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Your search keyword '"Wang, Chang‐Hao"' showing total 4 results
Start Over Author "Wang, Chang‐Hao" Journal journal of the american ceramic society
4 results on '"Wang, Chang‐Hao"'

1. Microwave dielectric properties of (Na0.5Bi0.5)MoO4–BaMoO4 composite ceramics with ultralow sintering temperature.

Author

Alzakree, Ahmed Redwan Hazaa, Wang, Chang‐Hao, Shehbaz, Muhammad, Wang, Wei, Xu, Di‐Ming, Du, Chao, and Zhou, Di

Subjects
*CERAMICS, *MICROWAVE sintering, *DIELECTRIC properties, *MICROWAVES, *DIELECTRIC resonator antennas, *SINTERING, *ANTENNA design, *SCANNING electron microscopy
Abstract

The rapidly ever‐growing wireless communication demands development of low loss, ultralow sintering temperature dielectric ceramics with excellent microwave properties. In this work, fabrication and properties of novel microwave dielectric composite ceramics (1 − x)(Na0.5Bi0.5)MoO4–xBaMoO4 (x = 0.3–0.6), in short as ((1 − x)NBM–xBM), synthesized via solid‐state reaction method with an ultralow sintering temperature is reported. X‐ray diffraction analysis confirms the coexistence of both (Na0.5Bi0.5)MoO4 and BaMoO4 scheelite phases. Scanning electron microscopy analysis demonstrated dense microstructures of ceramics sintered at 650°C and 700°C. The dielectric properties of (1 − x)NBM–xBM (x = 0.3–0.6) ceramic are significantly tailored by incorporation of BaMoO4. With the increase in x from 0.3 to 0.6, the (1 − x)(Na0.5Bi0.5)MoO4–xBaMoO4 displays noticeable change in microwave permittivity εr${\varepsilon }_r$ (varying from 25.4 to 16.6), quality factor (Q×f)$(Q \times f)$ values, and temperature coefficient of frequency (τf)$({\tau }_f)$ (range tunable from +37.6 ppm/°C to −14.2 ppm/°C). The microwave dielectric ceramic, 0.5(Na0.5Bi0.5)MoO4–0.5BaMoO4, has optimum dielectric properties (εr=19.02${\varepsilon }_{\mathrm{r}} = 19.02$, Q×f$Q \times f$ = 15 164 GHz, τf = −0.2 ppm/°C) at sintering temperature of 650°C. The dielectric resonator antenna designed using (1 − x)(Na0.5Bi0.5)MoO4–xBaMoO4 ceramics demonstrated excellent radiation performance at resonance frequency of 5.905 GHz, gain of ∼5.8 dBi and 140 MHz bandwidth, which validates its microwave applications utilization within the field of ultralow temperature cofired ceramics technology. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Crystal structure and microwave dielectric properties of temperature stable (CoxZn1–x)TiNb2O8 ceramics.

Author

Jiang, Jia‐Pei, Zhou, Di, Wang, Wei, Wang, Chang‐Hao, Shi, Zhong‐Qi, Liu, Wen‐Feng, Zhou, Tao, Chen, Ya‐Wei, Liang, Qi‐Xin, and Zhang, Mei‐Rong

Subjects
CERAMICS, MICROWAVES, DIELECTRIC properties, CRYSTAL structure, X-ray powder diffraction, PERMITTIVITY, QUALITY factor
Abstract

(CoxZn1–x)TiNb2O8 (x = 0.2–0.8) microwave dielectric ceramics were synthesized via the conventional solid‐state reaction route, and the correlation of microwave dielectric properties on the crystal structure was discussed. Crystal structures of ceramic samples were systematically investigated by X‐ray powder diffraction. Moreover, composition‐induced phase transitions were confirmed via the following sequence: for x ≤ 0.2, single‐phase orthorhombic ixiolite (ZnTiNb2O8) was formed, whereas for 0.3 ≤ x<0.8, ixiolite and rutile coexisted. When x ≥ 0.8, only single‐phase rutile was detected. For the (CoxZn1–x)TiNb2O8 ceramics, the microwave dielectric properties were changed with the crystal structural transitions: the dielectric constant (εr) and the temperature coefficient of resonant frequency (τf) increased upon increasing the Co2+, but the quality factor (Q) decreased. A near‐zero τf = +1.6 ppm/°C was obtained in the Co0.38Zn0.62TiNb2O8 ceramics with εr = 40.7 and high Q × f = 16 790 GHz. These research outcomes are expected to have great significance for developing microwave dielectric ceramics in practical applications. [ABSTRACT FROM AUTHOR]

Published
2023
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