人物介紹
侯育冬,男,1974年11月生,工學博士,教授,博士生導師。中國矽酸鹽學會溶膠凝膠分會理事,中國化學會、矽酸鹽學會、電子學會高級會員。2002年於西北工業大學獲材料學博士學位,2003年進入北京工業大學材料科學與工程學院從事科研與教學工作。擔任電子信息材料學科方向教學責任人,院教學指導委員會委員。科研方面主要開展電子信息陶瓷,功能化合物製備技術與新型器件的研究工作,在壓鐵電材料合成與器件套用、新型電介質材料與納米技術等領域取得多項重要研究進展。主持完成國家自然科學基金、北京市自然科學基金、教育部高校博士點基金(博導類)等各類科研課題20餘項,先後入選北京市科技新星計畫,北京市中青年骨幹教師培養計畫和北京工業大學京華人才支持計畫。擔任Adv Funct Mater、J Am Ceram Soc、Appl Phys Lett等二十餘種國際SCI刊物審稿人,已發表學術論文100餘篇,申請國家發明專利10餘項。科研成果先後獲省部級科技進步一等獎,二等獎和北京工業大學優秀學術成果獎。教學方面主持完成多項教研重點課題,多次獲得北京工業大學教學優秀獎、優秀教育教學成果獎和學業輔導工作實效獎,主講的《先進陶瓷材料》課程獲得北京工業大學研究生精品課程建設立項。此外,作為導師,先後多次獲得北京工業大學優秀博士論文指導教師、優秀碩士論文指導教師和優秀本科畢業設計指導教師稱號,2014年被評為北京工業大學優秀教師。
研究方向
新型電子陶瓷材料與器件,主要包括:
(1)壓電陶瓷與能量收集系統
(2)新型鐵電體與薄膜化技術
(3)納米光電材料與拓撲合成
(4)巨介電陶瓷與超級電容器
學術論文
1. Identification of substitution mechanism in group VIII metal oxides doped Pb(ZnNb)O-PbZrO-PbTiOceramics withhigh energy density and mechanical performance,Journal of the American Ceramic Society, 96(8), 2486-2492 (2013).
2.Effect of valence state and incorporation site of cobalt dopants onthe microstructure and electrical properties of 0.2PZN-0.8PZT ceramics,Acta Materialia, 61(5): 1489-1498 (2013).
3. The formation of (Zn,Ni)TiOsecondary phase in NiO-modified Pb(ZnNb)O-PbZrO-PbTiOceramics,Scripta Materialia, 68(9): 707-710 (2013).
4. Effect of NiO additive on microstructure, mechanical behavior and electrical properties of 0.2PZN-0.8PZT ceramics,Journal of the European Ceramic Society,33(8): 1447-1456 (2013).
5. Preparation and piezoelectricity of NaNbOhigh-density ceramics by molten salt synthesis,Journal of the American Ceramic Society, 94(12): 4329-4334 (2011).
6. Bismuth-induced ferroelectric relaxor behavior in paraelectric LaAlO,Journal of Applied Physics,110(9): 094107 (2011).
7. The investigation of depoling mechanism of densified KNbOpiezoelectric ceramic,Applied Physics Letters, 99(3): 032905 (2011).
8. Microstructure and relaxor behavior of dense fine-grainFeTiTaOceramics,Journal of the American Ceramic Society, 93(9): 2491-2494 (2010).
9. Effect of annealing temperature on dielectric relaxation and raman scattering of 0.65Pb(MgNb)O-0.35PbTiOsystem,Journal of the American Ceramic Society, 93(9): 2748-2754 (2010).
10. Growth of (NaK)NbOsingle crystals by abnormal grain growth method from special shaped nano-powders,Journal of the European Ceramic Society, 30(7): 1725-1730 (2010).
11. Relaxor behavior of (Ba, Bi)(Ti, Al)Oferroelectric ceramic,Journal of Applied Physics, 107(5): 054105 (2010).
12. Crystalstructure and orthorhombic-tetragonal phase transitionof nanoscale (LiNaK)NbO,Journal of the European Ceramic Society, 29(12): 2589-2594 (2009).
13. Effect of sintering temperature on dielectric relaxation and Raman scattering of 0.65Pb(MgNb)O-0.35PbTiOsystem,Journal of Applied Physics, 105(8): 084107 (2009).
14. Facile synthesis and high dof single-crystalline KNbOnanocubes,Chemical Communications, 41: 5137-5139 (2008).
15. Effect of LiCOaddition on the dielectric and piezoelectric responses in the low temperature sintered 0.5PZN-0.5PZT systems,Journal of Applied Physics, 102(8): 084507 (2007).
16. Relaxor behavior of (KBi)TiOceramics derived from molten salt synthesized single-crystalline nanowires,Applied Physics Letters, 91(2): 023118 (2007).
17. (NaK)BiTiOnanowires: low-temperature sol-gel-hydrothermal synthesis and densification,Journal of the American Ceramic Society, 90(6): 1738-1743 (2007).
18. Effect of sintering temperature on the phase transition and dielectrical response in the relaxor-ferroelectric-system 0.5PZN-0.5PZT,Journal of Applied Physics, 101(3): 034101 (2007).
19. Synthesis of (KBi)BaTiOnanowires and ceramics by sol-gel-hydrothermal method,Applied Physics Letters, 89(24): 243114 (2006).
20. Effects of atmospheric powder on microstructure and piezoelectric properties of PMZN-PZT quaternary ceramics,Journal of the European Ceramic Society, 24(15-16): 3731-3737 (2004).
21. Effect of MnOaddition on the structure and electrical properties of Pb(ZnNb)(ZrTi)Oceramics,Journal of the American Ceramic Society, 87(5): 847-850 (2004) .
