Hao, Shu-ZhaoShu-ZhaoHaoZhou, DiDiZhouDu, ChaoChaoDuPang, Li-XiaLi-XiaPangSingh, CharanjeetCharanjeetSinghTrukhanov, SergeiSergeiTrukhanovTrukhanov, AlexAlexTrukhanovSombra, Antonio S.B.Antonio S.B.SombraVarghese, JobinJobinVargheseLi, QiangQiangLiZhang, Xiu-QunXiu-QunZhang2022-03-062022-03-062021https://publica.fraunhofer.de/handle/publica/26763710.1021/acsaelm.1c00193Fifth-generation mobile communication systems provide a huge market for microwave dielectric materials, especially in the manufacture of dielectric resonators, filters, substrates, and antennas. Herein, an excellent performance microwave dielectric ceramic x(NaBi)0.5MoO4-(1-x)MoO3 (0.2 < x < 0.9, abbreviated as xNBM-(1-x)MO sintered below 660 °C with two coexisting phases is prepared via a solid solution reaction. With the increasing x value, the sintering temperature rises from 600 to 640 °C. The dielectric properties have a series of changes with increasing permittivity (10.3-28.1), decreasing Qf value (12,080 to 8600 GHz), and increasing tf value (-27.1 to +21.2 ppm/°C). Typically, at the ultralow temperature of 630 °C, the 0.8NBM-0.2MO ceramic exhibits great microwave performance with er &#8764; 24.4, Qf &#8764; 9030 GHz (7.7 GHz), and a near-zero tf &#8764; 7.2 ppm/°C. A prototype dielectric resonator antenna is manufactured using a 0.8NBM-0.2MO ceramic. A high-impedance bandwidth &#8764;360 MHz can be obtained in the antenna at 7.74 GHz with -10 dB transmission loss (S11). Furthermore, the chemical compatibility with Al powder indicates that the xNBM-(1-x)MO composite ceramics may be promising microwave materials for applications in ultralow-temperature co-fired ceramic technology.enULTCCmolybdenum-based composite microwave ceramicsultralow sintering temperatureraman spectradielectric resonator antenna620666journal article