Your search keyword '"Du, Jialun"' showing total 24 results

1. Effect of (Ba 1/3 Nb 2/3) 4+ Substitution on Microstructure, Bonding Properties and Microwave Dielectric Properties of Ce 2 Zr 3 (MoO 4) 9 Ceramics.

Author

Gao, Huamin, Xu, Xiangyu, Liu, Xinwei, Zhang, Xiaoyu, Li, Mingling, Du, Jialun, and Wu, Haitao

Subjects

CERAMIC materials, RIETVELD refinement, DIELECTRIC properties, SPACE groups, X-ray diffraction, CERAMICS

Abstract

In this study, Ce2[Zr1−x(Ba1/3Nb2/3)x]3(MoO4)9 (0.02 ≤ x ≤ 0.1, CZ1−xNx) ceramics were sintered at 600 °C and 700 °C using the traditional solid-state method. An analysis conducted through XRD and Rietveld refinement confirmed that all the CZ1−xNx ceramics displayed a single phase with a trigonal structure (space group R-3c). The observed increases in cell volume with increasing x values indicate the successful substitution of (Ba1/3Nb2/3)4+. The high densification of the synthesized phase was validated by the density and SEM results. Additionally, the P-V-L theory demonstrates a strong correlation between the Ce-O bond and εr, as well as τf, and between the Mo-O bond and Q×f. Notably, the CZ0.98N0.02 ceramics demonstrated superior performance at 675 °C, exhibiting εr = 10.41, Q×f = 53,296 GHz, and τf = −23.45 ppm/°C. Finally, leveraging CZ0.98N0.02 ceramics as substrate materials enabled the design of a patch antenna suitable for the 5G communication band, demonstrating its significant potential in this field. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effects of LiF-Addition on Sintering Behavior and Dielectric Response of LaPO 4 Ceramics at Microwave and Terahertz Frequency for LTCC Applications.

Author

Li, Hu, Wang, Dongfeng, Zhang, Kainan, Guo, Weijia, Xu, Xiaoyu, Zhang, Yanbin, Sun, Yan, Xu, Xingqi, Du, Jialun, Wu, Haitao, Duan, Guangbin, and Yue, Zhenxing

Subjects

DIELECTRIC properties, CERAMICS, TERAHERTZ time-domain spectroscopy, DIELECTRICS, DIELECTRIC materials, MICROWAVES, DIELECTRIC loss

Abstract

This paper reports on the successful preparation of LaPO4-x wt.% LiF (x = 0–5) ceramics using the traditional solid-state reaction method. The crystal structures, sintering behaviors, and dielectric response at microwave and terahertz frequencies were investigated. XRD results indicate that all the diffraction peaks were attributed to LaPO4, and no secondary phase was observed. Rietveld refinement was conducted to analyze the variation of the crystal structure of LaPO4-x wt.% LiF. SEM indicates that the addition of LiF significantly decreased the grain size while increasing the apparent density of the ceramics. When x = 3, the optimum microwave dielectric properties εr = 10.03, Q × f = 81,467 GHz, and τf = −43.79 ppm/°C were achieved in LaPO4-3 wt.% LiF ceramic at 750 °C. The infrared reflectance spectrum and terahertz time-domain spectroscopy were analyzed and compared with the dielectric properties measured at microwave frequency to investigate the inherent dielectric response. The findings indicate that the dielectric constant attributed to ionic displacement polarization and oxygen vacancy is an essential factor affecting dielectric loss. Moreover, it is worth noting that the LaPO4-3 wt.% LiF ceramic demonstrates excellent compatibility with silver powders, suggesting its immense potential as a dielectric material in LTCC applications. [ABSTRACT FROM AUTHOR]

Published

2023

3. A new type of microwave dielectric ceramic based on K2O–SrO–P2O5 composition with high quality factor and low sintering temperature.

Author

Bao, Jian, Du, Jialun, Liu, Lintao, Wu, Haitao, Zhou, Yuanyuan, and Yue, Zhenxing

Subjects

*MICROWAVES, *CERAMICS, *MICROWAVE sintering, *QUALITY factor, *NEAR infrared reflectance spectroscopy, *LOW temperatures, *DIELECTRIC loss, *DIELECTRIC properties

Abstract

A new type of microwave dielectric ceramics with low dielectric loss was fabricated through a traditional solid-phase method. X-ray diffraction and density tests showed that KSrPO 4 ceramics with a single orthorhombic phase could be synthesized and densified at 950 °C, and the crystal structure of KSrPO 4 was further confirmed by Rietveld refinement analysis. The densification temperature of KSrPO 4 was lower than 961 °C, indicating the ceramics could be used in LTCC devices. Additionally, based on the complex chemical bond theory, some internal parameters of KSrPO 4 ceramics were calculated and the effects of these parameters on the properties of KSrPO 4 were systematically analyzed for the first time. Furthermore, the composite dielectric constant and loss of KSrPO 4 ceramics were analyzed by infrared reflectance spectroscopy, and the theoretical loss and the actual loss were compared. Finally, a vector network analyzer was employed to measure the microwave dielectric properties of all samples. The results showed that KSrPO 4 sintered at 950 °C obtain the best microwave dielectric properties, including ε r = 7.85, Q·f = 34,527 GHz (at 10.43 GHz) and τ f = −14.82 ppm/°C. [ABSTRACT FROM AUTHOR]

Published

2022

4. Structure, microwave dielectric properties, and infrared reflectivity spectrum of W6+ substituted Ce2Zr3(MoO4)9 ceramics.

Author

Liu, Lintao, Du, Jialun, Tao, Bingjing, Zhang, Fengqing, and Wu, Haitao

Subjects

*DIELECTRIC properties, *INFRARED spectra, *MICROWAVES, *CERAMICS, *RIETVELD refinement, *PHOSPHORS, *MICROWAVE sintering

Abstract

A series of trigonal system Ce 2 Zr 3 (Mo 1- x W x O 4) 9 (CZM 1- x W x) (0.02 ≤ x ≤ 0.10) ceramics with space group R-3c were fabricated by solid-state synthesis method. The impacts of substituting W6+ for Mo6+ on the apparent morphology, structural parameters, microwave dielectric performances, and crystalline phase composition were comprehensively discussed in the CZM 1- x W x solid solutions. The X-ray diffraction and classical Rietveld refinement were performed to analysis the crystalline structure, which identified that all the as-synthesized CZM 1- x W x ceramic samples only contained a single phase without additional impurities. SEM photographs revealed that clear grain boundaries and well-densified microstructure could be acquired at the optimal temperature of 875 °C for the CZM 1- x W x ceramics. Combined with the extrinsic and intrinsic factors, the reduction of ε r was associated with porosity, ionic polarizability of primitive unit cell and average bond ionicity. The change in Q·f values could be explained by packing fraction and lattice energy of Mo-site. The variation in τ f values were governed by bond valence, bond energy and thermal expansion coefficient of Mo/W–O bond. Besides, the relationship between IR spectra and intrinsic dielectric properties were investigated. In total, the considerable and comprehensive microwave dielectric properties with ε r = 10.27, Q·f = 65,553 GHz (at 9.86 GHz), and τ f = −10.13 ppm/°C were realized at the low temperature of 875 °C for the CZM 1- x W x ceramics with x = 0.04. [ABSTRACT FROM AUTHOR]

Published

2021

5. Effect of adding Sn4+ on crystal structure, sintering behaviors, and microwave dielectric properties of La2Zr3(MoO4)9 ceramics.

Author

Feng, Zhanbai, Xu, Xiaoyu, Du, Jialun, Gong, Pijun, Zhang, Yuping, Wu, Haitao, and Duan, Guangbin

Subjects

*CERAMICS, *DIELECTRIC properties, *CRYSTAL structure, *MICROWAVES, *SINTERING, *X-ray diffraction, *VIBRATION absorption

Abstract

La 2 (Zr 1- x Sn x) 3 (MoO 4) 9 (0.02 ≤ x ≤ 0.10) (LZMS) materials were successfully synthesized to scientifically investigate the effects of Sn4+ addition on phase composition, microstructures, lattice vibration, and dielectric response at microwave frequency. XRD patterns indicate that all samples belong to the trigonal crystal (S.G. R-3c). The crystallite size and lattice strain were analyzed using the Willimson-Hall equation. According to the apparent density and SEM, the LZMS ceramics achieved a dense and homogeneous microstructure when sintered at 700 °C. Analysis of the microwave dielectric properties revealed that the ceramics with x = 0.06 sintered at 700 °C achieved excellent performances (Qf = 75,508 GHz, ε r = 10.18, τ f = −22.21 ppm/°C). The far-infrared reflectance spectrum shows that the theoretical permittivity of the ceramic was mainly from the absorption of phonon vibrations below 400 cm-1. Consequently, the La 2 (Zr 0.94 Sn 0.06) 3 (MoO 4) 9 ceramic has excellent microwave dielectric properties and can be used as a material for 5G communication devices. [ABSTRACT FROM AUTHOR]

Published

2023

6. Effect of (Ba1/3Ta2/3)4+ substitution on microstructure, bonding properties and microwave dielectric properties of zirconium-cerium molybdate ceramics and the fabrication of S-band patch antennas.

Author

Xu, Xiangyu, Du, Wei, Du, Jialun, Sun, Chunshui, Shan, Lianwei, Wu, Haitao, and Zhang, Xiaoyu

Subjects

*CERAMICS, *RIETVELD refinement, *ANTENNAS (Electronics), *PHASE space, *DIELECTRIC properties, *MICROWAVES

Abstract

In this study, Ce 2 [Zr 1 x (Ba 1/3 Ta 2/3) x ] 3 (MoO 4) 9 (CZ 1 x T x , x = 0.01 ∼ 0.1) ceramics were synthesized via the solid-state method at temperatures ranging from 650 °C to 850 °C. XRD and Rietveld refinement analyses revealed that CZ 1 x T x ceramics exhibit a single phase with the space group R 3-c, and the cell volume increases with higher doping content. SEM results indicate that CZ 0.98 T 0.02 ceramics exhibit a highly regular and uniform grain shape. The CZ 0.98 T 0.02 ceramics displayed optimal performance at 800 °C, exhibiting ε r = 10.40, Q × f = 76,893 GHz, and τ f = 14.61 ppm/°C. Additionally, the P-V-L theory was employed to establish correlations between ceramic chemical bonds and performance attributes. The results showed that the Ce-O bond predominantly influences ε r while the Mo-O bond correlates with Q × f and τ f. Furthermore, far-IR reflection spectra unveiled ion displacement polarization as the primary mechanism in CZ 1 x T x ceramics. Finally, based on CZ 0.0.98 T 0.02 ceramics, a patch antenna applicable to the S-band was designed and fabricated, evidencing the vast potential of this ceramic in industrial applications. • The influence of (Ba1/3Ta2/3)4+ ions on Ce2Zr3(MoO4)9 ceramics was studied. • The PVL theory was used to study the chemical bond characteristics of ceramics. • The analysis of the ceramic's lattice vibrations was conducted. • A patch antenna suitable for the S-band was designed and fabricated. [ABSTRACT FROM AUTHOR]

Published

2024

7. Effects of (Cd1/3Sb2/3)4+ co-substitution on the crystal structure, chemical bond characteristics, and microwave dielectric properties of CeO2-ZrO2-MoO3 ceramics.

Author

Wang, Laiguo, Xu, Xiangyu, Zhang, Yiyun, Zhang, Xiaoyu, Du, Wei, Wu, Haitao, Du, Jialun, and Xia, Wangsuo

Subjects

*DIELECTRIC properties, *DIELECTRIC loss, *SPECIFIC gravity, *RIETVELD refinement, *SPACE groups, *CERAMICS

Abstract

In this paper, Ce 2 [Zr 1− x (Cd 1/3 Sb 2/3) x ] 3 (MoO 4) 9 (CZ 1− x (CS) x M, x = 0.01–0.1) were prepared via the conventional solid-state method. XRD and Rietveld refinement analyses confirmed the formation of a single-phase CZ 1− x (CS) x M solid solution with a space group of R -3c(167). The sintering behavior of the samples were investigated using SEM and relative density, which showed that optimal densification for CZ 0.98 (CS) 0.02 M ceramics were achieved at 675 °C with an average grain size of 1.70 μm. The P-V-L theory revealed the significant influence of the Zr(Cd/Sb)-O bond on the dielectric properties of CZ 1− x (CS) x M ceramics. Furthermore, far-IR reflectance spectra indicated that the measured dielectric loss value (1.04 × 10−4) is in line with the calculated value (1.60 × 10−4), suggesting a substantial impact of phonon oscillation absorption on the dielectric properties. Notably, CZ 0.98 (CS) 0.02 M ceramics demonstrated superior performance at 675 °C, with ε r = 10.44, Q × f = 93,152 GHz (at 12.96 GHz), and τ f = −17.73 ppm/°C. [ABSTRACT FROM AUTHOR]

Published

2024

8. Microstructure, bonding characteristics, far-infrared spectra and microwave dielectric properties of co-substituted Ce2[(Zr1-x(Zn1/3Sb2/3)x]3(MoO4)9 ceramics.

Author

Xu, Xiangyu, Xi, Zhangxi, Feng, Zhanbai, Zhang, Xiaohan, Du, Wei, Shan, Lianwei, Du, Jialun, Wu, Haitao, and Wangsuo, Xia

Subjects

*DIELECTRIC properties, *CERAMICS, *RIETVELD refinement, *MICROSTRUCTURE, *MICROWAVES

Abstract

In this contribution, Ce 2 [(Zr 1- x (Zn 1/3 Sb 2/3) x ] 3 (MoO 4) 9 (CZ 1− x (ZS) x) (0 ≤ x ≤ 0.1) ceramics were fabricated using the solid-state reaction method, and the phase composition of the synthesized ceramics was analyzed via XRD and Rietveld refinement. The outcomes revealed that the ceramics, characterized by different x values, constituted a solitary phase with an R-3C space group, and the cell volume demonstrated a decrease with an increase in x value. The examination of the ceramics microwave dielectric characteristics using P–V−L theory reveals that the f i (Ce – O(6)) bond was found to be related to ε r , while Q × f was influenced by the average grain size and U ave. (Mo – O) , and E ave. (Mo – O) and α ave. (Mo – O) were related to the τ f value. The optimal properties were achieved at 750 °C (x = 0.02), resulting in ε r = 10.08, Q × f = 100,954 GHz, τ f = −12.46 ppm/°C. The infrared reflection spectrum analysis revealed that the primary polarization contribution was due to the dielectric response of intrinsic phonons. Additionally, the effects of three different complex ions (Zn 1/2 Sb 2/3)4+, (Zn 1/2 Ta 2/3)4+, and (Zn 1/2 Nb 2/3)4+ doping on the properties of Ce 2 Zr 3 (MoO 4) 9 ceramics were investigated using SEM, packing fraction, and chemical bond analysis. The results showed that (Zn 1/2 Sb 2/3)4+ doping was effective in improving the grain size and apparent density of Ce 2 Zr 3 (MoO 4) 9 ceramics, and the high packing fraction and U (Mo – O) were found to be the primary intrinsic factors for the optimal properties. [ABSTRACT FROM AUTHOR]

Published

2024

9. Crystal structure, infrared-reflectivity spectra, and microwave dielectric properties of novel Ce2(MoO4)2(Mo2O7) ceramics.

Author

Tian, Huanrong, Liu, Lintao, Du, Jialun, Wu, Haitao, Li, MingLing, and Tao, Bingjing

Subjects

*MICROWAVES, *DIELECTRIC properties, *CERAMICS, *CRYSTAL structure, *ANALYTICAL chemistry, *CHEMICAL bonds, *SPECTRUM analysis

Abstract

Novel Ce 2 (MoO 4) 2 (Mo 2 O 7) (CMO) ceramics were prepared by a conventional solid-state method, and the microwave dielectric properties were investigated. X-ray diffraction results illustrated that pure Ce 2 (MoO 4) 2 (Mo 2 O 7) structure formed upon sintering at 600 °C-725 °C. [CeO 7 ], [CeO 8 ], [MoO 4 ], and [MoO 6 ] polyhedra were connected to form a three-dimensional structure of CMO ceramics. Analysis based on chemical bond theory indicated that the Mo–O bond critically affected the ceramics' performance. Furthermore, infrared-reflectivity spectra analysis revealed that the primary polarisation contribution was from ionic polarisation. Notably, the optimum microwave dielectric properties of ε r = 10.69, Q·f = 49,440 GHz (@ 9.29 GHz), and τ f = −30.4 ppm/°C were obtained in CMO ceramics sintered at 700 °C. [ABSTRACT FROM AUTHOR]

Published

2021

10. Effects of Sn substitution on the crystal structures, microstructures, and microwave dielectric properties of Ce2Zr3(MoO4)9 ceramics.

Author

Tian, Huanrong, Jiang, Ling, Du, Jialun, Liu, Lintao, Cong, Hongkun, Zhang, Yiyun, and Wu, Haitao

Subjects

*CERAMICS, *DIELECTRIC properties, *CRYSTAL structure, *SCANNING electron microscopes, *DIFFRACTION patterns, *RIETVELD refinement, *MICROWAVES

Abstract

A series of Ce 2 (Zr 1− x Sn x) 3 (MoO 4) 9 (0.02 ≤ x ≤ 0.1) (CZ 1− x S x M) ceramics were synthesized to investigate the effect of Sn4+ doping on the crystal structure, chemical bond parameters, and dielectric properties of Ce 2 Zr 3 (MoO 4) 9 ceramics. X-ray diffraction patterns illustrated the formation of the single-phase trigonal system solid solution in all samples. Rietveld refinement result showed that the lattice volume decreased linearly, which can be explained by the fact that the effective radius of Sn ion is smaller than that of Zr ion. As the Sn content increased, scanning electron microscope images showed that the CZ 1− x S x M ceramics transformed from bar-like grains to disk-like grains and the grain size declined gradually. The structure–property correlation was estimated by using P–V-L theory; the descending ε r was mainly consistent with the reduced polarizability and total bond ionicity. The Q × f was associated with the lattice energy of the Ce–O1 bond. The change of τ f value was mainly attributed to the bond energy (E Mo1 – O1 and E Mo1 – O4) and the coefficients of thermal expansion (α Mo1 – O1 and α Mo1 – O4). Infrared analysis indicated that the dielectric properties of the CZ 1− x S x M ceramics were primarily ascribed to the absorption of phonon oscillation. Notably, when x = 0.08, outstanding microwave dielectric properties could be achieved, namely, ε r = 10.22, Q × f = 72,390 GHz, τ f = −7.54 ppm/°C. [ABSTRACT FROM AUTHOR]

Published

2021

11. Effects of W6+ on the microstructure, sinterability, lattice vibration, and dielectric properties of Pr2Zr3(Mo1˗xWxO4)9 ceramics at microwave/terahertz/infrared regions.

Author

Feng, Zhanbai, Wang, Gui, Zhang, Xiaohan, Du, Wei, Shan, Lianwei, Wang, Laiguo, Du, Jialun, Wu, Haitao, and Xia, Wangsuo

Subjects

*CERAMICS, *DIELECTRIC properties, *MICROWAVES, *RAMAN spectroscopy, *SPACE groups, *MICROSTRUCTURE, *X-ray diffraction

Abstract

In this article, a series of Pr 2 Zr 3 (Mo 1− x W x O 4) 9 ceramics were prepared using the solid-state reaction method and investigated in terms of phase compositions, lattice stress, lattice vibrations, and dielectric properties at microwave, terahertz, and infrared regions. X-ray diffraction (XRD) analysis revealed that all ceramics possess a trigonal structure (R-3c space group) with no discernible second-phase presence. Moreover, the ceramics exhibit oriented growth along the (0,0,18) crystal plane. The densification of all ceramics occurred within the range of 800–825 °C. Raman spectroscopy exhibited a minor blue shift in the predominant peak as the x value increased. The complex permittivity (ε′ and ε″) were evaluated using both infrared reflectance spectrum and terahertz time-domain (THz-TD) spectroscopy. Interestingly, the THz-TD spectral data exhibited a closer agreement with the measured values, which was attributed to a significant relaxation polarization mechanism. Specifically, the peaks below 400 cm−1 contributed significantly to the dielectric parameters, accounting for 88.4% and 95.7% of ε′ and ε″, respectively. As a result of these findings, it is suggested that Pr 2 Zr 3 (Mo 0.94 W 0.06 O 4) 9 (ε r = 9.82, Qf = 81,892 GHz, τ f = −17.90 ppm/°C) ceramics synthesized at 825 °C hold promise as potential materials for high-frequency communication circuits. [ABSTRACT FROM AUTHOR]

Published

2024

12. Eu3NbO7: Novel middle-dielectric constant microwave dielectric ceramic with monoclinic structure.

Author

Liu, Lintao, Wang, Laiguo, Du, Jialun, Feng, Zhanbai, Wu, Haitao, Zhang, Xiaoyu, and Gong, Pijun

Subjects

*DIELECTRIC properties, *PERMITTIVITY, *DIELECTRIC materials, *CERAMICS, *CHEMICAL bonds, *MICROWAVE materials

Abstract

A new kind of Eu 3 NbO 7 ceramic with a monoclinic structure (C 222 1) had been fabricated using the solid-state method. The X-ray diffraction results confirmed that all samples were pure phase and without secondary phases observed. Dense ceramics achieved in the sintering temperatures range from 1550 °C to 1650 °C and revealed by scanning electron microscopy. The dielectric properties were further investigated using the far-infrared spectrum and chemical bond theory of complex crystals and the results show that the Nb–O bonds with higher lattice energy and coefficient of thermal expansion have the primary contributions to Q × f and τ f. Optimum dielectric characteristics for the sample sintered at 1600 °C, ε r of 43.0, Q × f of 10,953 GHz, and τ f of 27.9 ppm/°C, was achieved. The Eu 3 NbO 7 has enriched the microwave dielectric material systems. [ABSTRACT FROM AUTHOR]

Published

2021

13. Significant improvement on quality factor in Bi3+/Ta5+ codoped Ce2Zr3-3xBi1.5xTa1.5xMo9O36 microwave dielectric ceramics with ultra-low sintering temperatures.

Author

Pan, Hailong, Feng, Zhanbai, Zhang, Yiyun, Du, Wei, Zhang, Xiaohan, Wang, Laiguo, Du, Jialun, Wu, Haitao, Xia, Wangsuo, and Wübbenhorst, Michael

Subjects

*CERAMICS, *MICROWAVES, *QUALITY factor, *ELECTRON density, *SINTERING, *SCANNING electron microscopes, *DIELECTRIC properties

Abstract

Molybdenum oxide-based ceramics have attracted intense interest due to ultra-low sintering temperatures. However, low quality factors (Q × f) hinder their practical applications. Although Q × f can be improved by ions doping, the sintering temperature is greatly increased. Accordingly, it is still a challenge to obtain high Q × f ceramics sintered at ultra-low temperatures (<660 °C). Herein, (Bi 0.5 Ta 0.5)4+ ions are utilized to tackle this issue in the Ce 2 Zr 3 (MoO 4) 9 ceramic as a prototype. Density and scanning electron microscope (SEM) results uncover good sintering states, and X-ray diffraction (XRD) results reveal the formation of solid solutions. Interestingly, the Ce-O bonds exhibit a dominant contribution to the bond ionicity (f i), while Mo-O bonds play an important role in the lattice energy (U), the bond energy (E) and the thermal expansion coefficient (α). The remarkable increase of Q × f can be interpreted by the enhancement of the packing fraction and the mean U of Mo-O bonds. Moreover, the variations of the dielectric constant (ε r) and the temperature coefficient of the resonance frequency (τ f) can be explained by the variations of the intrinsic parameters. More interestingly, a negative correlation between Q × f and τ f is first found. Typically, the CZ 0.98 B 0.02 ceramic sintered at 650 °C exhibits optimum microwave dielectric properties: ε r = 9.92, Q × f = 110,670 GHz, and τ f = −19.20 ppm °C−1. Notably, Q × f of the Ce 2 Zr 2.94 Bi 0.03 Ta 0.03 Mo 9 O 36 (CZ 0.98 B 0.02) ceramic is about 6 times larger than that of the matrix while retaining a low sintering temperature of 650 °C and a low ε r of 9.92, making it a promising candidate for ultra-low temperature cofired ceramics (ULTCC) applications. [ABSTRACT FROM AUTHOR]

Published

2023

14. Correlations between the crystal structure and microwave dielectric properties in Ce2[Zr1-xMx]3(MoO4)9 (M = Mn1/3Nb2/3, Mn1/3Ta2/3) solid-solution ceramics.

Author

Pan, Hailong, Feng, Zhanbai, Zhang, Yiyun, Du, Jialun, Xia, Wangsuo, Wu, Haitao, Tian, Huanrong, and Wübbenhorst, Michael

Subjects

*CERAMICS, *DIELECTRIC properties, *SINTERING, *CRYSTAL structure, *MICROWAVES, *RIETVELD refinement, *THERMAL expansion

Abstract

Ce 2 [Zr 1- x M x ] 3 (MoO 4) 9 (M = Mn 1/3 Nb 2/3 , Mn 1/3 Ta 2/3; x = 0.02, 0.04, 0.06, 0.08 and 0.10) (abbreviated as CZ 1- x N x and CZ 1- x T x) ceramics were prepared through the solid-state reaction method. Effects of (Mn 1/3 Nb 2/3)4+ and (Mn 1/3 Ta 2/3)4+ ions on the sintering characteristics, crystal structures, microwave dielectric properties and infrared vibrational modes were studied in detail. X-ray diffraction (XRD) results reveal the formation of solid solutions for all components. Based on the chemical bond theory and Rietveld refinement, intrinsic structure parameters including the polarizability (P), the packing fraction (P.F.) and the octahedral distortion (Δ octa.), and bond parameters including the lattice energy (U), bond energy (E) and thermal expansion coefficient (α) were calculated. Interestingly, the Ce–O bond plays a major role in the bond ionicity (f i), while Mo–O bond dominates the contributions in the lattice energy (U), bond energy (E) and thermal expansion coefficient (α). In addition, these parameters are used to explain the variations of the microwave dielectric properties of ceramics either changing the doping contents or replacing different ions at x = 0.06. Furthermore, far infrared (FIR) spectra uncover that the phonon modes provide the major polarization contribution of 68.59% in the CZ 0.9 T 0.1 ceramic, implying that the main contribution to ε r stems from the ionic polarization instead of the electronic polarization. Typically, the optimum microwave dielectric properties are achieved for the CZ 0.9 N 0.1 and CZ 0.9 T 0.1 ceramics with ε r = 10.76, Q × f = 85,893 GHz (at 9.52 GHz), τ f = −14.83 ppm °C−1 and ε r = 10.72, Q × f = 87,355 GHz (at 9.81 GHz) and τ f = −8.68 ppm °C−1, respectively. Notably, the CZ 0.9 T 0.1 ceramic has a markedly increased Q × f while maintaining a good τ f = −8.68 ppm °C−1 and a low sintering temperature of 700 °C. [ABSTRACT FROM AUTHOR]

Published

2023

15. Effects of (Cr0.5Ta0.5)4+ on the microstructure, chemical bond characteristics, and dielectric properties of molybdate-based ceramics at microwave and terahertz frequency.

Author

Feng, Zhanbai, Guo, Weijia, Xu, Xiaoyu, Li, Hu, Chen, Yueguang, Zhang, Yuping, Du, Jialun, Wu, Haitao, Duan, Guangbin, and Yue, Zhenxing

Subjects

*DIELECTRIC properties, *CHEMICAL bonds, *CERAMICS, *MICROWAVES, *DIELECTRIC loss, *INFRARED spectra

Abstract

In this study, Ce 2 [Zr 1− x (Cr 0.5 Ta 0.5) x ] 3 (MoO 4) 9 (x = 0.02–0.10) ceramics were synthesized using the solid-state reaction technique, and the crystalline parameters, sintering behaviors, chemical bond characteristics, infrared reflection spectrum, and dielectric response at microwave and terahertz frequency were examined. X-ray diffraction results demonstrated the crystallization of all ceramics in the trigonal structure (R-3c space group), and additional peaks were not detected. The densification point of ceramic was 875 °C. The addition of (Cr 0.5 Ta 0.5)4+ significantly reduced the dielectric loss in the host ceramic. For Ce 2 [Zr 0.96 (Cr 0.5 Ta 0.5) 0.04 ] 3 (MoO 4) 9 , outstanding microwave properties of ε r = 10.66, Qf = 79,436 GHz, and τ f = −19.07 ppm/°C were obtained at 875 °C. The chemical bond characteristics were also parameterized to explore the relationship between Zr(CrTa)–O and microwave properties. Infrared spectral results further indicate that phonon vibrations lower than 400 cm−1 contribute to 80% of the polarization. In our comparison between the infrared spectrum and terahertz time-domain spectrum, we found that the permittivity extracted by the latter is closer to the observed value. [ABSTRACT FROM AUTHOR]

Published

2023

16. The effect of (Mg1/3Ta2/3)4+ on the structure, Raman vibration, Terahertz time domain spectroscopy and dielectric properties for the Li2TiO3 ceramic.

Author

Liu, Lintao, Guo, Weijia, Li, Hu, Liu, Ping, Qin, Shitong, Rong, Xinxin, Liu, Tengteng, Du, Jialun, Zhang, Yuping, Chen, Yueguang, Wu, Haitao, and Yue, Zhenxing

Subjects

*DIELECTRIC properties, *TERAHERTZ spectroscopy, *LITHIUM titanate, *SCANNING electron microscopes, *CERAMICS, *RAMAN spectroscopy

Abstract

The ceramics of Li 2 Ti 1- x (Mg 1/3 Ta 2/3) x O 3 (x = 0.00–0.30) (LTMT x) were fabricated via the solid-phase method. The changes in crystal structure of LTMT x ceramics were confirmed by the X-ray diffraction (XRD). The microstructure of LTMT x ceramics was observed by the scanning electron microscope (SEM). The evolution of crystal structure and vibration for chemical bonds of LTMT x ceramics were studied by Raman spectra. The improvement on quality factors (Q × f values) was related to the weakening of asymmetric vibration in Li–O–Li bond. Based on the THz time domain spectrum (THz-TDS), the polarization mechanism and dielectric properties in THz frequency band were discussed. The satisfactory quality factor (80,005 GHz) was acquired in LTMT 0.15 ceramic, and the best resonant frequency temperature coefficient (τ f) value (0 ppm/°C) was achieved at x = 0.25, which firmly improved the application potential of LTMT x ceramics. [ABSTRACT FROM AUTHOR]

Published

2023

17. Crystal structures, bond characteristics, and dielectric properties of novel middle-εr Ln3NbO7 (Ln = Nd, Sm) microwave dielectric ceramics with opposite temperature coefficients.

Author

Bao, Jian, Guo, Weijia, Kimura, Hideo, Zhang, Yuping, Du, Jialun, Zhou, Yuanyuan, Ma, Yan, Wu, Haitao, and Yue, Zhenxing

Subjects

*DIELECTRIC properties, *CRYSTAL structure, *DIELECTRIC devices, *DIELECTRIC loss, *CERAMICS, *DIELECTRICS

Abstract

This study synthesized two novel middle- ε r Ln 3 NbO 7 (Ln = Nd, Sm; named NNO and SNO) microwave dielectric ceramics through the classic solid-state process. The results of XRD and Rietveld refinement show that NNO and SNO ceramics formed pure phases with the space group Cmcm (63) and C222 1 (20), respectively. The properties of Ln-O and Nb–O bonds of NNO and SNO ceramics were calculated based on the P–V–L theory. The Nb–O bonds positively affect the crystal structure stability of the two ceramics. The optimum microwave dielectric properties were obtained (NNO: ε r = 31.61, Q·f = 6,615 GHz (at 6.10 GHz), and τ f = −455.70 ppm/°C; SNO: ε r = 34.55, Q·f = 11,625 GHz (at 5.77 GHz) and τ f = 72.59 ppm/°C) when the samples sintered at 1550 °C. Notably, SNO ceramic shows a low dielectric loss and medium dielectric constant, and the opposite τ f of NNO and SNO ceramics provide the possibility to fabricate microwave dielectric devices with good temperature stability. [ABSTRACT FROM AUTHOR]

Published

2022

18. Bond characteristics, sintering behavior and microwave dielectric properties of Ce2[Zr1−x(Ca1/3Sb2/3)x]3(MoO4)9 ceramics.

Author

Zhou, Xu, Ji, Xueli, Liu, Lintao, Du, Jialun, Kimura, Hideo, Zhou, Yuanyuan, Yue, Zhenxing, Wen, Jianping, and Wu, Haitao

Subjects

*MICROWAVES, *CERAMICS, *DIELECTRIC properties, *MICROWAVE sintering, *LATTICE constants, *DIFFRACTION patterns, *RIETVELD refinement

Abstract

Ce 2 [Zr 1−x (Ca 1/3 Sb 2/3) x ] 3 (MoO 4) 9 (CZ 1−x (CS) x M) (x = 0.02–0.10) ceramics were prepared by the conventional solid-state reaction method. The correlations between the chemical bond parameters and microwave dielectric properties were calculated and analyzed by using the Phillips–Van Vechten–Levine (P–V–L) theory. Phase composition and microstructures were evaluated by scanning electron microscopy and X-ray diffraction patterns. Lattice parameters were obtained by Rietveld refinements based on XRD data. Excellent properties for Ce 2 [Zr 0.96 (Ca 1/3 Sb 2/3) 0.04 ] 3 (MoO 4) 9 ceramic sintered at 775 °C: ε r = 10.68, Q × f = 85,336 GHz and τ f = −7.58 ppm/°C were achieved. [ABSTRACT FROM AUTHOR]

Published

2022

19. Effects of (Mg1/3Sb2/3)4+ substitutions on the sintering behaviors and microwave dielectric properties of Li2Mg4Zr1−x(Mg1/3Sb2/3)xO7 ceramics.

Author

Liu, Lintao, Wang, Laiguo, Du, Jialun, Feng, Zhanbai, Li, Li, Gong, Yansheng, and Wu, Haitao

Subjects

*MICROWAVES, *DIELECTRIC properties, *MICROWAVE sintering, *CERAMICS, *RIETVELD refinement, *LATTICE constants, *MICROWAVE filters

Abstract

• Li 2 Mg 4 Zr 1–x (Mg 1/3 Sb 2/3) x O 7 (x = 0.10–0.25) microwave dielectric ceramics were prepared. • Rietveld refinement was used to obtain the lattice parameters. • Relationships among intrinsic factors and dielectric properties were investigated. • Li 2 Mg 4 Zr 0.8 (Mg 1/3 Sb 2/3) 0.2 O 7 materials with ɛ r = 12.29, Q×f = 153,140 GHz, and τ f = -17.7 ppm/°C were obtained. ga1 In this work, a series Li 2 Mg 4 Zr 1−x (Mg 1/3 Sb 2/3) x O 7 (x = 0.10–0.25) ceramics were synthesized using the classical solid-state reaction method. The effects of (Mg 1/3 Sb 2/3)4+ in the microstructures, sintering behaviors, and microwave dielectric properties of Li 2 Mg 4 Zr 1−x (Mg 1/3 Sb 2/3) x O 7 ceramics were investigated systematically. XRD analyses indicate that all samples were the rock-salt structure with the Fm -3 m space group, the crystalline parameters were obtained using the Rietveld refinement. Based on the complex chemical bond theory, the effects of inherent features (e.g. bond ionicity, bond energy, and lattice energy) on the dielectric performance of Li 2 Mg 4 Zr 1−x (Mg 1/3 Sb 2/3) x O 7 ceramics were analyzed in details. By adding proper content of (Mg 1/3 Sb 2/3)4+, the optimal dielectric performance of ɛ r = 12.29, Q × f = 153,140 GHz, and τ f = −17.7 ppm/°C were obtained in the Li 2 Mg 4 Zr 0.8 (Mg 1/3 Sb 2/3) 0.2 O 7 materials at 1600 °C for 4 h. The quality factor is more than 100 THz, which indicates that the Li 2 Mg 4 Zr 0.8 (Mg 1/3 Sb 2/3) 0.2 O 7 ceramic is a good candidate for the highly selective filters or microwave resonators. [ABSTRACT FROM AUTHOR]

Published

2021

20. Effects of (Ba1/3Sb2/3)4+ on the structure and dielectric properties of Ce2Zr3(MoO4)9 ceramic at microwave frequency.

Author

Chen, Yueguang, li, Hu, Xu, Xiaoyu, Zhang, Yuping, Du, Jialun, Wu, Haitao, Liu, Lintao, and Duan, Guangbin

Subjects

*MICROWAVES, *DIELECTRIC properties, *CRYSTAL chemical bonds, *LATTICE constants, *CERAMICS, *RIETVELD refinement

Abstract

The single-phase of Ce 2 [Zr 1- x (Ba 1/3 Sb 2/3) x ] 3 (MoO 4) 9 (x = 0.01 ∼ 0.10) (CZBS x M) ceramics were synthesized by the classic solid-state route successfully. The influence of (Ba 1/3 Sb 2/3)4+ replacement for Zr4+ on the lattice parameters, microstructure, chemical bonds and dielectric properties were discussed comprehensively. The X-ray diffraction (XRD) indicated that the CZBS x M ceramics are trigonal-type crystal structure with R-3c space group. The lattice parameters of CZBS x M ceramics were obtained via the Rietveld refinement method. The theory of complex crystals chemical bonds (P-V-L theory) was carried out to study the connections between the chemical bond and dielectric properties. The excellent dielectric properties (ɛ r = 10.71, Q×f = 91,798 GHz and τ f = −15.18 ppm/℃) were obtained at 700 ℃ in CZBS 0.02 M ceramic. [Display omitted] • The effects of (Ba 1/3 Sb 2/3)4+ substitution for Zr4+ on dielectric properties in Ce 2 Zr 3 (MoO 4) 9 was discussed by P-V-L theory. • The Q × f value of Ce 2 Zr 3 (MoO 4) 9 ceramic was increased by more than 3.5 times via doping of (Ba 1/3 Sb 2/3)4+ ions. • The optimum microwave dielectric properties (ɛr = 10.71, Q×f = 91,798 GHz, τf = −15.18 ppm/℃) were obtained at x = 0.02. [ABSTRACT FROM AUTHOR]

Published

2023

21. Crystal structure, Raman spectrum, bond characteristics, and terahertz time-domain spectrum of novel Na5Tm(MoO4)4 microwave dielectric ceramic with ultra-low sintering temperature and high quality factor.

Author

Bao, Jian, Li, Hu, Xu, Xiaoyu, Guo, Weijia, Chen, Yueguang, Zhang, Yuping, Du, Jialun, Wu, Haitao, Duan, Guangbin, and Yue, Zhenxing

Subjects

*QUALITY factor, *RAMAN spectroscopy, *TERAHERTZ materials, *CRYSTAL structure, *CERAMICS, *LATTICE dynamics, *HIGH temperatures

Abstract

This study synthesized a novel Na 5 Tm(MoO 4) 4 (NTM) ceramic through the solid-state process. A single tetragonal phase of NTM ceramic was formed when sintered at 550 ℃—650 ℃. Raman spectrum studied the lattice dynamics information of NTM ceramic. The influence of multiple chemical bonds in NTM ceramic on the crystal stability and dielectric properties was revealed via the Phillips–van Vechten–Levine (P–V–L) theory. Optimal dielectric properties of ε r = 7.66, Q · f = 67,499 GHz (at 10.11 GHz), and τ f = − 58.85 ppm/℃ were achieved in NTM ceramic sintered at 625 ℃. According to the terahertz time-domain spectrum, the dielectric constant of NTM ceramics in the terahertz band is slightly less than that in the microwave band. Furthermore, the ceramic shows good chemical compatibility with Ag powder and is suitable for low temperature co-fired ceramic (LTCC) applications. The ultra-low sintering temperature, low dielectric constant, and low dielectric loss in the microwave and terahertz frequency bands make it an excellent dielectric material for preparing high-frequency wireless communication devices. [Display omitted] • A novel Na 5 Tm(MoO 4) 4 ceramic with good Q · f was prepared. • The terahertz time-domain spectrum of Na 5 Tm(MoO 4) 4 ceramic was studied. • The lattice vibration of Na 5 Tm(MoO 4) 4 ceramic was analyzed. • Effect of bond characteristics on Na 5 Tm(MoO 4) 4 ceramic were discussed. [ABSTRACT FROM AUTHOR]

Published

2023

22. Influence of Ti4+ substitution for Zr4+ on the structure and microwave dielectric properties of Pr2Zr3(MoO4)9 ceramic.

Author

Liu, Lintao, Ji, Xueli, Wu, Haitao, Du, Jialun, Zhou, Yuanyuan, and Yue, Zhenxing

Subjects

*DIELECTRIC properties, *MICROWAVES, *CRYSTAL chemical bonds, *SCANNING electron microscopes, *RIETVELD refinement, *CERAMICS, *MICROWAVE spectroscopy

Abstract

Ceramics with composition of Pr 2 (Zr 1−x Ti x) 3 (MoO 4) 9 (0.02 ≤ x ≤ 0.10) were fabricated by classic solid-phase method. X-ray diffractometer (XRD), Scanning electron microscope (SEM), Raman spectra, FT-IR spectrometer and Agilent vector network analyzer were used to investigate the composition of phase, microscopy, lattice vibration, internal dielectric responding and dielectric properties, respectively. XRD indicates the Pr 2 (Zr 1−x Ti x) 3 (MoO 4) 9 (0.02 ≤ x ≤ 0.10) ceramics own trigonal-type crystal structure and R-3c space group and the SEM patterns confirms the optimal sintering temperature is 800 °C. Simultaneously, the ceramic reached the optimal microwave dielectric properties with ε r = 10.8, Q×f = 81,539 GHz and τ f = −14.2 ppm/°C at 800 °C for x = 0.10. By means of the theory of complex crystals chemical bonds (P-V-L theory), the connections with crystal structure and microwave dielectric properties were deeply discussed. Due to the relatively low fired temperature and superior dielectric properties, there is an expect for Pr 2 (Zr 0.90 Ti 0.10) 3 (MoO 4) 9 ceramic to apply in low temperature cofired ceramic (LTCC). [Display omitted] • Rietveld refinement was used to obtain the cell parameters. • The effects of substitution of Zr4+ by Ti4+ on Pr 2 Zr 3 (MoO 4) 9 ceramics was explored based on the P-V-L theory. • Q·f value has been improved by more than 130% in Pr 2 (Zr 0.90 Ti 0.10) 3 (MoO 4) 9 ceramics. • Optimum microwave dielectric properties (ε r = 10.8, Q×f = 81,539 GHz and τ f = −14.2 ppm/°C) were obtained at 800 °C. [ABSTRACT FROM AUTHOR]

Published

2022

23. Bond characteristics and microwave dielectric properties of (Mn1/3Sb2/3)4+ doped molybdate based low-temperature sintering ceramics.

Author

Tian, Huanrong, Zhou, Xu, Jiang, Tianyu, Du, Jialun, Wu, Haitao, Lu, Yizhong, Zhou, Yuan Yuan, and Yue, Zhenxing

Subjects

*MICROWAVES, *CERAMICS, *DIELECTRIC properties, *SPECIFIC gravity, *SINTERING, *INFRARED spectra, *INFRARED absorption

Abstract

• The sintering temperature of CZ 1− x (MS) x M ceramic was below 900 °C. • Effect of bond characteristics on microwave dielectric properties was discussed. • Infrared reflectivity spectrum was adapted to investigate intrinsic properties. [Display omitted] Ce 2 [Zr 1− x (Mn 1/3 Sb 2/3) x ] 3 (MoO 4) 9 (x = 0.1–1.0) ceramics were prepared by a conventional solid-state method. (Mn 1/3 Sb 2/3)4+ ions occupied the Zr-site, and Ce 2 [Zr 1− x (Mn 1/3 Sb 2/3) x ] 3 (MoO 4) 9 solid solution was obtained. With x value increased, the ε r decreased from 10.47 (x = 0.02) to 10.10 (x = 0.10), which was affected by bond ionicity of Zr/(Mn 1/3 Sb 2/3)1 O4 bond. The Q·f value first increased and then decreased, which was controlled by varying packing fraction, relative density, and lattice energy (Ce O bond). The thermal expansion coefficient and bond energy of Mo O bond were associated with τ f value. Besides, infrared reflection spectrum suggested that the properties were primarily derived from the absorption of phonon in the infrared range. Outstanding microwave dielectric properties of Ce 2 [Zr 0.92 (Mn 1/3 Sb 2/3) 0.08 ] 3 (MoO 4) 9 ceramics were obtained when sintered at 700 °C: ε r = 10.29, Q·f = 91,981 GHz and τ f = −9.81 ppm/°C. [ABSTRACT FROM AUTHOR]

Published

2022

24. Sintering behavior, infrared spectra and microwave dielectric characteristics analysis for Ce2Zr3(MoO4)9 ceramics achieved by reaction-sintering method.

Author

Jiang, Yishan, Chen, Juna, Liu, Lintao, Xu, Ying, Du, Jialun, Tao, Wenhong, Wu, Haitao, and Zhou, Xu

Subjects

*MICROWAVES, *MICROWAVE sintering, *INFRARED spectra, *REFLECTANCE spectroscopy, *DIELECTRIC properties, *CERAMICS, *CHEMICAL bonds

Abstract

Ce 2 Zr 3 (MoO 4) 9 (CZM) ceramics were prepared successfully through the reaction-sintering (RS) method and a single phase was detected in X-ray diffraction patterns. The microstructures of ceramics were observed by a scanning electron microscopy. Based on the results of Rietveld refinement, the influence of chemical bonds parameters on microwave dielectric properties were analyzed by complex chemical bond theory. The lattice vibrational characteristics were investigated by far-infrared reflection spectroscopy. The promising dielectric properties of CZM ceramics were ε r = 10.1, Q×f = 69,705 GHz and τ f = −6.34 ppm/°C, sintered at 850 °C. [Display omitted] • Ce 2 Zr 3 (MoO 4) 9 ceramics were prepared successfully through the reaction-sintering (RS) method. • Microwave dielectric properties were analyzed deeply by complex chemical bond theory and far-infrared reflection spectroscopy. • Effects of the distortion of oxygen octahedral on temperature coefficient of resonant frequency were discussed. [ABSTRACT FROM AUTHOR]

Published

2021