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Research Article | Open Access

A low-firing melilite ceramic Ba2CuGe2O7 and compositional modulation on microwave dielectric properties through Mg substitution

Changzhi YINa,c,Zezong YUb,Longlong SHUbLaijun LIUcYan CHENaChunchun LIa,b,c( )
College of Information Science and Engineering, Guilin University of Technology, Guilin 541004, China
School of Materials Science and Engineering, Nanchang University, Nanchang 330031, China
Guangxi Universities Key Laboratory of Non-Ferrous Metal Oxide Electronic Functional Materials and Devices, College of Material Science and Engineering, Guilin University of Technology, Guilin 541004, China

† Changzhi Yin and Zezong Yu contributed equally to this work.

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Abstract

A melilite Ba2CuGe2O7 ceramic was characterized by low sintering temperature and moderate microwave dielectric properties. Sintered at 960 ℃, the Ba2CuGe2O7 ceramic had a high relative density 97%, a low relative permittivity (εr) 9.43, a quality factor (Q×f) of 20,000 GHz, and a temperature coefficient of resonance frequency (τf) -76 ppm/℃. To get a deep understanding of the relationship between composition, structure, and dielectric performances, magnesium substitution for copper in Ba2CuGe2O7 was conducted. Influences of magnesium doping on the sintering behavior, crystal structure, and microwave dielectric properties were studied. Mg doping in Ba2CuGe2O7 caused negligible changes in the macroscopic crystal structure, grain morphology, and size distribution, while induced visible variation in the local structure as revealed by Raman analysis. Microwave dielectric properties exhibit a remarkable dependence on composition. On increasing the magnesium content, the relative permittivity featured a continuous decrease, while both the quality factor and the temperature coefficient of resonance frequency increased monotonously. Such variations in dielectric performances were clarified in terms of the polarizability, packing fraction, and band valence theory.

References

[1]
T Sebastian. Dielectric Materials for Wireless Communications. Oxford, UK: Elseiver Publishers. 2008.
[2]
MJ Wu, YC Zhang, MQ Xiang. Synthesis, characterization and dielectric properties of a novel temperature stable (1-x)CoTiNb2O8-xZnNb2O6 ceramic. J Adv Ceram 2019, 8: 228-237.
[3]
CC Li, HC Xiang, MY Xu, et al. Li2AGeO4 (A = Zn, Mg): Two novel low-permittivity microwave dielectric ceramics with olivine structure. J Eur Ceram Soc 2018, 38: 1524-1528.
[4]
QB Lin, KX Song, B Liu, et al. Vibrational spectroscopy and microwave dielectric properties of AY2Si3O10 (A = Sr, Ba) ceramics for 5G applications. Ceram Int 2020, 46: 1171-1177.
[5]
D Zhou, LX Pang, DW Wang, et al. High permittivity and low loss microwave dielectric suitable for 5G resonators and low temperature co-fired ceramic architecture. J Mater Chem C 2017, 5: 10094-10098.
[6]
A Ullah, HX Liu, H Hao, et al. Influence of TiO2 additive on sintering temperature and microwave dielectric properties of Mg0.90Ni0.1SiO3 ceramics. J Eur Ceram Soc 2017, 37: 3045-3049.
[7]
ME Song, JS Kim, MR Joung, et al. Synthesis and microwave dielectric properties of MgSiO3 ceramics. J Am Ceram Soc 2008, 91: 2747-2750.
[8]
NH Nguyen, JB Lim, S Nahm, et al. Effect of Zn/Si ratio on the microstructural and microwave dielectric properties of Zn2SiO4 ceramics. J Am Ceram Soc 2007, 90: 3127-3130.
[9]
ZY Zou, XK Lan, WZ Lu, et al. Novel high Curie temperature Ba2ZnSi2O7 ferroelectrics with low-permittivity microwave dielectric properties. Ceram Int 2016, 42: 16387-16391.
[10]
XQ Song, W Lei, MQ Xie, et al. Sintering behaviour, lattice energy and microwave dielectric properties of melilite-type BaCo2Si2O7 ceramics. Mater Res Express 2020, 6: 126322.
[11]
ZY Zou, ZH Chen, XK Lan, et al. Weak ferroelectricity and low-permittivity microwave dielectric properties of Ba2Zn(1+x)Si2O(7+x) ceramics. J Eur Ceram Soc 2017, 37: 3065-3071.
[12]
J Hanuza, M Ma̧czka, M Ptak, et al. Polarized IR and Raman spectra, temperature dependence of phonons and lattice dynamic calculations for M′2M″Ge2O7 pyrogermanates (M′ = Sr, Ba; M″ = Mg, Zn). J Raman Spectrosc 2011, 42: 782-789.
[13]
A Sazonov, V Hutanu, M Meven, et al. Crystal structure of magnetoelectric Ba2MnGe2O7 at room and low temperatures by neutron diffraction. Inorg Chem 2018, 57: 5089-5095.
[14]
CC Li, CZ Yin, JQ Chen, et al. Crystal structure and dielectric properties of germanate melilites Ba2MGe2O7 (M = Mg and Zn) with low permittivity. J Eur Ceram Soc 2018, 38: 5246-5251.
[15]
CZ Yin, Y Tang, JQ Chen, et al. Two low-permittivity melilite ceramics in the SrO-MO-GeO2 (M = Mg, Zn) system and their temperature stability through compositional modifications. J Eur Ceram Soc 2020, 40: 1186-1190.
[16]
YM Lai, H Su, G Wang, et al. Improved microwave dielectric properties of CaMgSi2O6 ceramics through CuO doping. J Alloys Compd 2019, 772: 40-48.
[17]
LX Pang, D Zhou. Microwave dielectric properties of low-firing Li2MO3 (M = Ti, Zr, Sn) ceramics with B2O3-CuO addition. J Am Ceram Soc 2010, 93: 3614-3617.
[18]
YM Lai, XL Tang, X Huang, et al. Phase composition, crystal structure and microwave dielectric properties of Mg2-xCuxSiO4 ceramics. J Eur Ceram Soc 2018, 38: 1508-1516.
[19]
G Wang, DN Zhang, F Xu, et al. Correlation between crystal structure and modified microwave dielectric characteristics of Cu2+ substituted Li3Mg2NbO6 ceramics. Ceram Int 2019, 45: 10170-10175.
[20]
ES Kim, BS Chun, KH Yoon. Dielectric properties of [Ca1-x(Li1/2Nd1/2)x]1-yZnyTiO3 ceramics at microwave frequencies. Mat Sci Eng B 2003, 99: 93-97.
[21]
CZ Yin, HC Xiang, CC Li, et al. Low-temperature sintering and thermal stability of Li2GeO3-based microwave dielectric ceramics with low permittivity. J Am Ceram Soc 2018, 101: 4608-4614.
[22]
WS Kim, ES Kim, KH Yoon. Effects of Sm3+ substitution on dielectric properties of Ca1-xSm2x/3TiO3 ceramics at microwave frequencies. J Am Ceram Soc 2004, 82: 2111-2115.
[23]
F Shi, HL Dong. Vibrational modes and structural characteristics of (Ba(0.3)Sr(0.7))[(Zn(x)Mg(1-x))(1/3)Nb(2/3)]O3 solid solutions. Dalton Trans 2011, 40: 11591-11598.
[24]
A Manan, Z Ullah, AS Ahmad, et al. Phase microstructure evaluation and microwave dielectric properties of (1-x)Mg0.95Ni0.05Ti0.98Zr0.02O3-xCa0.6La0.8/3TiO3 ceramics. J Adv Ceram 2018, 7: 72-78.
[25]
XQ Song, WZ Lu, XC Wang, et al. Sintering behaviour and microwave dielectric properties of BaAl2-2x(ZnSi)xSi2O8 ceramics. J Eur Ceram Soc 2018, 38: 1529-1534.
[26]
HL Pan, L Cheng, HT Wu. Relationships between crystal structure and microwave dielectric properties of Li2(Mg1-xCox)3TiO6 (0 ≤ x ≤ 0.4) ceramics. Ceram Int 2017, 43: 15018-15026.
[27]
RD Shannon. Dielectric polarizabilities of ions in oxides and fluorides. J Appl Phys 1993, 73: 348-366.
[28]
AL Allred. Electronegativity values from thermochemical data. J Inorg Nucl Chem 1961, 17: 215-221.
[29]
ES Kim, BS Chun, R Freer, et al. Effects of packing fraction and bond valence on microwave dielectric properties of A2+B6+O4 (A2+: Ca, Pb, Ba; B6+: Mo, W) ceramics. J Eur Ceram Soc 2010, 30: 1731-1736.
[30]
QW Liao, LX Li, X Ren, et al. New low-loss microwave dielectric material ZnTiNb2O8. J Am Ceram Soc 2011, 94: 3237-3240.
[31]
M Xiao, QQ Gu, ZQ Zhou, et al. Study of the microwave dielectric properties of (La1-xSmx)NbO4 (x = 0-0.10) ceramics via bond valence and packing fraction. J Am Ceram Soc 2017, 100: 3952-3960.
[32]
HL Pan, L Cheng, HT Wu. Relationships between crystal structure and microwave dielectric properties of Li2(Mg1-xCox)3TiO6 (0 ≤ x ≤ 0.4) ceramics. Ceram Int 2017, 43: 15018-15026.
[33]
HS Park, KH Yoon, ES Kim. Relationship between the bond valence and the temperature coefficient of the resonant frequency in the complex perovskite (Pb1-xCax)[Fe0.5(Nb1-yTay)0.5]O3. J Am Ceram Soc 2001, 84: 99-103.
[34]
NE Brese, M O'Keeffe. Bond-valence parameters for solids. Acta Cryst 1991, B47: 192-197.
[35]
ID Brown, D Altermatt. Bond-valence parameters obtained from a systematic analysis of the Inorganic Crystal Structure Database. Acta Cryst 1985, B41: 244-247.
[36]
ES Kim, SH Kim. Effects of structural characteristics on microwave dielectric properties of (1-x)CaWO4-xLaNbO4 ceramics. J Electroceram 2006, 17: 471-477.
[37]
T Joseph, MT Sebastian. Microwave dielectric properties of (Sr1-xAx)2(Zn1-xBx)Si2O7 ceramics (A = Ca, Ba and B = Co, Mg, Mn, Ni). J Am Ceram Soc 2010, 93: 147-154.
[38]
XQ Song, ZY Zou, WZ Lu, et al. Crystal structure, lattice energy and microwave dielectric properties of melilite-type Ba1-xSrxCu2Si2O7 solid solutions. J Alloys Compd 2020, 835: 155340.
[39]
HI Hsiang, CC Chen, SY Yang. Microwave dielectric properties of Ca0.7Nd0.2TiO3 ceramic-filled CaO-B2O3-SiO2 glass for LTCC applications. J Adv Ceram 2019, 8: 345-351.
[40]
J Zhou. Towards rational design of low-temperature co-fired ceramic (LTCC) materials. J Adv Ceram 2012, 1: 89-99.
Journal of Advanced Ceramics
Pages 108-119
Cite this article:
YIN C, YU Z, SHU L, et al. A low-firing melilite ceramic Ba2CuGe2O7 and compositional modulation on microwave dielectric properties through Mg substitution. Journal of Advanced Ceramics, 2021, 10(1): 108-119. https://doi.org/10.1007/s40145-020-0424-3

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Received: 22 June 2020
Revised: 06 September 2020
Accepted: 15 September 2020
Published: 25 November 2020
© The Author(s) 2020

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