field measurements show an effective piezoelectric coefficient of approximately d 33 , eff = 12.7 pm / V for 17 mol. % cerium under bipolar excitation and d 33 , eff = 8 pm / V under unipolar excitation. Progressive bipolar electric field cycling leads to a reduction in the overall field induced strain although no fatigue with regards to the polarization is observed. To explain this, we propose a model explanation based on changes in the polarization reversal pathway from a primarily ferroelastic, i.e., 90 ° domain wall mediated switching, to a 180 ° type switching. Furthermore, unipolar strain-field measurements reveal a negative intrinsic piezoelectric coefficient in the absence of any ferroelastic contribution, confirming theoretical predictions. The results suggest that the ferroelastic contribution to the field-induced strain needs to be stabilized in Hafnia-based ferroelectric materials to make them more feasible for micro-electromechanical systems. [ABSTRACT FROM AUTHOR]

Published

2024

4. Induced out-of-plane piezoelectricity and giant Rashba spin splitting in Janus WSiZ3H (Z = N, P, As) monolayers toward next-generation electronic devices.

Author

Vu, Tuan V., Hoi, Bui D., Kartamyshev, A. I., and Hieu, Nguyen N.

Subjects

*PIEZOELECTRICITY, *PIEZOELECTRIC thin films, *MONOMOLECULAR films, *ELECTRONIC equipment, *SPIN-orbit interactions, *MIRROR symmetry, *BAND gaps, *PIEZOELECTRIC materials

Abstract

Two-dimensional (2D) piezoelectric nanomaterials have widely been studied recently due to their promise for various applications in technology. Investigation of vertical piezoelectricity will contribute to a deeper understanding of the intrinsic mechanism of piezoelectric effects in the 2D structures. In this paper, we report a first-principle study for the structural, electronic, piezoelectric, and transport properties of new-designed Janus WSi Z 3 H (Z = N, P, and As) monolayers. The structural stability of WSi Z 3 H is theoretically confirmed based on the energetic, phonon dispersion, and also elastic analyses. At the ground state, while WSiN 3 H is an indirect semiconductor, both WSiP 3 H and WSiAs 3 H are predicted to be direct semiconductors with smaller bandgaps. When the spin-orbit coupling effects are taken into account, a large valley spin splitting is observed at the K point of WSi Z 3 H materials. Interestingly, a giant Rashba spin splitting is found in WSiP 3 H and WSiAs 3 H with Rashba constant α R up to 770.91 meV Å. Additionally, our first-principles study indicates that Janus WSi Z 3 H monolayers are piezoelectric semiconductors with high out-of-plane piezoelectric coefficient | d 31 | , up to 0.15 pm/V, due to the broken mirror symmetry. Besides, with high electron mobilities and also possessing direct band gaps, WSiP 3 H and WSiAs 3 H monolayers are favorable for applications in optoelectronics. [ABSTRACT FROM AUTHOR]

Published

2024

5. Fabrication and characterization of high-temperature AlN thick-film piezoelectric accelerometer.

Author

Lv, Ting, Pelenovich, Vasiliy O., Xu, Chang, Zeng, Xiaomei, Hou, Dongyang, Xiong, Zechang, Yang, Bing, Dong, Fang, and Liu, Sheng

Subjects

*LEAD zirconate titanate, *ALUMINUM nitride, *RADIOFREQUENCY sputtering, *MAGNETRON sputtering, *THERMAL noise, *PIEZOELECTRIC thin films

Abstract

Piezoelectric thick-film (10–100 μm) sensors are mainly manufactured using lead zirconate titanate (PZT) materials, however, their performance is limited in high-temperature environments. Therefore, this paper proposes a high-temperature aluminum nitride (AlN) thick-film accelerometer. The AlN film with a thickness of 10 μm was directly deposited on the stainless steel substrate using the reactive RF magnetron sputtering technique. Compared with the silicon-based piezoelectric accelerometer, the preparation method can improve the energy transfer efficiency of the piezoelectric layer and the fracture toughness of the cantilever beam under vibration deformation and eliminate the need for complicated photolithography, etching, and thinning while being compatible with microelectromechanical systems (MEMS) technology. The experimental results indicated that the sensitivity, resonant frequency, resolution, and thermal noise (T = 300 K) of the accelerometer were 6.73 mV/g, 1193 Hz, 0.45 mg, and 39.76 nV/ Hz , respectively. Further, the designed accelerometer had long-term (6 h) and stable sensitivity at a temperature of 600 °C, indicating its broad potential for application in high-temperature environments. [ABSTRACT FROM AUTHOR]

Published

2024

6. On the Piezoelectric Properties of Zinc Oxide Thin Films Synthesized by Plasma Assisted DC Sputter Deposition.

Author

McKinlay, Michael, Fleming, Lewis, García, Manuel Pelayo, Sierra, Lucía Nieto, Castro, Pilar Villar, Araujo, Daniel, García, Basilio Javier, Gibson, Des, and Nuñez, Carlos García

Subjects

ZINC oxide thin films, PLASMA physics, PIEZOELECTRIC thin films, THIN films, SUBSTRATES (Materials science), MAGNETRON sputtering, ZINC oxide films

Abstract

This work presents a study of piezoelectric zinc oxide (ZnO) thin films deposited by a novel post‐reactive sputtering method. The process utilizes a rotating drum with DC magnetron sputtering deposition onto substrates with subsequent DC plasma‐assisted oxidation of the deposited metal to metal oxide. The paper analyzes the influence of plasmaassisted magnetron sputtering (PA‐MS) deposition parameters (O2 plasma source power, O2 flow, and Ar flow) on the morphological, structural, optical, and piezoelectric properties of ZnO thin films. Design of experiments has been utilized to evaluate the role of these parameters on the growth rate (rg) and the properties of resulting films. Results indicate a predominant influence of the plasma power on the rg over other parameters. Among the eight tested samples, three of them show high crystal quality with high intensity (0001) diffraction peak, characteristic of the wurtzite crystalline structure of ZnO, and one of them exhibits piezoelectric coefficient values of ≈11pC N−1. That sample corresponding to a ZnO film deposited at the lowest rg of 0.075 nm s−1, confirmed the key role of the deposition parameters on the piezoelectric response of films, and demonstrated PA‐MS as a promising technique to produce high‐quality piezoelectric thin films. [ABSTRACT FROM AUTHOR]

Published

2024

7. Flexible Piezoelectric Energy Harvesters with Mechanoluminescence for Mechanical Energy Harvesting and Stress Visualization Sensing.

Author

Fu, Xueting, Cao, Yongquan, Song, Xinyue, Sun, Renbing, Jiang, Hai, Du, Peng, Peng, Dengfeng, and Luo, Laihui

Subjects

*MECHANICAL energy, *PIEZOELECTRIC detectors, *PIEZOELECTRIC composites, *DYNAMIC pressure, *STRESS concentration, *ENERGY harvesting, *PIEZOELECTRIC thin films

Abstract

Flexible piezoelectric energy harvesters (FPEHs) have wide applications in mechanical energy harvesting, portable device driving, and piezoelectric sensors. However, the poor output performance of piezoelectric energy harvesters and the intrinsic shortcoming of piezoelectric sensors that can only detect dynamic pressure limit their further applications. BaTiO3 (BT) and PVDF are deposited on the glass fiber electronic cloth (GFEC) by impregnation and spin‐coating methods, respectively, to form BT‐GFEC/PVDF piezoelectric composite films. A mixed solution of mechanoluminescence (ML) particles ZnS:Cu and PDMS are used as the encapsulation layer to construct a high‐performance ML‐FPEH with self‐powered electrical and optical dual‐mode response characteristics. Due to the interconnection structure of the piezoelectric films, the prepared ML‐FPEH illustrates a high effective energy harvesting performance (≈58 V, ≈43.56 µW cm−2). It can also effectively harvest mechanical energy from human activities. More importantly, ML‐FPEH can sense stress distribution of hand‐writing via ML to achieve stress visualization, making up for the shortcomings of piezoelectric sensors. This work provides a new strategy for endowing FPEH with dual‐mode sensing and energy harvesting. [ABSTRACT FROM AUTHOR]

Published

2024

8. Fully Solution‐Processed Polymeric Multilayer Piezoelectric Devices.

Author

Hu, Shiyu, Zhang, Yanguang, Wang, Dongze, Weber, John, Chang, Shoude, Xiao, Gaozhi, Lu, Jianping, Graddage, Neil, Gao, Jun, Siddiqui, Tahmid Rakin, Islam, Suprabha, Kim, Chun‐il, and Tao, Ye

Subjects

*PIEZOELECTRIC devices, *NANOGENERATORS, *SHORT circuits, *MASS production, *SOLUBILITY, *PIEZOELECTRIC thin films

Abstract

This study demonstrates fully solution‐processed polymeric multilayer piezoelectric devices. The key challenge, the effective control of the redissolution issue that will cause severe electrical shorting and inconsistent piezoelectric output, is overcome by searching for and using a solvent that offers adequate solubility but extremely slow dissolution for the piezoelectric polymer. The solvent screening methodology is established and demonstrated. The process parameters is systematically optimized to maximize the piezoelectric performance of the multilayer devices. The multilayer devices can output a high charge density of 376 µC m−2, even higher than the record charge density of 250 µC m−2 achieved by traditional contact electrification‐based triboelectric nanogenerators operated in ambient air. The crucial factors for increasing device fabrication yield, namely resistance to short circuits and poling‐induced breakdown, are analyzed. The potential of multilayer devices in practical applications is demonstrated using a five‐layer device as a direct power source and energy harvester. More importantly, the process developed here is transferrable for cost‐effective high‐throughput roll‐to‐roll production. This work thus lays the foundation for the mass production of polymeric multilayer piezoelectric devices and paves the way for their future commercialization. [ABSTRACT FROM AUTHOR]

Published

2024

9. Investigation of Microstructure and Physical Characteristics of Eco-Friendly Piezoelectric Composite Thin Films Based on Chitosan and Ln 2 O 3 -Doped Na 0.5 Bi 0.5 TiO 3 -BaTiO 3 Nanoparticles.

Author

Zidani, Jacem, Zannen, Moneim, Da Costa, Antonio, Mlida, Oumayma, Jamali, Arash, Majdoub, Mustapha, El Marssi, Mimoun, Ferri, Anthony, and Lahmar, Abdelilah

Subjects

*PIEZOELECTRIC thin films, *RARE earth metals, *PIEZOELECTRIC composites, *ENERGY harvesting, *DIELECTRIC properties

Abstract

This paper investigates the synthesis and characterization of eco-friendly piezoelectric composite thin films composed of chitosan and Ln2O3-doped Na0.5Bi0.5TiO3-BaTiO3 (NBT-BT) nanoparticles. The films were fabricated using a solution-casting technique, successfully embedding the particles into the chitosan matrix, which resulted in enhanced piezoelectric properties compared to pure chitosan. Characterization methods, such as photoluminescence spectroscopy and piezo-response force microscopy (PFM) which revealed strong electromechanical responses, with notable improvements in piezoelectric performance due to the inclusion of NBT-BT nanoparticles. X-ray diffraction (XRD) analysis revealed a pure perovskite phase with the space group R3c for NBT-BT and NBT-BT-Ln particles. Scanning electron microscopy (SEM) images showed a non-uniform distribution of NBT-BT particles within the chitosan matrix. The results also suggest that the incorporation of rare earth elements further enhances the electrical and piezoelectric properties of the composites, highlighting their potential in flexible and smart device applications. Overall, these findings underscore the potential of chitosan-based composites in addressing environmental concerns while offering effective solutions for energy harvesting and biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2024

10. Nanoelectronics: Materials, Devices and Applications.

Author

Wang, Chunchang

Subjects

*QUANTUM electronics, *TWO-dimensional electron gas, *INFORMATION technology, *ATOMIC layer deposition, *MOORE'S law, *PIEZOELECTRIC thin films, *THIN film transistors

Abstract

The document "Nanoelectronics: Materials, Devices and Applications" explores the field of nanoelectronics, focusing on the manipulation and control of nano-scale materials and devices to address challenges in the semiconductor industry. The document highlights significant breakthroughs in various industries, such as healthcare and energy systems, achieved through the exploration of materials, devices, and their applications in nanoelectronics. It is anticipated that nanoelectronics will replace microelectronics as the mainstay of information technology in the future, impacting human life profoundly. The document includes research articles covering topics like polymers, devices, energy-harvesting, electrons, sensors, and transducers in nanoelectronics, showcasing advancements and potential applications in the field. [Extracted from the article]

Published

2024

11. Spontaneous Alignment of Boron Nitride Nanotubes into Polycrystalline Film Arrays for Enhanced Piezoelectric Nanogeneration.

Author

Kim, Daeun, Ko, Jaehyoung, Kim, Young‐Kyeong, Lee, Sang Seok, Ahn, Seokhoon, Lee, Sanghan, Jang, Se Gyu, and Joo, Yongho

Subjects

*MATERIALS science, *BORON nitride, *LIQUID crystals, *THIN films, *NANOTUBES, *PIEZOELECTRIC thin films

Abstract

1D nanomaterials feature distinct physical properties owing to their characteristic anisotropy and size‐induced quantization; yet, creating an ordered ensemble of the nanomaterials is nontrivial, marking it as a grand challenge in materials science. Herein, the spontaneous alignment of a model 1D nanomaterial, boron nitride nanotube (BNNT), into a highly ordered multidomain film is presented. A conventional, benchtop gravity filtration is employed, during which thickening of the BNNT dispersion leads to a formation of the liquid crystal (LC) phase that is readily isolatable. The spontaneity of the phase separation excludes notoriously persisting synthetic impurities to a degree >99%, from ≈50% of the initial material purity. The LC‐based thin film features an aligned multidomain with an exceptionally low angular deviation of <2.5° and a domain size of >50 μm. A piezoelectric nanogenerator based on the thin film records a 1000‐fold increase in the piezocurrent compared to its random analog. This work demonstrates the first example of the spontaneous alignment of an unconventional nanotube system and the realization of the macroscopic properties therefrom, which can be readily expanded to 1D materials in general. [ABSTRACT FROM AUTHOR]

Published

2024

12. Aspect ratio optimization of piezoelectric extensional mode resonators for quality factor and phase noise performance enhancement.

Author

Tang, Ken-Wei, Lin, Wei, Zope, Anurag A, Lin, Zhong-Wei, and Li, Sheng-Shian

Subjects

*PIEZOELECTRIC thin films, *PHASE noise, *LOW noise amplifiers, *QUALITY factor, *FINITE element method

Abstract

This study focuses on optimizing the resonator geometry via the aspect ratio design of a width-extensional mode resonator to improve its quality factor (Q), which is one of the critical performance parameters for resonators in either sensing (Allan deviation) or frequency reference (phase noise) applications. The proposed approach uses finite element analysis to reduce the strain energy at anchor supports by altering the resonator geometric structure, thereby reducing energy loss through anchors. Moreover, process limitations on feature sizes are used as constraints to find aspect ratios that can not only increase the Q but also reduce spurious modes near the targeted frequency. The devices were fabricated using AlN thin film piezoelectric on a substrate (TPoS) process. The simulated energy dissipation trends for specific length-to-width (L / W) ratios closely match the measured changes in the resonator Q values in vacuum. In vacuum, the highest Q -factor achieved by the device is close to 8816, with a motional resistance of a few tens of ohms. Additionally, a board-level oscillator realized using a commercial low-noise amplifier exhibits phase noise performance of −141.21 dBc Hz−1 and −164.25 dBc Hz−1 at 1 kHz and 1 MHz frequency offsets, respectively. The calculated figures of merit for these offsets are 204 and 168, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

13. Assessing mechanical and stray magnetic field energy harvesting capabilities in lead-free PVDF/BCT-BZT composites integrated with metglas.

Author

Pabba, Durga Prasad, Ram, Nayak, Kaarthik, J., Bhaviripudi, Vijayabhaskara Rao, Yadav, Sandeep Kumar, Soosairaj, Amutha, Pabba, Naveen Kumar, Annapureddy, Venkateswarlu, Thirumurugan, Arun, Panda, H.S., and Aepuru, Radhamanohar

Subjects

*METALLIC glasses, *DIELECTRIC loss, *MAGNETIC fields, *MECHANICAL energy, *ELECTRICAL energy, *PIEZOELECTRIC composites, *ENERGY harvesting, *DIELECTRIC films, *PIEZOELECTRIC thin films

Abstract

The exploration of energy harvesting encompasses a wide array of sources, with a specific focus on recovering mechanical and magnetic energy from overlooked outlets, driving current research endeavours. In this study, we developed highly flexible Magneto-Mechano-Electric (MME) harvesters by combining poly(vinylidene fluoride) (PVDF)/barium calcium zirconium titanate (BCT-BZT) composite films with metglas. The flexible piezoelectric polymer-ceramic composite films were fabricated using a solvent casting technique. The high piezoelectric BCT-BZT fillers were synthesized through a sol-gel reaction route. A thorough analysis was carried out on these composites to evaluate their structural, functional, microstructural, and dielectric properties. The composite film loaded with 20 wt% BCT-BZT filler achieved a 78 % β-phase with a significant enhancement in the dielectric properties, resulting in a high permittivity∼40 and low dielectric loss. Employing these films, we engineered nanogenerators capable of converting mechanical energy into electrical energy, yielding an output voltage of 11 V. Thereafter, to harvest mechanical and stray magnetic fields, we developed a MME generator comprising a magnetic Metglas layer and PVDF-BCT-BZT composite and achieved an output voltage of 3.3 V with a power density of 85 μW/m2 when subjected to an AC magnetic field of 5 Oe. Furthermore, the MME generator has demonstrated the ability to charge various capacitors showcasing its potential for usage in self-powered, non-contact, and implantable devices. [ABSTRACT FROM AUTHOR]

Published

2024

14. Optimized performance of self-driven piezoelectric sensors through KNN/Nb2CTx synergistic effect.

Author

Deng, Jizhong, Zhao, Ping, Wu, Zhiyi, and Wang, Yuanyu

Subjects

*NATURAL disaster warning systems, *PIEZOELECTRIC detectors, *PIEZOELECTRIC composites, *PIEZOELECTRIC thin films, *POLYETHYLENE oxide, *MECHANICAL energy, *ELECTRICAL energy

Abstract

Flexible high-performance piezoelectric nanogenerator (PENG) excel in converting mechanical energy into electrical energy and exhibit remarkable sensitivity, a feature that is paramount for the development of self-driven piezoelectric sensors. In this study, electrospinning technology was used to prepare poly (vinylidene fluoride-co-trifluoroethylene) [P(VDF-TrFE)] based piezoelectric nanofiber composite films containing potassium-sodium niobate nano particles (KNN NPs) and Nb 2 CT x co-doping, as well as single-component doping. The co-doped composite film attained an optimal β-phase content of 91.33%. Owing to the enhanced dipole alignment and interface charge polarization, the piezoelectric performance of the co-doped composite film was significantly enhanced compared to that of single-component doping. The co-doped piezoelectric composite film displayed a stable maximum output voltage of 20 V and an output current of 1.46 μA. The peak instantaneous power output was measured at 9.9 μW under the optimal resistive load of 10 MΩ. Durability testing over 2000 cycles affirmed the excellent mechanical stability of the piezoelectric composite film. Moreover, the fabricated piezoelectric composite film showed considerable potential in applications such as monitoring human activities and serving as an early warning system for natural disasters such as landslides, as indicated by the test results. [ABSTRACT FROM AUTHOR]

Published

2024

15. Noncontact excitation of multi-GHz lithium niobate electromechanical resonators.

Author

Wang, Danqing, Xie, Jiacheng, Guo, Yu, Shen, Mohan, and Tang, Hong X.

Subjects

LITHIUM niobate, PIEZOELECTRIC thin films, FLIP chip technology, RESONATORS, ELECTROMECHANICAL devices, QUALITY factor

Abstract

The demand for high-performance electromechanical resonators is ever-growing across diverse applications, ranging from sensing and time-keeping to advanced communication devices. Among the electromechanical materials being explored, thin-film lithium niobate stands out due to its strong piezoelectric properties and low acoustic loss. However, in nearly all existing lithium niobate electromechanical devices, the configuration is such that the electrodes are in direct contact with the mechanical resonator. This configuration introduces an undesirable mass-loading effect, producing spurious modes and additional damping. Here, we present an electromechanical platform that mitigates this challenge by leveraging a flip-chip bonding technique to separate the electrodes from the mechanical resonator. By offloading the electrodes from the resonator, our approach yields a substantial increase in the quality factor of these resonators, paving the way for enhanced performance and reliability for their device applications. [ABSTRACT FROM AUTHOR]

Published

2024

16. Piezoelectrically driven Fano resonance in silicon photonics.

Author

Ansari, I., Feutmba, G. F., George, J. P., Rijckaert, H., Beeckman, J., and Van Thourhout, D.

Subjects

PIEZOELECTRIC thin films, FANO resonance, VIBRATION (Mechanics), SILICON films, THIN films, LEAD zirconate titanate

Abstract

Piezoelectric optomechanical platforms provide a promising avenue for efficient signal transduction between microwave and optical domains. Lead zirconate titanate (PZT) thin film stands out as a compelling choice for building such a platform given its high piezoelectricity and optical transparency, enabling strong electro-optomechanical transduction. This work explores the application of such transduction to induce Fano resonance in a silicon photonics integrated circuit (PIC). Our methodology involves integrating a PZT thin film onto a silicon PIC and subsequently removing the SiO2 layer to suspend the silicon waveguide, allowing controlled mechanical vibrations. Fano resonances, characterized by their distinctive asymmetric line shape, were observed at frequencies up to 6.7 GHz with an extinction ratio of 21 dB. A high extinction ratio of 41 dB was achieved at the lower resonance frequency of 223 MHz. Our results demonstrate the potential of piezoelectric thin film integration for the generation of Fano resonances on passive photonic platforms such as Si, paving the way for highly sensitive, compact, and power-efficient devices relevant to a wide range of applications. [ABSTRACT FROM AUTHOR]

Published

2024

17. Design and Analysis of SAW Gas Sensor Utilizing AIN/Diamond/Si Multilayered Structure for VOCs Detection.

Author

Abu Waar, Ziad and Moustafa, Mohamed

Subjects

SURFACE acoustic wave sensors, DIAMOND thin films, PIEZOELECTRIC thin films, GAS detectors, FINITE element method, PHASE velocity

Abstract

This study provides insights into the design and analysis of surface acoustic wave sensors customized for detecting volatile organic compounds (VOCs), utilizing an innovative AlN/diamond/Si multilayered configuration. The results are explored numerically using finite element method simulation within the COMSOL Multiphysics package. The potential of the AlN piezoelectric thin film on diamond on Si substrates for sensor development is examined. The phase velocities, electromechanical coupling coefficient, K 2 , and reflectivity are examined versus the normalized thicknesses of the substrates, considering both Rayleigh and Sezawa wave modes. Additionally, the temperature coefficient of frequency (TCF) is investigated. The results show that the TCF increases with reducing the thickness of the diamond. For instance, at khAIN = 2 where the maximum K 2 can be observed, the TCF increases from −17 to −14 to 3 ppm/°C for khdiamond = 0.5, 0.2, and 0.05, respectively. Furthermore, the sensor sensitivity to gas concentration in the air is examined for several VOCs using a thin polyisobutylene (PIB) layer for sensor demonstration. The study shows a remarkable sensitivity enhancement in sensor sensitivity achieved through the Sezawa wave mode compared to the Rayleigh counterpart. For example, in the case of tetrachloroethene gas (PCE), the sensor sensitivity reaches 197.73 Hz/ppm for the Sezawa mode, as opposed to 62.15 Hz/ppm for the Rayleigh mode. [ABSTRACT FROM AUTHOR]

Published

2024

18. Fracture Mechanisms of Lead Zirconate Titanate Piezoelectric Thin Films Determined by Mechanical and Electrical Cyclic Loading Tests.

Author

Yuga Kumakiri, Tomohiro Date, Noriyuki Shimoji, Koji Terumoto, and Takahiro Namazu

Subjects

PIEZOELECTRIC thin films, LEAD zirconate titanate, CYCLIC loads, ELECTRICAL load, STRAINS & stresses (Mechanics), FOCUSED ion beams

Abstract

In this paper, we describe the fracture mechanisms of lead zirconate titanate (PZT) piezoelectric thin films synthesized by sol-gel processing. One of the technical concerns in piezoelectric thin films is how their surface fractures because, in most cases, the films fail electrically, and the fracture surface is remade after its first fracture. To estimate the failure mechanisms, cantilever-type and clamped capacitor-type actuators made of PZT piezoelectric thin films deposited on a Si wafer were prepared and subjected to electrical and mechanical stresses. The cantilever-type actuators showed a decreasing trend in dielectric withstand voltage with increasing number of mechanical loading cycles. The clamped capacitor-type actuators showed a decreasing trend in withstand voltage with increasing cyclic voltage amplitude. Through mechanical and electrical experiments, we found that the origin of cracking differed from that of short circuit. This finding indicates that the PZT films fractured mechanically, then fractured electrically. The focused ion beam fabrication of a surface defect and scanning electron microscopy observation around the defect suggest a reasonable fracture mechanism. [ABSTRACT FROM AUTHOR]

Published

2024

19. Improved piezoelectric properties through manganese-doping in phase coexistence region in lead strontium zirconate titanate (PSZT) thin films.

Author

Priyadarsini, V., Pradeep, Athul, Jumana, P. J., Kanno, Isaku, and Kumar, V.

Subjects

*LEAD zirconate titanate, *STRONTIUM titanate, *THIN films, *PIEZOELECTRIC thin films, *MICROACTUATORS

Abstract

In the quaternary system PbTiO3-PbZrO3-SrTiO3-SrZrO3, compositions that lie close to the antiferroelectric tetragonal and ferroelectric rhombohedral (AFET-FER) phase boundary have potential applications in micro-actuators. However, in thin films, this phase boundary is reported to shift significantly to the zirconium-rich region. Hence, it is necessary to seek alternative approaches to stabilize the tetragonal AFE phase in such compositions. Therefore, this study explores the effect of B-site Mn3+-doping on their structure. Dielectric, ferroelectric, and piezoelectric characteristics of such thin films have been compared with those with increasing Zr/Ti ratios to understand the efficacy of this approach. Transverse piezoelectric coefficient, e31,f, and bipolar strain are found to be higher in Mn3+-doped thin films. Furthermore, large strains and e31,f in thin films have been correlated with structural modifications revealed by systematic Raman spectroscopic investigations. [ABSTRACT FROM AUTHOR]

Published

2023

20. Analysis of Vibration Electromechanical Response Behavior of Poly(Vinylidene Fluoride) Piezoelectric Films.

Author

Wang, Xinyue, Zuo, Jialin, Jiang, Tianlin, Xiao, Jinxin, Tong, Jie, Huang, Shiqing, and Zhang, Wenhua

Subjects

*PIEZOELECTRIC thin films, *DIFLUOROETHYLENE, *FREQUENCIES of oscillating systems, *ELECTRONIC equipment, *THIN films

Abstract

Studying the electromechanical response behavior of piezoelectric thin films under different loading conditions is of great value for the development and optimization of piezoelectric sensors and flexible portable electronic devices. This paper establishes the theory of large deflection vibration of rectangular four-edge simply supported piezoelectric thin films using the energy method, and analyzes the electromechanical response characteristics of vibration force (including resonant frequency and nonlinear vibration). Meanwhile, the electromechanical response behavior of Poly(vinylidene fluoride) (PVDF) films under different loading conditions (static and harmonic vibration) is analyzed. The study investigates the nonlinear vibration characteristics and resonance frequency variations under different film sizes and thickness conditions in the case of various loading conditions. The developed model can predict the resonance frequency associated with the plate dimensions. This study is of great significance for the research and application of laminated piezoelectric film sensors. [ABSTRACT FROM AUTHOR]

Published

2024

21. Application of multi-layered composite fiber films with enhanced piezoelectric performance in flexible energy harvesting devices.

Author

Yuan, Chongxiao, Li, Xiao, Yang, Xinyue, Wu, Fuling, Zhou, Hengqing, Gao, Guoqi, Sun, Huajun, and Liu, Xiaofang

Subjects

*ENERGY harvesting, *FIBROUS composites, *PIEZOELECTRIC composites, *PIEZOELECTRIC thin films, *FIBER orientation, *ELECTRONIC equipment, *PIEZOELECTRIC materials

Abstract

Flexible electronic components such as wearable sensors, energy harvesting devices, and human health monitoring systems based on piezoelectric materials have garnered significant attention within the scientific community. In this study, PZT nanofibers were modified with dopamine hydrochloride prior to their integration into PVDF fibers, serving as piezoelectric reinforcements to enhance the mechanical and piezoelectric characteristics of composite fiber films. Subsequently, a facile hot-pressing method was employed to fabricate multilayered films characterized by a densely packed surface fiber arrangement and a loosely organized internal fiber orientation, which markedly improved the self-supporting ability and fiber density of the electrospun fiber films. A detailed investigation into the micro-morphology, crystallinity, and enhanced piezoelectric properties of the films was conducted. Notably, the composite fiber film containing 6 wt% PZT NFs exhibited a peak piezoelectric coefficient (d 33) of 29 pC/N, resulting in an output voltage of 13.8 V. This represents a 2.23-fold enhancement in d 33 value and a 4.6-fold increase in output voltage when compared to the pristine PVDF fiber film, which had a d 33 of 13 pC/N and an output voltage of 3 V. The power density achieved by the sensor is 0.73 μW/cm2. This performance is underpinned by a high piezoelectric coefficient, outstanding output characteristics, and robust stability, which collectively enhance the sensor's efficacy in various applications. This research presents an effective approach for augmenting the piezoelectric performance of PVDF-based composite films and paves the way for the advancement of piezoelectric energy harvesting applications. [ABSTRACT FROM AUTHOR]

Published

2024

22. Ferroelectric SrMnO3 Thin Film Grown on (110)‐Oriented PMN‐PT Substrate.

Author

Park, Seong Min, Kim, Jaegyu, Anoop, Gopinathan, Seol, WooJun, Lee, Su Yong, Joh, Hyunjin, Kim, Tae Yeon, Choi, Je Oh, Hong, Seungbum, Yang, Chan‐Ho, Lee, Hyeon Jun, and Jo, Ji Young

Subjects

*FERROELECTRIC thin films, *PULSED laser deposition, *SUBSTRATES (Materials science), *ANNEALING of crystals, *THIN films, *PIEZOELECTRIC thin films

Abstract

Exploring the unique physical properties of oxide perovskites necessitates their growth on diverse single‐crystal substrates. The thin‐film growth of perovskite SrMnO3 (SMO) has been a particular focus of research due to its emerging room‐temperature multiferroicity. Herein, the epitaxial thin films of (110)‐oriented SMO are grown on the piezoelectric (110)‐oriented (1–x)Pb(Mg1/3Nb2/3)O3–xPbTiO3 (PMN‐PT) substrate. The effects of the thickness and oxygen annealing on the crystal structure, stoichiometry, and ferroelectric properties of the SMO thin film are systematically investigated. The tensile strain produced by the lattice mismatch between the bulk SMO and the PMN‐PT substrate causes an expansion of the c‐lattice parallel to the in‐plane direction of the substrate. The films show larger a‐, b‐, and c‐lattice parameters than the bulk material, resulting in volume expansion of the unit cell. This lattice expansion is attributed to the generation of oxygen vacancies driven by the reduced formation energy caused by the high elastic strain. Piezoelectric force microscopy reveals that the SMO film contains domains with strain‐mediated in‐plane and vacancy‐mediated out‐of‐plane polarization. Furthermore, the piezoelectric response of the PMN‐PT substrate effectively modulates the biaxial tensile strain in the SMO film, offering a potential strategy for controlling the crystal structure and ferroelectric properties of SMO. [ABSTRACT FROM AUTHOR]

Published

2024

23. Enhancing output current in degradable flexible piezoelectric nanogenerators through internal electrode construction.

Author

Yang, Xinyue, Guo, Huiling, Yuan, Chongxiao, Li, Yuanhui, and Sun, Huajun

Subjects

*NANOGENERATORS, *ENERGY harvesting, *MECHANICAL energy, *PIEZOELECTRIC materials, *POTASSIUM niobate, *PIEZOELECTRIC composites, *PIEZOELECTRIC thin films

Abstract

[Display omitted] Conventional piezoelectric nanogenerators (PNGs) face challenges in terms of degradation and reusability, which have negative environmental implications. On the other hand, biocompatible and degradable piezoelectric materials often exhibit lower piezoelectric response. In this study, potassium sodium niobate (KNN) powder and the biodegradable polymer poly(ε-caprolactone) (PCL) were used to fabricate piezoelectric composite films through solution casting. By constructing staggered electrodes, the total polarized charges quantity is increased, achieving a larger current output. The three-unit PNG (3-PNG) based on the composite film with 15 wt% KNN powder, reaches a maximum output current of 0.85 μA, which exhibits higher charging efficiency compared to 1-PNG. Moreover, the prepared 3-PNG can effectively harvest mechanical energy from human activities and maintain a stable output after 10,000 cycles of bending and releasing. The film exhibits complete degradation when exposed to acidic, neutral, and alkaline solutions. This research provides a promising option for environmentally friendly piezoelectric materials selected and output performance enhanced through optimized structural designs, making them more suitable for practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

24. Asymptotic formula of Rayleigh wave speed in an orthotropic half-space coated by a thin piezoelectric film.

Author

Truong, Thi Thuy Dung, Nguyen, Hai Ha, Pham, Chi Vinh, and Tran, Thanh Tuan

Subjects

*RAYLEIGH waves, *PIEZOELECTRIC thin films, *PIEZOELECTRIC devices, *PIEZOELECTRICITY, *SPEED, *SUBSTRATES (Materials science)

Abstract

Piezoelectric thin films have been widely used in electro-acoustic devices including ones measuring Rayleigh wave speed. The main objective of this work is to find an explicit formula of Rayleigh speed taking into account the effect of the thin piezoelectric film. First the problem of Rayleigh surface waves propagating along an orthotropic substrate coated by a thin piezoelectric film is considered using Stroh's formalism approach. Then, the exact secular equation of Rayleigh wave is obtained in implicit form. In case when the thickness of the thin layer is much smaller than the considering wavelength of Rayleigh waves, an asymptotic formula of Rayleigh speed is derived from the asymptotic form of the exact secular equation. The obtained asymptotic formula is simple enough and could be used in practice when Rayleigh speed is measured by using piezoelectric device. Numerical illustrations are carried out to show the validity of the obtained approximate formulas and its potential application in inverse problem. [ABSTRACT FROM AUTHOR]

Published

2024

25. Significantly optimized piezoelectric catalytic properties of surface functionalized Nano-BaTiO3.

Author

Fu, Ye, Hao, Hua, Liu, Yiren, Fu, Shuai, Guo, Qinghu, Wang, Zhen, Li, Dongxu, Cao, Minghe, Yao, Zhonghua, and Liu, Hanxing

Subjects

*PIEZOELECTRIC thin films, *SURFACE properties, *SIZE reduction of materials, *CATALYTIC activity, *CARBOXYL group, *ORGANIC dyes

Abstract

In piezoelectric catalysis, the interaction between reaction molecules and the catalyst surface is of great significance for designing highly selective reaction processes. In this study, chemically functionalized BaTiO 3 nanoparticles were fabricated using the hydrothermal method, and the piezoelectric catalytic activity was evaluated for degradation dye reactants by ultrasonic vibration. Due to surface modification of BaTiO 3 nanoparticles, the carboxyl groups will be applied on the surface of BaTiO 3 nanoparticles, resulting in the reduction in particle size and an increase in specific surface area. The adsorption of the carboxyl groups on the surface can also improve the ability of the BaTiO 3 nanoparticles to capture the organic dyes. A high piezoelectric catalytic reaction rate constant of 0.0716 min−1, together with a degradation efficiency of >90 % was achieved within 30 min under 60 kHz and 100 W ultrasonic conditions. These results show that the surface modification of BaTiO 3 nanoparticles brought excellent performance of piezoelectric catalysis by controlling the precursor and hydrothermal parameters. This study provides a new method for the preparation of chemically functionalized piezoelectric catalysts and design of other new highly selective catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

26. PZT thick film element balancing flexibility with piezoelectricity fabricated by electrohydrodynamics jet printing used for micro power generator.

Author

Zhao, Kuipeng, Shan, Ziyi, Li, Dongming, Ma, Ruize, Li, Peilin, Wang, Feng, Cui, Yunhao, Zhong, Zhidan, and Zhang, Keke

Subjects

*THICK films, *ELECTROHYDRODYNAMICS, *SURFACE roughness, *SUBSTRATES (Materials science), *PIEZOELECTRICITY, *PIEZOELECTRIC materials, *PIEZOELECTRIC thin films, *LIGHT emitting diodes

Abstract

In this paper, a novel flexible piezoelectric thick-film generator is proposed to address the challenges caused by flexible deformation and high piezoelectricity. This improves the output charge of the generator, which breaks the limitation imposed by the rigid and brittle nature of traditional piezoelectric bulks on elastic strain and piezoelectric performance. Additionally, the low piezoelectric coefficient of piezoelectric polymer-based piezoelectric generators is also resolved. Given the high thickness precision of electrohydrodynamic jet printing technology, the facile production of 10-μm thick film components is achieved through a process of printing and layer-by-layer accumulation on a flexible substrate, which ensures the flexible deformation and piezoelectric characteristics of the functional film. To ensure that AC is converted into stable DC output, a bipolar charge collection circuit is developed. The printed thick film produces an excellent performance in surface uniformity and smoothness. Notably, the piezoelectric constant d 33 is measured to be approximately 80 pC/N, which is five times higher than the d 33 value of flexible PVDF films. Additionally, the strength of adhesion between the printed thick film and the flexible substrate is remarkably high, reaching up to 20 N, which is an order of magnitude higher than the magnetron sputtering method. In a single cycle, the forward charge output reaches an impressively high level of 260 nC, which is approximately thirteen times the charge transfer capability of PVDF flexible generator. Furthermore, a bipolar charge collection circuit is applied to convert AC into DC effectively. This increases the output voltage from 2 V to 4 V. The illumination of commercial electronic screens and 39 LED lights demonstrates the applicability of micron-scale jet-printed thick films in micro-energy harvesting. [ABSTRACT FROM AUTHOR]

Published

2024

27. Corrigendum: Recent progress in piezoelectric thin films as self-powered devices: material and application.

Subjects

SUBSTRATES (Materials science), THIN film devices, MATERIALS science, LEAD zirconate titanate, MORPHOTROPIC phase boundaries, PIEZOELECTRIC thin films

Abstract

This document is a corrigendum for an article titled "Recent progress in piezoelectric thin films as self-powered devices: material and application." The corrigendum addresses errors in the references and their citations in the published article. It provides the correct references for several studies related to AlN and PZT piezoelectric films. The corrigendum aims to rectify the inaccuracies in the original article and ensure the accuracy of the references cited. [Extracted from the article]

Published

2024

28. Recent progress in piezoelectric thin films as self-powered devices: material and application.

Author

Zhiqiang Song, Rongxi Hou, and Feng Jiang

Subjects

PIEZOELECTRIC thin films, THIN film devices, PIEZOELECTRIC materials, ENERGY harvesting, ELECTRONIC equipment

Abstract

Piezoelectric materials have become a key component in sensors and actuators in many industrial fields, such as energy harvesting devices, self-powered structures, biomedical devices, nondestructive testing, owing to the novel properties including high piezoelectric coefficient and electromechanical coupling factors. Piezoelectric thin films integrated on silicon substrates are widely investigated for their high performance and low manufacturing costs to meet the requirement of sensor networks in internet of things (IoT). The aim of this work is to clarify the application and design structure of various piezoelectric thin films types, synthesis methods, and device processes. Based on latest literature, the process of fabricating thin film sensors is outlined, followed by a concise overview of techniques used in microelectromechanical systems (MEMS) processing that can integrate more complex functions to obtain relevant information in surrounding environment. Additionally, by addressing piezoelectric thin films sensors as a cutting-edge technology with the ability to produce self-powered electronic devices, this work delivers incisive conclusions on all aspects of piezoelectric sensor related features. A greater understanding of piezoelectricity is necessary regarding the future development and industry challenges. [ABSTRACT FROM AUTHOR]

Published

2024

29. Effect of Bismuth Ferrite Nanoparticles on Physicochemical Properties of Polyvinylidene Fluoride-Based Nanocomposites.

Author

Petrukhin, Denis, Salnikov, Vitalii, Nikitin, Aleksey, Sidane, Ibtissame, Slimani, Sawssen, Alberti, Stefano, Peddis, Davide, Omelyanchik, Alexander, and Rodionova, Valeria

Subjects

BISMUTH iron oxide, PIEZOELECTRIC thin films, NANOPARTICLES, NANOCOMPOSITE materials, POLYVINYLIDENE fluoride, ENERGY harvesting, LEAD zirconate titanate, FLUORIDES

Abstract

Bismuth ferrite (BiFeO3, BFO) is one of the few single-phase crystalline compounds exhibiting strong multiferroic properties at room temperature, which makes it promising for use in various fields of science and technology. The remarkable characteristics of BFO at the nanoscale position it as a compelling candidate for enhancing the functionalities of polymeric nanocomposite materials. In this study, we explore the fabrication of polyvinylidene fluoride (PVDF) nanocomposites with a variable content of BFO nanopowders (0, 5, 10, 15, 20, and 25 wt%) by solution casting in the form of thin films with the thickness of ~60 µm. Our findings reveal that the presence of BFO nanoparticles slightly facilitates the formation of β- and γ-phases of PVDF, known for their enhanced piezoelectric properties, thereby potentially expanding the utility of PVDF-based materials in sensors, actuators, and energy harvesting devices. On the other hand, the increase in filler concentration leads to enlarged spherulite diameter and porosity of PVDF, as well as an increase in filler content above 20 wt% resulting in a decrease in the degree of crystallinity. The structural changes in the surface were found to increase the hydrophobicity of the nanocomposite surface. Magnetometry indicates that the magnetic properties of nanocomposite are influenced by the BFO nanoparticle content with the saturation magnetization at ~295 K ranging from ~0.08 emu/g to ~0.8 emu/g for samples with the lowest and higher BFO content, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

30. 基于 ScAIN 薄膜的高频 PMUT 阵列的设计与制造.

Author

塔桂峰1. 2., 刘建河,李加东, 姚术涛, 浩杰1. 2., 苗斌2., 商文玲, and 陶金燕2. 3.

Subjects

FOCUSED ion beams, THIN film devices, PIEZOELECTRIC ceramics, ULTRASONIC transducers, NONDESTRUCTIVE testing, PIEZOELECTRIC thin films, LEAD zirconate titanate

Abstract

Copyright of Piezoelectrics & Acoustooptics is the property of Piezoelectric & Acoustooptic and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

31. Large piezoelectric property of Bi(Fe0.93Mn0.05Ti0.02)O3 film by constructing internal bias electric field.

Author

Yuan, Xiufang, Fan, Mengjia, Wang, Wenxuan, Wang, Guoguo, Lin, Xiujuan, Huang, Shifeng, and Yang, Changhong

Subjects

ELECTRIC fields, BISMUTH iron oxide, MICROELECTROMECHANICAL systems, STRAY currents, THIN films, PIEZOELECTRIC thin films

Abstract

BiFeO3 (BFO), Mn-doped-BFO (BFMO), Ti-doped-BFO (BFTO), and (Mn,Ti)-codoped-BFO (BFMTO) thin films are fabricated on the Pt/TiO2/SiO2/Si substrates via a sol–gel method combined with spin-coating and the subsequent layer-by-layer annealing technique. Compared with BFO film, the BFMTO film exhibits the lowest leakage current density (∼ 1 0 − 4 A/cm2@290 kV/cm). Notably, the polarization–electric field (P–E) loop of BFMTO film exhibits a positive displacement along the x-axis due to the existence of internal bias electric field, which is in agreement with the results of the PFM phase and amplitude curves. Especially, a very prominent inverse piezoelectric constant of d 3 3 ∼ 1 6 0 pm/V was obtained, which overcomes other related thin films. The internal bias electric field of BFMTO film can be caused by the different work functions of the thin film and the bottom electrode, accumulation of oxygen vacancies and the formation of defect dipoles. Besides, the internal bias electric field of BFMTO film has a good stability at the same electric field after experiencing the test cycle from low electric field to high electric field (400–1900 kV/cm). These results indicate that self-polarized BFMTO film can be integrated to devices without additional polarization process, and have a wide range of application in microelectromechanical systems. [ABSTRACT FROM AUTHOR]

Published

2024

32. Extremely Stable, Multidirectional, All‐in‐One Piezoelectric Bending Sensor with Cycle up to Million Level.

Author

Yan, Chao, Li, Xiangming, Wang, Xiaopei, Liu, Guifang, Yang, Zhengjie, Tian, Hongmiao, Wang, Chunhui, Chen, Xiaoliang, and Shao, Jinyou

Subjects

*PIEZOELECTRIC detectors, *INTERFACIAL bonding, *AUTOMATIC systems in automobiles, *POLYMER films, *PIEZOELECTRIC thin films, *SHEAR strength, *WEARABLE technology

Abstract

Flexible bending sensors are crucial components of flexible/wearable electronics. However, their broad application is restricted by their difficulty in sensing different bending directions and, more importantly, their significant output attenuation after long cycles. Herein, a new design of an All‐in‐One piezoelectric bending sensor is proposed, in which double‐deck, cross‐over 3D interdigital microelectrodes (silver nanowires (Ag NWs)) are embedded in a piezoelectric polymer film (poly(vinylidene fluoride‐trifluoroethylene (P(VDF‐TrFE))). The piezoelectric film with the embedded 3D microelectrodes exhibits a high anisotropy coefficient (η90∘${{\eta }_{90^\circ }}$ > 1) based on dual piezoelectric modes (d31 and d33), which renders it more sensitive to different bending directions. More importantly, the homogeneous interconnected interface and heterogeneous microinterlocked interface formed inside the sensor significantly enhance its interface mechanical properties, with at least a tensile strength of 51 MPa, a shear strength of 28 MPa, and an interfacial toughness of 300 J m−2, which are nearly two orders of magnitude greater than those of conventional sandwich architectures. The prepared All‐in‐One sensor shows an extremely stable piezoelectric output over as many as 16 00 000 bending cycles, which represents a remarkable breakthrough. Furthermore, a single sensor can be used to remotely control the multidirectional motion of a smart car, demonstrating enormous potential in practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

33. Trans-membrane piezoelectric activation of peroxymonosulfate for effective control of waterborne antibiotic resistance dissemination.

Author

Yu, Yang, Liu, Lianyu, Xie, Yiqiao, Huang, Wei, Liu, Hai, Liu, Xiaotu, and Chen, Da

Subjects

DRUG resistance in bacteria, REACTIVE oxygen species, PEROXYMONOSULFATE, HYDROXYL group, PIEZOELECTRIC thin films, WATER currents, RADICALS (Chemistry)

Abstract

Increasing prevalence of antibiotic resistant bacteria (ARB) and antibiotic resistance genes (ARGs) constitutes an emerging water safety issue globally. However, the effectiveness of current water treatment techniques in the control of ARGs dissemination remains controversial. Here, we develop a dual-zone strategy based on piezoelectric membrane filtration to efficiently eliminate waterborne antibiotic resistance. Following complete ARB inactivation and effective ARGs reduction in the retentate near the membrane surface (zone 1), a subsequent trans-membrane process (zone 2) further promotes ARGs elimination in the permeate, due to boosted interactions between ARGs and reactive oxygen species (ROS) generated from piezoelectric peroxymonosulfate activation and minimized ROS competition from inactivated ARB within piezocatalytic channels. The abundance of ARGs was largely reduced to ~1.0 × 103 copies·mL−1 in the permeate from ~5.0 × 106 copies·mL−1 in the feed solution. The singlet oxygen (1O2) is demonstrated to be primarily responsible for ARB inactivation, while 1O2, hydroxyl radical (•OH), sulfate radical (SO4·−) and superoxide radical (·O2−) can all participate in ARGs degradation. Our work demonstrates that the piezoelectric membrane-based dual-zone strategy has great potential to control the risk of ARGs dissemination. [ABSTRACT FROM AUTHOR]

Published

2024

34. All‐organic shell–core PVDF/PMMA composite fiber films with enhanced piezoelectric performance for flexible sensing and energy harvesting.

Author

Li, Xiao, Yuan, ChongXiao, Gao, Guoqi, Zhou, Hengqing, Zhang, Nannan, Yang, Xinyue, Liu, Xiaofang, and Sun, Huajun

Subjects

ENERGY harvesting, FIBROUS composites, POLYMETHYLMETHACRYLATE, PIEZOELECTRIC thin films, PIEZOELECTRIC materials, PIEZOELECTRIC composites, HYDROGEN bonding

Abstract

The demand for self‐powered sensing technology and energy harvesting system necessitates high‐performance and flexible piezoelectric materials. This paper presents a novel approach utilizing coaxial electrospinning to fabricate all‐organic PVDF/PMMA piezoelectric fiber films with a shell–core structure. The resulting fiber films, cut into 2 × 2 cm2 square pieces and hot‐pressed every three pieces, demonstrate enhanced piezoelectric properties while retaining high flexibility. The interaction between the CO bonds in the PMMA polymer and the CH2 in PVDF promotes the arrangement of F atoms in PVDF, enhancing the content of the piezoelectric active phase. Additionally, the coaxial electrospinning process fosters vertically oriented hydrogen bonds between PVDF and PMMA, augmenting cross‐linking and improving mechanical properties. Notably, when the PVDF to PMMA layer volume ratio is 5:1, the piezoelectric coefficient (|d33|) of the composite fiber film exhibits a significant 60% increase from 10 pC N−1 in neat PVDF to 16 pC N−1. This research holds substantial promise for applications in self‐powered sensing and energy harvesting piezoelectric materials. [ABSTRACT FROM AUTHOR]

Published

2024

35. Enhanced Piezoelectricity by Polarization Rotation through Thermal Strain Manipulation in PbZr0.6Ti0.4O3 Thin Films.

Author

Huang, Sizhao, Houwman, Evert, Gauquelin, Nicolas, Orekhov, Andrey, Chezganov, Dmitry, Verbeeck, Johan, Hu, Sixia, Zhong, Gaokuo, Koster, Gertjan, and Rijnders, Guus

Subjects

PIEZOELECTRIC thin films, THIN films, THERMAL strain, FERROELECTRIC thin films, PHASE transitions, PULSED laser deposition, ELECTROMECHANICAL effects, PIEZOELECTRICITY

Abstract

Lead based bulk piezoelectric materials, e.g., PbZrxTi1‐xO3 (PZT), are widely used in electromechanical applications, sensors, and transducers, for which optimally performing thin films are needed. The results of a multi‐domain Landau–Ginzberg‐Devonshire model applicable to clamped ferroelectric thin films are used to predict the lattice symmetry and properties of clamped PZT thin films on different substrates. Guided by the thermal strain phase diagrams that are produced by this model, experimentally structural transitions are observed. These can be related to changes of the piezoelectric properties in PZT(x = 0.6) thin films that are grown on CaF2, SrTiO3 (STO) and 70% PbMg1/3Nb2/3O3‐30% PbTiO3 (PMN‐PT) substrates by pulsed laser deposition. Through temperature en field dependent in situ X‐ray reciprocal space mapping (RSMs) and piezoelectric force microscopy (PFM), the low symmetry monoclinic phase and polarization rotation are observed in the film on STO and can be linked to the measured enhanced properties. The study identifies a monoclinic ‐rhombohedral MC‐MA‐R crystal symmetry path as the polarization rotation mechanism. The films on CaF2 and PMN‐PT remain in the same symmetry phase up to the ferroelectric‐paraelectric phase transition, as predicted. These results support the validity of the multi‐domain model which provides the possibility to predict the behavior of clamped, piezoelectric PZT thin films, and design films with enhanced properties. [ABSTRACT FROM AUTHOR]

Published

2024

36. Enhanced Piezoelectric Energy Harvester by Employing Freestanding Single‐Crystal BaTiO3 Films in PVDF‐TrFE Based Composites.

Author

Peng, Ruobo, Zhang, Butong, Dong, Guohua, Wang, Yinghui, Yang, Guannan, Zhang, Jie, Peng, Bin, Zhao, Yanan, and Liu, Ming

Subjects

*NANOGENERATORS, *ENERGY harvesting, *ELECTRONIC equipment, *PIEZOELECTRIC thin films, *POWER density, *SANDWICH construction (Materials), *BIO-imaging sensors, *PIEZOELECTRIC transducers

Abstract

Advancements in wearable electronics and Internet of Things (IoT) sensors have catalyzed the need for effective micro‐energy harvesting. Piezoelectric nanogenerators (PENGs) are ideal due to their high conversion efficiency and durability. However, the contrast between the high piezoelectric coefficients of brittle inorganic ceramics and the lower coefficients of superior flexibility and biocompatibility of organic polymers poses a significant challenge. This work introduces a novel multilayer composite PENG, integrating a single‐crystal BaTiO3 (BTO) film between poly(vinylidene fluoride‐co‐trifluoroethylene) (PVDF‐TrFE) layers. The PVDF‐TrFE/BTO/PVDF‐TrFE PENGs demonstrate substantially improved energy harvesting performance, with outputs reaching up to 15.1 V, 2.39 µA, and power density of 17.33 µW cm−2 during bending deformation. This power density represents a significant increase compared to pure PVDF‐TrFE and nanoparticle BTO‐doped PVDF‐TrFE PENGs. Durability tests show consistent performance, with a stable ∼15.0 V output across 2000 bending cycles. Additionally, when attached to the human body, these PENGs efficiently convert body motions into electrical responses. This work demonstrates a significant enhancement in the performance of PENGs using sandwich‐structured composite of PVDF‐TrFE and freestanding single‐crystal BTO films, showing its potential to address the power requirements of wearable and flexible electronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

37. The Robust Ferroelectric and Electrical Response in 2D Bi2O2Se Semiconductor.

Author

Khan, Usman, Xu, Runzhang, Nairan, Adeela, Han, Mengjiao, Wang, Xusheng, Kong, Lingan, Gao, Junkuo, and Tang, Lei

Subjects

*PIEZORESPONSE force microscopy, *SEMICONDUCTORS, *FERROELECTRIC materials, *CHEMICAL vapor deposition, *FIELD-effect transistors, *ENERGY harvesting, *PIEZOELECTRIC thin films, *RELAXOR ferroelectrics

Abstract

The amelioration of atomically thin ferroelectric materials is imperative for next‐generation outperformed two‐dimensional (2D) electronics, which is elusive by their bulk counterparts. These remarkable materials' ferroelectric and piezoelectric features are the fundamental urges in optoelectronics, electronics, and energy harvesting. In this work, 2D ferroelectric Bi2O2Se flakes have been synthesized using a modified chemical vapor deposition technique. The 6 nm thick Bi2O2Se flake provides a robust ferroelectric switching under an applied voltage of ±10 V by piezoresponse force microscopy, further confirmed by first principles. Leveraging the successful growth, the high‐quality Bi2O2Se flakes permit the fabrication of a field‐effect transistor (FET) with state‐of‐the‐art performance. The FET device rewards a high current on–off ratio of 108 and field effect mobility of almost 131 cm2 V−1 s−1, owing to the small carrier effective mass of 0.2 m0. Combined, the electric field‐induced local polarization of ferroelectric switching and unprecedented device performance of Bi2O2Se semiconductors are certified for their utilization in advanced nanoelectronics and miniaturization of multifunctional devices with multifunctionalities. [ABSTRACT FROM AUTHOR]

Published

2024

38. Flexible Piezoelectric Sensors Based on Ionic Liquid‐doped Poly(L‐Lactic Acid) for Human Coughing Recognition.

Author

He, Zifeng, Liu, Yijie, Babichuk, Ivan S., Zhou, Zisen, Liu, Zhaohua, Yang, Xiongbang, Zhou, Ruiliang, Pu, Yan, Li, Shuhao, Chang, Yu, Ye, Terry Tao, Gao, Zhaoli, and Yang, Jian

Subjects

*PIEZOELECTRIC detectors, *HILBERT-Huang transform, *PIEZOELECTRIC thin films, *COUGH, *ACOUSTIC imaging, *LACTIC acid

Abstract

Cough is a common symptom of various respiratory diseases. However, recognizing a subject's cough using acoustic imaging can be challenging due to the complexity of coughing and the vulnerability of acoustic acquisition to external interference. This research aims to address these issues by utilizing a flexible piezoelectric ionic liquid‐doped poly(L‐lactic acid) (PLLA) sensor to gather the pressure signals from the human surface. 1‐butyl‐3‐methylimidazolium bis (trifluoromethylsulfonyl)imide ([BMIm]TFSI) ionic liquid (IL) can enhance the piezoelectric performance of PLLA thin film, the corresponding output voltage, and impact sensitivity are improved to three times and 105.1% for the PLLA/IL thin film with 1 wt% IL, 140 °C annealing 2 h and four times drawing ratio. The effect of IL on the crystallization behavior and piezoelectric properties of thin films during their preparation is investigated. The flexible PLLA/IL sensor is integrated into a wearable electronic system which collects and transmits piezoelectric signals from cough‐induced vibrations to the filter for denoising, then the acquired cough data are decomposed using the Empirical Mode Decomposition method and trained in a multi‐layer perception model to detect human coughing. It's evident that the flexible piezoelectric PLLA/IL sensors can be applied to human coughing recognition and show great potential applications in intelligent healthcare. [ABSTRACT FROM AUTHOR]

Published

2024

39. Small extracellular vesicles' enrichment from biological fluids using an acoustic trap.

Author

Mengli Chen, Zhiguo Pei, Yao Wang, Feifei Song, Jinfeng Zhong, and Ce Wang

Subjects

*EXTRACELLULAR vesicles, *PLASMA flow, *PIEZOELECTRIC transducers, *MICROFLUIDICS, *FLUIDS, *BLOOD plasma, *PIEZOELECTRIC thin films

Abstract

Small extracellular vesicles (sEVs), a form of extracellular vesicles, are lipid bilayered structures released by all cells. Large-scale studies on sEVs from clinical samples are necessary, but a major obstacle is the lack of rapid, reproducible, efficient, and low-cost methods to enrich sEVs. Acoustic microfluidics have the advantage of being label-free and biocompatible, which have been reported to successfully enrich sEVs. In this paper, we present a highly efficient acoustic microfluidic trap that can offer low and large volume compatible ways of enriching sEVs from biological fluids by flexible structure design. It uses the idea of pre-loading larger seed particles in the acoustic trap to enable sub-micron particle capturing. The microfluidic chip is actuated using a piezoelectric plate transducer attached to a silicon-glass bonding plate with circular cavities. Each cavity works as a resonant unit, excited at the frequency of both the half wave resonance in the main plane and inverted quarter wave resonance in the depth direction, which has the ability to strongly trap seed particles at the center, thereby improving the subsequent nanoparticle capture efficiency. Mean trapping efficiencies of 35.62% and 64.27% were obtained using 60 nm and 100 nm nanobeads, respectively. By the use of this technology, we have successfully enriched sEVs from cell culture conditioned media and blood plasma at a flow rate of 10 µL min-1. The isolated sEV subpopulations are characterized by NTA and TEM, and their protein cargo is determined by WB. This acoustic trapping chip provides a rapid and robust method to enrich sEVs from biofluids with high reproducibility and sufficient quantities. Therefore, it can serve as a new tool for biological and clinical research such as cancer diagnosis and drug delivery. [ABSTRACT FROM AUTHOR]

Published

2024

40. Influence of the Domain Structure of LaBGeO5 Polar Crystals on Their Gyrotropic Properties.

Author

Konstantinova, A. F., Golovina, T. G., Mareev, E. I., Butashin, A. V., Volchkov, I. S., Gainutdinov, R. V., Asharchuk, N. M., Kasimova, V. M., Zabelina, E. V., and Kozlova, N. S.

Subjects

*SECOND harmonic generation, *ABSORPTION coefficients, *CRYSTAL symmetry, *SCANNING electron microscopy, *CRYSTALS, *PIEZOELECTRIC thin films, *OPTICAL rotation

Abstract

The spectra of transmisson coefficients and absorption indices of single-domain and multidomain LaBGeO5 samples have been measured. It is shown that, to measure more exactly the optical rotation ρ, it is necessary to use the spectra of transmission coefficients not only for the cases of parallel and crossed polarizers but also at other angles between them. The obtained ρ values for both samples are described quite well by only dispersion using the Drude formula. This is in agreement with the fact that the ρ value should not change during transition to the single-domain state of the crystal at a given symmetry (P31 in the ferroelectric phase and P3121 in the paraelectric phase). It is shown that the Cherenkov-type second harmonic generation (SHG) is observed only in a polydomain sample, while the second-harmonic radiation is not polarized. The domain structure of the samples was observed by scanning electron microscopy and piezoelectric force microscopy. The presence of a labyrinth-like domain structure was shown for the multidomain sample, whereas for a single-domain sample no changes in contrast were observed within the scanned region. [ABSTRACT FROM AUTHOR]

Published

2024

41. A Review of Plasma-Synthesized and Plasma Surface-Modified Piezoelectric Polymer Films for Nanogenerators and Sensors.

Author

Jung, Eun-Young, Suleiman, Habeeb Olaitan, Tae, Heung-Sik, and Park, Choon-Sang

Subjects

*POLYMER films, *NANOGENERATORS, *PIEZOELECTRIC materials, *PIEZOELECTRIC detectors, *VAPOR-plating, *PIEZOELECTRIC thin films, *LEAD zirconate titanate

Abstract

In this review, we introduce recently developed plasma-based approaches for depositing and treating piezoelectric nanoparticles (NPs) and piezoelectric polymer films for nanogenerator (NG) and sensor applications. We also present the properties and an overview of recently synthesized or modified piezoelectric materials on piezoelectric polymers to highlight the existing challenges and future directions of plasma methods under vacuum, low pressure, and ambient air conditions. The various plasma processes involved in piezoelectric NGs and sensors, including plasma-based vapor deposition, dielectric barrier discharge, and surface modification, are introduced and summarized for controlling various surface properties (etching, roughening, crosslinking, functionalization, and crystallinity). [ABSTRACT FROM AUTHOR]

Published

2024

42. Self-assembly ordered domain configurations serve the high electromechanical response lead-free thin films.

Author

Zhu, Kun, Shi, Xiaoming, Ge, Guanglong, Yang, Weiwei, Qian, Jin, Shi, Cheng, Liu, Yang, Zeng, Huarong, Man, Zhenyong, Wei, Yongqi, Shen, Bo, Zhai, Jiwei, Huang, Houbing, and Chou, Xiujian

Subjects

*LEAD-free ceramics, *THIN films, *MORPHOTROPIC phase boundaries, *PIEZOELECTRIC thin films, *ELECTRIC stimulation

Abstract

Micro-electromechanical systems (MEMS) urgently require high-performance lead-free piezoelectric thin films, which is rather difficult to achieve via the existing strategy of designing a morphotropic phase boundary. How to update the optimization methods for piezoelectric performance is a challenge. Here, we proposed a simple and interesting way, that is, constructing the self-assembly ordered domain configurations in our oriented lead-free thin films. Driven by the local strain, we realized a periodic arrangement of disordered nano-domains and ordered striped domain structures, and thus obtained an outstanding electrostrain of 1.55%. Multi-scale characterization and phase-field simulations suggest the underlying mechanism of this giant strain as the synergy between the high polarization brought about by the periodic nano-pillar-like striped domains, the highly sensitive electrical stimulation response of defective dipoles and disordered nano-domains. The presented high electrostrain supports the potential MEMS application, the proposed optimization strategy serves the next generation lead-free thin films with higher electromechanical response. [ABSTRACT FROM AUTHOR]

Published

2024

43. Synthesis of High‐Performance Polyvinylidene Fluoride Composites via Hydroxyl Anchoring Effect and Directional Freeze‐Drying Method.

Author

Lu, Jiaqi, Zhang, Kaihang, Hazarika, Dinku, Xu, Liangquan, Li, Jie, Wu, Jianhui, Naeem Shah, Muhammad, Jin, Hao, Dong, Shurong, Huang, Yuhui, Zhang, Qilong, Wu, Yongjun, and Luo, Jikui

Subjects

POLYVINYLIDENE fluoride, ANCHORING effect, PIEZOELECTRIC thin films, POLARIZATION (Electricity), FREEZE-drying, PIEZOELECTRIC composites, MOLECULAR dynamics

Abstract

Polyvinylidene fluoride (PVDF) and its copolymers present extensive application prospects, especially in the field of wearable electronics. However, utilizing nanofillers for enhanced β‐phase and piezoelectric properties faces challenges like noncontinuous interfaces, poor compatibility between nanofillers and PVDF matrix, and the requirement of high‐voltage polarization, hindering extensive domain alignment on a large scale. Herein, a method is proposed to synthesize high‐performance PVDF composites by introducing hydroxylated barium titanate (H@BTO) nanoparticles and a directional freeze‐drying method to enhance β‐phase content and piezoelectric properties without polarization. Molecular dynamics simulations reveal robust binding interactions between Ba and F atoms along with OH surface terminations on H@BTO, facilitating hydrogen bonding within the PVDF matrix, resulting in dipole alignment and increased spontaneous polarization. The composite film achieves an 86.69% β phase content and a piezoelectric coefficient of ≈14.49 pm V−1 without electric polarization. The freeze‐drying PVDF‐H@BTO composite film paired with a PA6 membrane is used to fabricate triboelectric nanogenerator, demonstrating a current density of ≈107.5 mA m−2 and an output voltage of ≈832 V. Results demonstrate that the utilization of strong binding interactions between various atoms, the hydroxyl anchoring effect, and directional freeze‐drying method as a strategy holds promising prospects for synthesizing high‐performance piezoelectric composites. [ABSTRACT FROM AUTHOR]

Published

2024

44. Design and Fabrication of Micro/Nano Sensors and Actuators.

Author

Wang, Weidong, Yang, Ruiguo, and Liu, Min

Subjects

DETECTORS, TACTILE sensors, ACTUATORS, MAGNETIC sensors, PIEZOELECTRIC thin films, INTEGRATED circuits manufacturing, EDDY current losses

Abstract

This document discusses the design and fabrication of micro/nano sensors and actuators, specifically focusing on micro-electromechanical systems (MEMS). MEMS devices integrate various components such as sensors, converters, and actuators into one or more chips. These devices are made from materials like silicon, metal, ceramics, and glass, which greatly influence their performance. The document also highlights the importance of process manufacturing in determining the reliability and performance of MEMS devices. The Special Issue included in the document features 11 papers that explore different aspects of MEMS/NEMS, including device design, materials, and manufacturing processes. [Extracted from the article]

Published

2024

45. Eco-friendly piezoelectric energy harvester from crustacean shells.

Author

Marimuthu, Ramar, Devarayan, Kesavan, Sukumaran, Monikandon, Rasu, Palani, Maruthu, Lavanya, Ramasamy, Mahalakshmi, and Muruganantham, Sinthiya

Subjects

*PIEZOELECTRIC thin films, *CRAB shells, *ENERGY harvesting, *COPPER electrodes, *SHRIMPS, *CRUSTACEA, *COPPER plating

Abstract

We have developed a piezoelectric thin film from shrimp and crab shells, after demineralizing the shells and removing the minerals to create a flexible, transparent film. The dried piezoelectric thin film plated between copper electrodes contains a piezoelectric harvesting circuit that stores energy derived from the shells. A rectifier circuit is connected to this experimental set up and output is observed in order to find output how the energy is extracted from the crustacean shells. This process makes the energy an eco-friendly source of energy. The flexibility of processed crustacean film such as shrimp and crab shells will be important in energy harvesting devices. [ABSTRACT FROM AUTHOR]

Published

2024

46. Grain to grain heterogeneity in PZT thin films as probed by in situ biasing XRD.

Author

Nguyen, Kien, Gueye, Ibrahima, Leake, Steven, Le Rhun, Gwenael, Gergaud, Patrice, and Vaxelaire, Nicolas

Subjects

*PIEZOELECTRIC thin films, *THIN films, *GRAIN, *HETEROGENEITY, *X-ray diffraction

Abstract

Piezoelectric thin films are particularly difficult to model at the grain scale. Moreover, this problem is sparsely experimentally documented due to the lack of adequate methods. Here, an original methodology is proposed to study the behavior of single grains during in situ biasing. Pb(Zr,Ti)O3 films have been evaluated thanks to an in situ biasing x-ray diffraction technique performed on a synchrotron source with a sub-micronic x-ray beam. Small capacitors have been biased with DC voltage between 0 and ±20 V and at each step of bias a set of spotty Debye rings have been recorded. By selecting an appropriate region of interest, the evolution of a single grain peak has been followed. The fine analysis of these peaks allows to calculate the effective piezoelectric coefficient d33,eff, the proportion of each domain variants, the tetragonality inside each grain, as well as their evolution during the electrical biasing. A higher heterogeneity in samples with morphotropic phase boundary composition is observed. This study contributes to a better understanding of the local behaviors in piezo/ferroelectric polycrystalline films and in the improvement of their performance for different applications. [ABSTRACT FROM AUTHOR]

Published

2023

47. Analysis of surface effect and flexoelectric effect on the electromechanical responses of bilayered transversely isotropic rectangular micro-plate.

Author

Zhou, Shasha, Zhang, Rongmin, Qiao, Jinwei, Li, Anqing, and Zhou, Shenjie

Subjects

*ELECTROMECHANICAL effects, *SURFACE analysis, *ULTRASONIC transducers, *RESIDUAL stresses, *FLEXOELECTRICITY, *PIEZOELECTRICITY, *PIEZOELECTRIC thin films

Abstract

A new model of a bilayered transversely isotropic piezoelectric rectangular micro-plate with a distributed load is developed on the basis of Kirchhoff's plate theory and the extended linear piezoelectricity theory to characterize the piezoelectric micromachined ultrasonic transducer. The model takes into account both the surface effect and the flexoelectricity effect. The governing equation at the simply supported boundary condition is derived according to the variation principle. Based on the new model, the size dependent electromechanical coupling behaviors of the bilayered piezoelectric rectangular micro-plate are investigated. Considering the flexoelectric effect and surface effect synchronously, the numerical result indicates that the size dependence of the normalized central deflection decreases as the residual surface stress increases. For negative residual stress, the surface effect is the main influencing factor. While for positive residual stress, the surface effect dominates only when the ratio of thickness to length is smaller than about 25; otherwise, the flexoelectric effect will be more crucial. Moreover, if the thickness of the piezoelectric layer is less than about 40 nm, the electrical potential and polarization show a stronger size dependence. These results will be helpful to design and manufacture a piezoelectric micromachined ultrasonic transducer. [ABSTRACT FROM AUTHOR]

Published

2022

48. On the structural, dielectric, piezoelectric, and energy storage behavior of polyvinylidene fluoride (PVDF) thick film: Role of annealing temperature.

Author

Jaglan, Nitin and Uniyal, Poonam

Subjects

*POLYVINYLIDENE fluoride, *LEAD zirconate titanate, *THICK films, *FOURIER transform infrared spectroscopy, *PIEZOELECTRIC thin films, *ENERGY storage, *DIELECTRICS, *ENERGY density

Abstract

The optimization of the processing condition of polyvinylidene fluoride (PVDF) plays a pivotal role in determining the structural, dielectric, and energy storage behavior. The present work addresses the effect of annealing on the structural, dielectric, piezoelectric, and energy storage behavior of the PVDF thick film. X-ray diffractogram/Fourier transform infrared spectroscopy/RAMAN reveals the enhancement in the β crystalline phase of PVDF with annealing temperature which is highest for the film annealed at 110 °C. The film annealed at 110 °C exhibited the dielectric constant, dielectric loss, and piezoelectric coefficient as 14.02, 0.05 at 100 Hz and 24 pC/N, respectively. A systematic enhancement of 21% in dielectric constant, 46% in discharge energy density, and 87% in piezoelectric coefficient is reported for the PVDF film annealed at 110 °C as compared to the film annealed at 50 °C. The enhancement in dielectric and energy storage properties is attributed to the alignment of CH2–CF2 by virtue of molecular motion in the PVDF chain. This work suggests the adaptation of annealing for modifying the dielectric and energy storage behavior which is momentous for various electronic applications. [ABSTRACT FROM AUTHOR]

Published

2022

49. Piezoelectric composites from sandwiched polydimethylsiloxane sponges.

Author

Hu, Hang, Li, Dongsheng, and Zhu, Weijun

Subjects

*SANDWICH construction (Materials), *THIN films, *PIEZOELECTRIC materials, *POLYTEF, *ENERGY harvesting, *POLYDIMETHYLSILOXANE, *ELASTOMERS, *PIEZOELECTRIC composites, *PIEZOELECTRIC thin films

Abstract

A novel elastomer-based composite material with enhanced piezoelectric performances is proposed in this paper, which is composed of the top and bottom polytetrafluoroethylene (PTFE) solid films with the middle PTFE nanoparticle–polydimethylsiloxane (PDMS) sponge layer. To enhance the charge retention capability of elastomers, PTFE nanoparticles are introduced to form PTFE–PDMS interfaces, which can trap charges with longevity. Besides, PTFE solid films take on the role of the charge blocking layers to further improve the piezoelectric performances. As a result, the PTFE–PDMS sandwich structure shows the advantages of remarkable sensitivity (1053 pC/N), high stability, and flexibility. After a 6 h of annealing treatment at the temperature of 100 °C, no significant deterioration of the piezoelectric properties can be observed, which reveals the great thermal stability of the sandwich structure. In addition, the sandwich structure can be immersed in water for 24 h without any loss of piezoelectric activity. Finally, the experiment of lighting one LED by hand pressing successfully demonstrates that the sandwich structure has good applicability in the field of energy harvesting. Considering the excellent electrical and mechanical features, the PTFE–PDMS sandwich structure has promising applications in sensing, energy harvesting, and actuation. [ABSTRACT FROM AUTHOR]

Published

2022

50. Enhanced piezoelectric properties and domain morphology under alternating current electric field poled in [001]-oriented PIN-PMN-PT single crystal.

Author

Song, Kexin, Ma, Ming, Hu, Qingyuan, Qiao, Liao, Zhao, Jinyan, Qiu, Chaorui, Liu, Jinfeng, Luan, Peng, Guo, Haisheng, Li, Fei, Li, Zhenrong, Fan, Shiji, and Xu, Zhuo

Subjects

*SINGLE crystals, *ELECTRIC fields, *POLARIZATION microscopy, *FERROELECTRIC crystals, *STRESS fractures (Orthopedics), *PIEZOELECTRIC thin films

Abstract

The piezoelectric and dielectric properties of PMN-PT single crystals were significantly enhanced by alternating current electric field poling (ACP). In this work, to investigate the mechanisms of piezoelectric performance enhancement in relaxor ferroelectric single crystals by ACP, a [001]-oriented PIN-PMN-PT single crystal with a diameter of 3 in was grown by the modified Bridgman method, and a series of single crystal samples within 100 mm of the height of the crystal boule were prepared. Compared with their direct current electric field poling (DCP) counterparts, the electrical properties of single crystal samples at different heights by ACP were regularly enhanced. The piezoelectric coefficient d33 and the dielectric constant ɛ33 of the rhombohedral samples both increased by nearly 20%. Based on the results of polarized light microscopy, the domain wall in [001]-poled ACP samples could not be observed along the [001] direction. The brightness of polarized light propagating along the [010] orientation was enhanced after ACP. The domain images of {100} in the DCP and ACP samples were observed by piezoelectric force microscopy. The results showed that the domain size of ACP samples increased. The existence of layered domains can be clearly found in the scanning electron microscopy results of the stress fracture surface of the ACP sample. According to the analysis, the improvement of the piezoelectric performance in ACP samples comes from the elimination of the 71° domain walls. This work demonstrates that certain ACPs can regulate the domain structure and steadily improve the piezoelectric properties of R-phase PIN-PMN-PT single crystals. [ABSTRACT FROM AUTHOR]

Published

2022