KNN-based Lead-free Piezoelectric Ceramics Research Articles

High Piezoelectric Performance of KNN-Based Ceramics over a Broad Temperature Range through Crystal Orientation and Multilayer Engineering.

Uninterrupted breakthroughs in the room temperature piezoelectric properties of KNN-based piezoceramics have been witnessed over the past two decades; however, poor temperature stability presents a major challenge for KNN-based piezoelectric ceramics in their effort to replace their lead-based counterparts. Herein, to enhance temperature stability in KNN-based ceramics while preserving the high piezoelectric response, multilayer composite ceramics were fabricated using textured thick films with distinct polymorphic phase transition temperatures. The results demonstrated that the composite ceramics exhibited both outstanding piezoelectric performance (d33~467 ± 16 pC/N; S~0.17% at 40 kV/cm) and excellent temperature stability with d33 and strain variations of 9.1% and 2.9%, respectively, over a broad temperature range of 25-180 °C. This superior piezoelectric temperature stability is attributed to the inter-inhibitive piezoelectric fluctuations between the component layers, the diffused phase transition, and the stable phase structure with a rising temperature, as well as the permanent contribution of crystal orientation to piezoelectric performance over the studied temperature range. This novel strategy, which addresses the piezoelectric and strain temperature sensitivity while maintaining high performance, is well-positioned to advance the commercial application of KNN-based lead-free piezoelectric ceramics.

Giant piezoelectric response and structure evolution of Bi0.5(Na0.3K0.3Li(0.4-x)Bax)0.5ZrO3 modified (K0.48Na0.52)(Nb0.95Sb0.05)O3 lead-free piezoelectric ceramics

The composition of materials can significantly affect the structure and properties of KNN based piezoelectric ceramics. Here, 0.965(K0.48Na0.52)(Nb0.95Sb0.05)O3-0.035Bi0.5(Na0.3K0.3Li(0.4-x)Bax)0.5ZrO3 ceramics were designed and synthesized using CuO as a sintering aid to promote densification of ceramics. The results show that these ceramics had orthorhombic-tetragonal phase transition structure, and the ratio of the two phases becomes an important factor affecting the electrical properties. When the ratio of the two is close, the piezoelectric performance is optimized. Under specific composition, the sample exhibits a large piezoelectric effect, with the piezoelectric constant and inverse piezoelectric constant reaching 347 pC/N and 1052 p.m./V, respectively. These results prove that rational composition and structure modulation can effectively improve the performance of KNN-based lead-free piezoelectric ceramics, making it a promising alternative for lead-based piezoelectric ceramic materials.

BNH doping enhances the piezoelectric properties and temperature stability of KNN-based lead-free piezoelectric ceramics

BNH doping enhances the piezoelectric properties and temperature stability of KNN-based lead-free piezoelectric ceramics

KNN-Based Lead-Free Piezoelectric Ceramics with High Qm and Enhanced d33 via a Donor-Acceptor Codoping Strategy.

The wide application of KNN-based lead-free piezoelectric ceramics is constrained by the contradictory relationship between its mechanical quality factor and piezoelectric constant. From an application point of view, searching for chemical composition with enhanced piezoelectric constant (d33) and mechanical quality factor (Qm) is one of the key points of KNN-based ceramics. In this work, KNN-based ceramics with enhanced d33 and high Qm values were obtained by the solid solution method via a donor-acceptor codoping strategy. The donor dopant Ho3+ enhanced d33 values by refining the domain size, while the acceptor dopant (Cu1/3Nb2/3)4+ improved Qm by the formation of defect dipoles. The composition (KNN-5Ho-4CN) exhibits optimal integrated performances, of which d33, Qm, and TC values are 120 pC/N, 850, and 392 °C, respectively. Moreover, the temperature coefficient of resonant frequency (TCF = -429 ppm/K) indicates that KNN-5Ho-4CN ceramic has good temperature stability. This work provides a new insight for developing KNN-based ceramics with enhanced d33 and high Qm.

Coexistence of excellent piezoelectric performance and high Curie temperature in KNN-based lead-free piezoelectric ceramics

A new KNN-based lead-free piezoelectric material system of (1-x)K0.4Na0.6Nb0.96Sb0.04O3-x(Bi0.45Sm0.05)Na0.5ZrO3 (abbreviated as KNNS-xBSNZ, 0.00 ≤ x ≤ 0.06) is designed to obtain high performance to meet the requirement of next generation electronic devices. The relevant electric properties such as piezoelectricity, strain, and temperature stability are analyzed in detail. An excellent comprehensive property (d33∼508 pC/N, TC∼268 °C) is obtained in ceramic with x = 0.04 through the construction of rhombohedral-orthorhombic-tetragonal (R-O-T) phase boundary. In addition, a good temperature stability of strain for KNNS-0.04BSNZ ceramic is also obtained within the range from room temperature to 175 °C (Suni100°C/SuniRT∼97.81%, Suni150°C/SuniRT∼84.67%), which is comparatively superior to some reported KNN-based ceramics and lead-based ceramics. Therefore, we believe that this new material system would be a promising lead-free candidate for the practical applications.

Research progress of high piezoelectric activity of potassium sodium niobate based lead-free ceramics

Due to excellent piezoelectric properties and electromechanical coupling properties, lead-based piezoelectric ceramics represented by lead zirconate titanate Pb(Zr<sub><i>x</i></sub>Ti<sub>1–<i>x</i></sub>)O<sub>3</sub> (PZT) are widely used in science and technology, industry, military and daily life. However, the content of Pb in PZT-based ceramics exceeds 60% (mass ratio), which will cause serious damage to human ecological environment in the process of their production, use and waste treatment. Therefore, the development of lead-free piezoelectric ceramics has become one of the hot research spots. Potassium sodium niobate (K<sub>0.5</sub>Na<sub>0.5</sub>)NbO<sub>3</sub> (KNN) lead-free piezoelectric ceramics are considered as one of the most promising material systems to substitute for lead-based piezoelectric ceramics because of their good piezoelectric properties and higher Curie temperature. Through many years of researches, the piezoelectric properties of modified KNN based lead-free piezoelectric ceramics have approached to or even exceeded those of some lead-based piezoelectric ceramics. Combining with our relevant work, we comprehensively review the research progress of high piezoelectric activity of KNN based lead-free piezoelectric ceramics, especially focus on the research progress of high-performance potassium sodium niobate lead-free piezoelectric ceramics, preparation technology and related theoretical mechanisms. The future research direction and prospect of KNN-based lead-free piezoelectric ceramics are also presented.

Coexistence of excellent piezoelectric performance and thermal stability in KNN-based lead-free piezoelectric ceramics

With close attention being paid to environmental issues and more legislation coming into force to limit the application of Pb-based materials, accelerating research on lead-free piezoelectric ceramics has become increasingly requisite and urgent. Herein, we have devised and synthesized (1-x)(K0.5Na0.5)0.98Ag0.02(Nb0.96Sb0.04)O3-x(Bi0.5Na0.5)ZrO3 [abbreviated as (1-x)KNANS-xBNZ, x = 0.01, 0.02, 0.03, 0.035, 0.04, 0.045, 0.05, 0.06] Pb-free ceramics. Phase transition, microstructure, electrical properties, and temperature stability of the ceramics have been comprehensively investigated. The findings illustrate that optimizing BNZ content can give rise to a rhombohedral-tetragonal (R-T) phase boundary when x = 0.04, 0.045, 0.05. The specimens with x = 0.04 show improved piezoelectric properties (d33 ~ 440 pC/N, kp ~ 53%, TC ~ 250 °C, d33* ~ 553 pm/V) and good temperature stability. The overall performance is excellent and indicates that (1-x)KNANS-xBNZ ceramics have great potential for replacing their lead-based counterparts.

Temperature dependent fracture toughness of KNN-based lead-free piezoelectric ceramics

The fracture toughness of unpoled and electrically poled lead-free KNN-based piezoelectric ceramics with the composition of 0.92KNN-0.02Bi0.5Li0.5TiO3-0.06BaZrO3 was investigated. Results reveal that at room temperature, the intrinsic fracture toughness (KI0) of the unpoled samples, evaluated by the near-tip crack opening displacement (COD) technique, is the lowest with a value of 0.70 MPa⋅m0.5; the long (through-thickness) crack fracture toughness (KIvnb), obtained by the single edge V-notch beam (SEVNB) technique, is the highest, with a value of 0.95 MPa⋅m0.5; intermediate short surface crack fracture toughness (KIsc) of 0.86 MPa⋅m0.5 was determined by the surface crack in flexure (SCF) technique. These results were rationalized by the toughening behavior of the material combined with the crack geometry-dependent stress intensity evolution during crack propagation. With increasing temperature, KIvnb and KIsc decrease, and become nearly identical at 350 °C, suggesting an absence of toughening. For electrically poled samples, their room temperature fracture toughness was characterized by both SCF and SEVNB techniques, with values of 0.88 MPa⋅m0.5 and 0.99 MPa⋅m0.5, respectively, slightly larger than the values measured for unpoled samples. Nonlinear electric field-strain and stress-strain analysis of the material was also employed during electric field loading, mechanical compression and four-point bending in order to quantify crack tip shielding by domain switching and the actual stress at the point of instable crack propagation.

Giant strain response with low hysteresis in potassium sodium niobate based lead-free ceramics

Abstract In this work, the relationships between the composition-driven phase boundary, ferroelectricity and strain properties of the (1- x )(K 0.48 Na 0.52 )(Nb 1- y Sb y )O 3 - x Bi 0.5 (Na 0.82 K 0.18 ) 0.5 ZrO 3 (abbreviated as (1- x )KNN 1- y S y - x BNKZ) ceramics were investigated. A giant electric field-induced strain of 0.3% ( d 33 ∗ = 750 p.m./V) and a low hysteresis (16.4%) were obtained in the 0.97KNN 0.98 S 0.02 -0.03BNKZ ceramics. The giant strain is attributed to the enhanced piezoelectricity induced by the appearance of the O-T phase boundary and the electric-field-induced phase transition from the relaxor phase to the ferroelectric phase. Furthermore, the 0.97KNN 0.98 S 0.02 -0.03BNKZ ceramics exhibit good thermal stability in the temperature range from 25 °C to 150 °C. Hence, this work can promote the practical applications of KNN-based lead-free piezoelectric ceramics in highly sensitive and precise piezoelectric actuators.

Polarization switching and rotation in KNN-based lead-free piezoelectric ceramics near the polymorphic phase boundary

(K,Na)NbO3 (KNN)-based ceramics have attracted considerable attention owing to their excellent piezoelectric performance in the polymorphic phase boundary (PPB); however, many researchers have found that the optimal composition usually appears on the tetragonal side near the PPB zone. In this study, it is found that the maximum piezoelectric performance is achieved in the PPB region for unpoled ceramics due to the more efficient and facile polarization switching. However, the most outstanding piezoelectricity shifts to the tetragonal side after the ceramics are poled. Raman spectra and first-principles calculations reveal the occurrence of a phase transformation from a tetragonal to monoclinic structure under an external electric field. Hence, the unpoled tetragonal ceramics transform to a two-phase coexistence condition after the poling process and exhibit the best electrical properties driven by the combined effects of polarization switching and rotation. This study reveals that the electric-field-induced phase transformation leads to the optimal composition on the tetragonal side, and this can provide useful guidance for the design of high-performance KNN-based materials.

Structure and properties of (K0.5Na0.5)0.98Ag0.02Nb0.96Ta0.04O3 piezoelectric ceramics doped by CuO

Low-temperature sintering technology can control the volatilization of sodium and potassium ions during high-temperature preparation to obtain excellent physical properties of ceramics. In this research, we used the traditional ceramic preparation technology. KNN-based lead-free piezoelectric ceramics were prepared for the first time at home and abroad by using CuO and Na2O as collective additives under low sintering temperature (1020 °C) conditions. X-ray diffraction, scanning electron microscopy, and other modern test analyses show that KNANTC ceramics can form a pure perovskite structure of tetragonal phase in the total research range when 0.01 mol Na2O is used as a supplement to the A position of KNN piezoelectric ceramics. A moderate amount of CuO doping can simultaneously enhance liquid-phase sintering, promote grain growth, improve the density of ceramics, and achieve excellent electrical properties. The test results of KNANTC piezoelectric ceramics show good electrical properties when x = 0.035, that is, d33 = 343 pC/N, kp = 49%, er = 1382, tan δ = 1.1%, Pr = 24.9 µC/cm2, EC = 1.92 kV/mm, and Tc = 306 °C. These results indicate that KNANTC-x is a promising lead-free piezoelectric ceramic material that can gradually replace the traditional PZT-based piezoelectric ceramics in the future.

Structure and electrical properties of SrZrO3-modified (K,Na,Li)(Nb,Ta)O3 lead-free piezoelectric ceramics

In this work, SrZrO3 was used as a dopant for KNN-based lead-free piezoelectric ceramics with composition of (K0.49Na0.49Li0.02)(Nb0.8Ta0.2)O3 (denoted by KNLNT) to optimize their piezoelectric and dielectric properties. SrZrO3-modified KNLNT lead-free piezoelectric ceramics were synthesized via a conventional solid-state method. The effects of doping on crystal structure, ferroelectric properties, dielectric properties and piezoelectric properties were systematically investigated. The transformation of the crystal structures of the ceramics from orthorhombic to tetragonal has been monitored and the coexistence of orthorhombic and tetragonal phases has been identified with the range of 0.01–0.03 for the doping SrZrO3. The doping of SrZrO3 was found to be effective in reducing the grain sizes and lowering the orthorhombic–tetragonal phase transition point temperature (T O−T) and Curie temperature (T C) in SrZrO3-modified KNLNT ceramics. The optimized content of SrZrO3 is 0.02, in which the maximum d 33 of 156 pC/N can be obtained, corresponding to the disappearance of T O–T and T C of 252.5 °C.

Dependence of Crystal Structure and Electronic Structures, Dielectric and Piezoelectric Properties on Composition for (K, Na)NbO3-(Bi, Na)TiO3

INTRODUCTION Lead zirconate titanate (PZT)-based piezoelectric ceramics have been widely used in actuators, sensors and other electric devices, owing to their outstanding electrical properties. However, their raw materials containing PbO cause serious harm to human health and environment, and thus it is an important issue to develop lead-free piezoelectric materials for the replacement of these lead-based ceramics. (K, Na)NbO3-based ceramics is considered to be one of the most promising lead-free piezoelectric ceramics1), but problems such as volatilization of alkali metals, inferior sinterability and lower electrical properties than PZT are pointed out. In order to improve the piezoelectric properties of (K, Na)NbO3(KNN), some previous works prepared solid solutions of KNN-based lead-free piezoelectric ceramics with another perovskite oxide. In this study, we focused on a substitution effect of (Bi0.5Na0.5)TiO3(BNT) which induce tetragonal structure for (K0.45Na0.55)NbO3 (KNN), and synthesized (K, Na)NbO3-(Bi, Na)TiO3 by the solid-state reaction method using the spark plasma sintering. We compared ferroelectric properties with crystal and electronic structure obtained by the Rietveld analysis using synchrotron X-ray diffraction data. EXPERIMENTAL Starting materials were wet-mixed in appropriate proportions, and then calcined at 900 ℃ in air for 3 h (KNN), and at 850 ℃ in air for 3 h (BNT), respectively. Thereafter, the samples were grounded by a ball mill and then sintered by the spark plasma sintering (SPS) method under an uniaxial pressing at 50 MPa at 1050 ℃ in vacuum for 5 min. For the obtained products, an annealing treatment was performed at 950 ℃ in O2 for 6 h. The identification of the phases and the evaluation of the lattice parameters were performed by XRD. Metal compositions of the ceramics were measured by ICP. Relative densities of the pellets were estimated by the Archimedes method. P-E hysteresis loop measurements were carried out at various frequencies using a TF-2000FE device (aixACCT) with the virtual ground mode. The surface and cross-section morphologies of the samples were observed by SEM. The temperature dependences of the dielectric permittivity (εs ) and dielectric losses (tanδ) of the samples were measured by a LCR meter (HP-4284A). For average crystal structure analysis, we performed the Rietveld analysis (RIETAN-FP) using synchrotron X-ray diffraction patterns (BL19B2, SPring-8). The electron densities were determined by the maximum entropy method (MEM, Dysnomia program). For local crystal structure analysis, we measured X-ray absorption fine structure (XAFS) patterns (BL14B2, SPring-8) and then performed EXAFS fitting (Athena, Artemis) of a first coordination shell of Nb. RESULTS AND DISCUSSION (1-x)(K0.45Na0.55)NbO3-x(Bi0.5Na0.5)TiO3 (x=0~0.07) could be identified as the perovskite structures with the tetragonal (P4mm) and/or the orthorhombic (Amm2) symmetries without impurity phases. It was found that all of the sample were sufficiently dense by the Archimedes method and the observation by SEM. From P-E hysteresis loop measurements, it was demonstrated that the remanent polarization P r decreased by substitution of BNT. Relative dielectric constant and the Curie temperature (T c) declined with the replacement of BNT. Therefore, it can be considered that BNT substitution has unfavorable influence on the ferroelectric property. In order to clarify an origin of such changes in the electrical properties, crystal structures and electron density distributions of the samples were analyzed. From the crystal structure analysis by the Rietveld method, it was found that the morphotropic phase boundary (MPB) existed around the composition of x=0.04 in the 1-x(K0.45Na0.55)NbO3-x(Bi0.5Na0.5)TiO3. We also calculated octahedral distortions of λ and σ2 from bond lengths and angles, respectively. These values tended to decrease due to BNT substitutions, and such a tendency corresponded to the change in the ferroelectric properties. From the electron density distribution obtained by MEM, it was considered that the electron density between (Nb, Ti) site and O1 site decreased due to BNT substitutions, leading to a decrease in the Curie temperature T c. Analysis of the local crystal structure by EXAFS fitting indicated longer bond distance between Nb and O2 compared with KNN by BNT substitution which could not be seen from the average structure analysis. REFERENCE 1) Y. Saito, et al., Nature, 432, 84 (2004). Figure 1

Influence of B-site non-stoichiometry on electrical properties of (K0.458Na0.542)0.96Li0.04Nb0.85Ta0.15Sb x O3 ceramics

In the study, B-site non-stoichiometric (excess) lead-free (K0.458Na0.542)0.96Li0.04Nb0.85Ta0.15Sb x O3 (KNLNS x T) ceramics were prepared by conventional mixed oxide method. The results indicate that excess Sb in an amount of ≤0. 5 mol% can diffuse into the lattice of the KNLNT ceramics and form the pure perovskite phase. The Sb excess ceramics show decreased ferroelectric properties due to the partial substitution of Sb3+ for B-site ions. The deviation of Sb from chemical stoichiometry can distinctly influence electrical properties of KNLNT ceramics. Enhanced piezoelectric activity is observed in the ceramics with a 0.5 mol% excess of Sb. The work has shown the necessity of adequately controlling B-site non-stoichiometry of KNN-based lead-free piezoelectric ceramics in obtaining the desired electrical properties.

Phase structure and electrical properties of Yb and Mn co-substituted (K0.48Na0.52)NbO3 lead-free piezoelectric ceramics

Rare-earth and Mn co-substituted KNN-based lead-free piezoelectric ceramics and (1−x)(K0.48Na0.52)NbO3–xYbMnO3 (KNN–xYM) were prepared by a conventional solid-state sintering method. The effects of YM addition on the structure, dielectric, and piezoelectric properties of KNN–xYM ceramics were systematically investigated. With increase of YM content, from the rhombohedral to orthorhombic transition temperature (TR–O) moves close to room temperature against the direction of the orthorhombic to tetragonal transition temperature (TO–T). A polymorphic phase transitions (PPT) between rhombohedral and orthorhombic phases exists at x∼0.01 and the optimum electrical characterization (d33∼140pC/N, kp∼0.42, Qm∼214, εr∼634, tanδ∼0.02, and Tc∼386°C) is also given to the compositions (x=0.01) around PPT. In addition, KNN–xYM ceramics became a relaxor ferroelectric gradually with increasing YM content. These results indicate that the enhanced piezoelectric properties can be achieved based on the coexistence of rhombohedral and orthorhombic phases.

Piezoelectric Properties of (1-x)(K0.52Na0.48)1-x Li x NbO3-x (Bi0.5Na0.5)0.9Ca0.1TiO3 with Higher Curie Temperature

The polymorphic phase transition (PPT) near room temperature can induce enhanced electrical properties of KNN-based lead-free piezoelectric ceramics, limiting their temperature stability. In this paper, the 0.98(K0.52Na0.48)1-x Li x NbO3–0.02(Bi0.5Na0.5)0.9 Ca0.1TiO3 (KNLN x -BNCT) lead-free piezoelectric ceramics were prepared by the conventional sintering technique, and the electrical properties and phase structure can be tailored by modifying Li content. The polymorphic phase transition (PPT) from orthorhombic and tetragonal phase around room temperature was identified in the composition range 0.01 ≤ x ≤ 0.02, resulting in improved electrical properties (d 33∼262 pC/N, k p ∼ 0.36, ϵ r ∼ 715, and tan δ∼ 0.03). Moreover, KNLN x -BNCT (x0.02) ceramics with tetragonal structure possess a pertinent temperature stability and a broader application range owing to its higher T C (>400°C).

PROGRESSES AND FURTHER CONSIDERATIONS ON THE RESEARCH OF PEROVSKITE LEAD-FREE PIEZOELECTRIC CERAMICS

The research on lead-free piezoelectric ceramics has been one of the important fields worldwide for years for the sustainable development of the world. In recent years, the author and his group concentrated their work on perovskite lead-free piezoelectric ceramics, especially on ( Bi 1/2 Na 1/2) TiO 3 ( BNT )- and K 1/2 Na 1/2 NbO 3 ( KNN )-based ceramics. In this paper, the researches of the composition design on BNT- and KNN-based lead-free piezoelectric ceramics, the effects of doping on the properties of these ceramics, the study of the temperature stability of these ceramics, and the fabrication technique used in the author's group for these ceramics are reviewed, and the further considerations and some prospects to be resolved in coming years from the viewpoint of the device applications of these ceramics are suggested.

Study on the sintering mechanism of KNN-based lead-free piezoelectric ceramics

The sintering process and mechanism of (K, Na, Li) (Nb, Ta, Sb)O3 (KNLNTS) solid solution were investigated. The results show that the KNLNTS forms via the reaction of A2CO3(A: K,Na,Li) and B2O5(B: Nb,Ta,Sb) at 400–800 °C. The kinetics for the formation of KNLNTS during solid-state reaction is investigated using an isothermal method. Based on the reaction kinetic isothermal analysis, KNLNTS formation is corroborated as being controlled by diffusion mechanism. It has been found that sintering densification occurs within a narrow temperature range, and the density decreases apparently when the sintering temperature slightly exceeds the optimal one. Abnormal grain growth tends to occur after reaching the maximum density and get intensified with increasing temperature. The effect of sintering temperature and time on the shrinkage of powder compacts during sintering were studied. The sintering process in the KNLNTS solid solutions may be explained by the grain boundary diffusion model inferring from the shrinkage rate of about 0.3.

Effect of Doping Ions on the Properties of KNN-Based Lead-Free Piezoelectric Ceramics

Different ions modified (K0.5Na0.5)NbO3(KNN)-based lead free piezoelectric ceramics were prepared by conventional mixed oxide ceramic processing. The roles of different doping ions, at the A or B sites of perovskite structure of KNN, on the properties of KNN-based ceramics were analyzed. The XRD analysis and dielectric spectra measurement show that the dopant at B site of perovskite structure has more significant influence on the stability of the crystal structures of KNN-based ceramics. Some prospects to be resolved in coming years from the viewpoint of the actual applications are pointed out.

Miniature Ultrasonic Motor Using Shear Mode of Potassium Sodium Niobate-Based Lead-Free Piezoelectric Ceramics

A miniature piezoelectric ultrasonic motor (USM) using the shear mode of (K,Na)NbO3 (KNN)-based lead-free piezoelectric ceramics was developed. The motor can be driven in the shearing and bending vibration modes. By using the finite-element method, the motor vibration modes and driving mechanism were modeled. Both the “soft-type” (high-d USM) and “hard-type” (high-Qm USM) KNN-based lead-free piezoelectric ceramics were employed to clarify the characteristics of USMs. The experimental results reveal that the high-d USM widens the band of operational frequency in both vibration modes. In the shearing vibration mode, the high-d USM showed a revolution speed of 416 rpm, a torque of 41.5 µN m, and an efficiency of 0.6%, whereas the high-Qm USM showed the same characteristics of 313 rpm, 19.6 µN m and 1.6%, respectively. In the bending vibration mode, the characteristics of the high-Qm USM were 376 rpm, 51.4 µN m and 0.4%; however, the characters of the high-d USM deteriorated owing to the shift in resonance frequency caused by heat generation.