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1. Coherent Precipitates with Strong Domain Wall Pinning in Alkaline Niobate Ferroelectrics

   https://doi.org/10.1002/adma.202202379  

   Zhao, Changhao; Gao, Shuang; Kleebe, Hans‐Joachim; Tan, Xiaoli; Koruza, Jurij; Rödel, Jürgen (August 2022, Advanced Materials)

   Abstract High‐power piezoelectric applications are predicted to share approximately one‐third of the lead‐free piezoelectric ceramic market in 2024 with alkaline niobates as the primary competitor. To suppress self‐heating in high‐power devices due to mechanical loss when driven by large electric fields, piezoelectric hardening to restrict domain wall motion is required. In the present work, highly effective piezoelectric hardening via coherent plate‐like precipitates in a model system of the (Li,Na)NbO₃(LNN) solid solution delivers a reduction in losses, quantified as an electromechanical quality factor, by a factor of ten. Various thermal aging schemes are demonstrated to control the average size, number density, and location of the precipitates. The established properties are correlated with a detailed determination of short‐ and long‐range atomic structure by X‐ray diffraction and pair distribution function analysis, respectively, as well as microstructure determined by transmission electron microscopy. The impact of microstructure with precipitates on both small‐ and large‐field properties is also established. These results pave the way to implement precipitate hardening in piezoelectric materials, analogous to precipitate hardening in metals, broadening their use cases in applications. 

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2. Substrate Dependence of the Self-heating in Lead Zirconate Titanate (PZT) MEMS Actuators

   https://doi.org/10.1063/5.0204385  

   Song, Yiwen; Kang, Kyuhwe; Tipsawat, Pannawit; Cheng, Christopher Y.; Zhu, Wanlin; LaBella, Michael; Choi, Sukwon; Trolier-McKinstry, Susan E. (April 2024, Journal of Applied Physics)

   Lead zirconate titanate (PZT) thin films offer advantages in microelectromechanical systems (MEMSs) including large motion, lower drive voltage, and high energy densities. Depending on the application, different substrates are sometimes required. Self-heating occurs in the PZT MEMS due to the energy loss from domain wall motion, which can degrade the device performance and reliability. In this work, the self-heating of PZT thin films on Si and glass and a film released from a substrate were investigated to understand the effect of substrates on the device temperature rise. Nano-particle assisted Raman thermometry was employed to quantify the operational temperature rise of these PZT actuators. The results were validated using a finite element thermal model, where the volumetric heat generation was experimentally determined from the hysteresis loss. While the volumetric heat generation of the PZT films on different substrates was similar, the PZT films on the Si substrate showed a minimal temperature rise due to the effective heat dissipation through the high thermal conductivity substrate. The temperature rise on the released structure is 6.8× higher than that on the glass substrates due to the absence of vertical heat dissipation. The experimental and modeling results show that the thin layer of residual Si remaining after etching plays a crucial role in mitigating the effect of device self-heating. The outcomes of this study suggest that high thermal conductivity passive elastic layers can be used as an effective thermal management solution for PZT-based MEMS actuators. 

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3. Failure Mechanisms of Lead Zirconate Titanate Thin Films during Electromechanical Loading

   Coleman, Kathleen; Walker, Julian; Zhu, Wanlin; Ko, Song Won; Trolier-McKinstry, Susan (July 2020, 2020 JOINT CONFERENCE OF THE IEEE INTERNATIONAL FREQUENCY CONTROL SYMPOSIUM AND INTERNATIONAL SYMPOSIUM ON APPLICATIONS OF FERROELECTRICS (IFCS-ISAF))

   null (Ed.)

   Understanding the failure mechanisms of piezoelectric thin films is critical for the commercialization of piezoelectric microelectromechanical systems. This paper describes the failure of 0.6 mu m lead zirconate titanate (PZT) thin films on Si wafers with different in-plane stresses under large electric fields. The films failed by a combination of cracking and thermal breakdown events. It was found that the crack initiation and propagation behavior varied with the stress state of the films. The total stress required for crack initiation was estimated to be near 500 MPa. As expected, cracks propagated perpendicular to the maximum tensile stress direction. Thermal breakdown events and cracks were correlated, suggesting coupling between electrical and mechanical failure. It was also found that films that were released from the underlying substrates were less susceptible to failure by cracking. It was proposed that during electric field loading the released film stacks were able to bow and alleviate some of the stress. Released films may also experience enhanced domain wall motion that increases their fracture toughness. The results indicate that both applied stress and clamping conditions play important roles in the electromechancial failure of piezoelectric thin films. 

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4. Reliability of piezoelectric films for MEMS

   https://doi.org/10.35848/1347-4065/acf5f8  

   Trolier-McKinstry, Susan; Zhu, Wanlin; Akkopru-Akgun, Betul; He, Fan; Ko, Song Won; Fragkiadakis, Charalampos; Mardilovich, Peter (September 2023, Japanese Journal of Applied Physics)

   Abstract Thin films based on PbZr_1−xTi_xO₃and K_1−xNa_xNbO₃are increasingly being commercialized in piezoelectric MEMS due to the comparatively low drive voltages required relative to bulk actuators, as well as the facile approach to making sensor or actuator arrays. As these materials are incorporated into devices, it is critically important that they operate reliably over the lifetime of the system. This paper discusses some of the factors controlling the electrical and electromechanical reliability of lead zirconate titanate (PZT)-based piezoMEMS films. In particular, it will be shown the gradients in the Zr/Ti ratio through the depth of the films are useful in increasing the lifetime of the films under DC electrical stresses. 

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5. Ferroelectric Domain Wall Engineering Enables Thermal Modulation in PMN–PT Single Crystals

   https://doi.org/10.1002/adma.202211286  

   Negi, Ankit; Kim, Hwang Pill; Hua, Zilong; Timofeeva, Anastasia; Zhang, Xuanyi; Zhu, Yong; Peters, Kara; Kumah, Divine; Jiang, Xiaoning; Liu, Jun (April 2023, Advanced Materials)

   Abstract Acting like thermal resistances, ferroelectric domain walls can be manipulated to realize dynamic modulation of thermal conductivity (k), which is essential for developing novel phononic circuits. Despite the interest, little attention has been paid to achieving room‐temperature thermal modulation in bulk materials due to challenges in obtaining a high thermal conductivity switching ratio (k_high/k_low), particularly in commercially viable materials. Here, room‐temperature thermal modulation in 2.5 mm‐thick Pb(Mg_1/3Nb_2/3)O₃–xPbTiO₃(PMN–xPT) single crystals is demonstrated. With the use of advanced poling conditions, assisted by the systematic study on composition and orientation dependence of PMN–xPT, a range of thermal conductivity switching ratios with a maximum of ≈1.27 is observed. Simultaneous measurements of piezoelectric coefficient (d₃₃) to characterize the poling state, domain wall density using polarized light microscopy (PLM), and birefringence change using quantitative PLM reveal that compared to the unpoled state, the domain wall density at intermediate poling states (0<d₃₃<d_33,max) is lower due to the enlargement in domain size. At optimized poling conditions (d_33,max), the domain sizes show increased inhomogeneity that leads to enhancement in the domain wall density. This work highlights the potential of commercially available PMN–xPT single crystals among other relaxor‐ferroelectrics for achieving temperature control in solid‐state devices. 

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