Method of Improving Dielectric Properties of AlN Ceramic

Hui Na Ma; Zhi Min Yang; Jun Du

doi:10.4028/www.scientific.net/AMR.535-537.844

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 535-537Method of Improving Dielectric Properties of AlN...

Method of Improving Dielectric Properties of AlN Ceramic

Abstract:

AlN-Mo composite ceramics were prepared by spark plasma sintering (SPS) with AlN and Mo, introduction of Mo particles into the AlN matrix was through direct current magnetron sputtering, sol-gel and blending technology methods. The effect of Mo particles on densification, electrical conduction and dielectric properties of AlN ceramic was studied by XRD, SEM, dielectric frequency spectrum. The results indicate that dielectric constant of AlN-0.26vol.%Mo composite ceramics obtained by sputtering increase by 22.5% at 1MHz as compared to the pure AlN sample; AlN-18vol.%Mo composite ceramics prepared with Mo powder coated with Al2O3 show insulator character and good dielectric properties; dielectric constant and loss of the composite ceramics increase with increasing the content of the elongated shape Mo particles, the highest dielectric constant and loss will be obtained when AlN-12vol.%Mo content is 30wt.% ( =98.41, tgδ=0.018 at 1MHz), the value of electrical resistivity decreases rapidly from 1.32×104 to 3.16×101Ω•cm when AlN-12vol.%Mo weight fraction increases from 30% to 40%.

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Periodical:

Advanced Materials Research (Volumes 535-537)

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844-850

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.535-537.844

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Online since:

June 2012

Authors:

Hui Na Ma, Zhi Min Yang, Jun Du

Keywords:

Aluminum Nitride (AlN), Dielectric Property, Electrical Resistivity, Spark Plasma Sintering (SPS)

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References

[1] DAVID K B M: IEEE International Vacuum Electronics Conference, California, USA, 2002, p.32

Google Scholar

[2] XU Gengfu: J Mater Res, Vol.18(2003) , p.66

Google Scholar

[3] Shoichi Kume, Masaki Yasuoka, Naoki Omura, et al: International Journal of Refractory Metals & Hard Materials, Vol. 23(2005), p.382

Google Scholar

[4] Takahashi K, Jimbou R: J. Am. Ceram. Soc., Vol. 70 (1987), p.369

Google Scholar

[5] Shoichi Kume, Masaki Yasuoka and Naoki Omura: Ceramics International, Vol. 33 (2007), p.269

Google Scholar

[6] KHAN A A, LABBE J C: Journal of the European Ceramic Society, Vol. 16(1996), p.739

Google Scholar

[7] Sbaizero O, Pezzotti G: Acta Materialia, Vol. 48(2000), p.985

Google Scholar

[8] Sheng Zhu, Wøadysøaw WøosinÂski: Journal of Materials Processing Technology, Vol. 109(2001), p.277

Google Scholar

[9] Q.C. Zhang, Y.G. Shen: Solar Energy Materials & Solar Cells, Vol. 81(2004), p.25

Google Scholar

[10] T J Lewis:IEEE Transactions on Dielectrics and Electrical Insulation, Vol. 11(2004),p.739

Google Scholar

[11] ZHAO Yiqiang, YAO Suying, XIE Xiaodong, et al: Semiconductor physics and devices, 2005, p.232. (In Chinese)

Google Scholar

[12] Renzheng Chen, Xiaohui Wang, Hai Wen, et al: Ceramics International, Vol. 30(2004), p.1271

Google Scholar

[13] S. Biwa, S. Idekoba, N and Ohno: Mech. Mater, Vol. 34(2002), p.671

Google Scholar

[14] J-H. Oh , K-S. Oh , C-G. Kim and C-S. Hong: Compos.: Part B, Vol. 35(2004), p.49

Google Scholar

[15] Chen Y C, Huang C Z, Wang B Y, et al:Materials Science＆Engineering, Vol. 38(2000), p.19

Google Scholar

[16] RenZheng Chen, AiLi Cui, XiaoHui Wang, et al : Materials Letters, Vol. 54(2002), p.314

Google Scholar