A low‐permittivity microwave dielectric ceramic BaZnP₂O₇ and its performance modification

Abstract: The past few decades have witnessed an ever-growing scholarly interest in microwave dielectric ceramics with the rapid development of telecommunication. [1][2][3][4] Recently, there is a strong ongoing search for dielectric ceramics with a dielectric constant (ε r ) less than 15, a low dielectric loss (tan δ = 1/Q), and a near-zero temperature coefficient (τ f ) to meet the demands for microwave substrate applications. 5,6 Although traditional inorganic substrates such as Al 2 O 3 possess excellent dielectric … Show more

“…Appropriate dielectric properties of ceramics are the premise behind the performance and also determine the characteristics of temperature robustness of a metamaterial perfect absorber. [64][65][66][67] Here, the modification of BENT-AG ceramics is done for hightemperature stable perfect absorption. The results of X-ray diffraction (XRD) and scanning electron microscopy (SEM) are presented in the ESI † (in Fig.…”

Perfect absorption based on a ceramic anapole metamaterial

“…Appropriate dielectric properties of ceramics are the premise behind the performance and also determine the characteristics of temperature robustness of a metamaterial perfect absorber. [64][65][66][67] Here, the modification of BENT-AG ceramics is done for hightemperature stable perfect absorption. The results of X-ray diffraction (XRD) and scanning electron microscopy (SEM) are presented in the ESI † (in Fig.…”

Perfect absorption based on a ceramic anapole metamaterial

“…A 2 P 2 O 7 , A 1 A 2 P 2 O 7 (A = Ca, Ba, Sr, Mg, Mn, Zn; A 1 = Ca, Sr, Ba; A 2 = Cu, Zn, Mg), and LiMPO 4 (M = Mg, Zn) [13][14][15][16][17][18][19][20][21][22][23][24][25][26] are some of the hot studied phosphate microwave dielectric ceramics as they possess low dielectric constants, high quality factors, and low sintering temperatures (<950 • C) that meet the LTCC processes. Various reports on LiMPO 4 can be found in the literature, 13,14 and the later studies have mainly focused on ionic substitution to improve the microwave dielectric properties of ceramics [15][16][17][18][19][20] ceramics have superior properties compared to some of the LiMPO 4 ceramics.…”

“…Xie et al 25 initially reported that the microwave dielectric properties of BaZnP 2 O 7 are (ε r = 8.4, Q × f = 27 925 GHz and τ f = −56.7 ppm/ • C). Then Chen et al 26 substituted Mg 2+ for Zn 2+ to improve the microwave dielectric properties of ceramics, and based on the P-V-L theory, the relationship between the chemical bond characteristics and performance was analyzed. The excellent performance was realized for the sample BaZn 0.98 Mg 0.02 P 2 O 7 with ε r = 8.21, Q × f = 84 760 GHz and τ f = −21.9 ppm/ • C. However, as can be seen from previously reported works, there are few relevant studies on the spectral and vibrational properties of BaZnP 2 O 7 .…”

“…initially reported that the microwave dielectric properties of BaZnP 2 O 7 are ( ε r = 8.4, Q × f = 27 925 GHz and τ f = −56.7 ppm/°C). Then Chen et al 26 . substituted Mg 2+ for Zn 2+ to improve the microwave dielectric properties of ceramics, and based on the P–V–L theory, the relationship between the chemical bond characteristics and performance was analyzed.…”

The lattice vibration and microwave dielectric properties of BaZnP_2−xNb_xO₇ ceramics for microwave substrates

“…10 Therefore, controlling the near-stoichiometric ratio of BN elements, reducing crystal defects, and improving BN fiber's crystallization and orientation are beneficial to further increase the fiber strength, thermal stability, and transparent properties. [11][12][13][14] However, according to the previous research on the synthesis of precursor polymers and pyrolysis mechanism, most polyborazine precursors are nitrogen-rich, and a large number of N elements will be excessive in the process of carbon removal in an ammonia atmosphere and crystallization in a nitrogen atmosphere, resulting in the content of boron and nitrogen deviating from stoichiometry. 11,[15][16][17] Thus, many B vacancy defects are produced in the crystallization process, which destroys the crystal structure of the fiber and reduces the strength of the fiber.…”

Nearly stoichiometric BN fiber with high crystallinity achieved by boron trichloride assisted curing process