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微秒脉冲电场下Pb0.99(Zr0.95Ti0.05)0.98Nb0.02O3陶瓷击穿过程电阻变化规律

刘艺 杨佳 李兴 谷伟 高志鹏

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微秒脉冲电场下Pb0.99(Zr0.95Ti0.05)0.98Nb0.02O3陶瓷击穿过程电阻变化规律

刘艺, 杨佳, 李兴, 谷伟, 高志鹏

Resistance of Pb0.99(Zr0.95Ti0.05)0.98Nb0.02O3 under high voltage microsecond pulse induced breakdown

Liu Yi, Yang Jia, Li Xing, Gu Wei, Gao Zhi-Peng
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  • 陶瓷作为应用非常广泛的一种材料,其电击穿问题一直是研究的重点和热点.由于击穿过程涉及热、光、电多场耦合效应,目前还没有一个普适的模型能够解释陶瓷击穿问题.针对此问题进行分析,实验中采用脉冲高压发生装置击穿陶瓷,通过对陶瓷击穿过程中等效电阻的研究,揭示了PZT95/5陶瓷样品体击穿和沿面闪络形成过程的异同.结果显示,在两种击穿模式下,陶瓷样品内部均会在40 ns左右形成导电通道,陶瓷等效电阻急剧下降至105 量级;然后体击穿与沿面闪络的导电通道以不同的速率继续扩展;电阻减小速率与导电通道上载流子的浓度有关,二者的等效电阻以不同速率减小,直至导电通道达到稳定.
    Ferroelectric ceramics have been widely used in lots of fields, such as mechanical-electric transducer, ferroelectric memory, and energy storage devices. The dielectric breakdown process of ferroelectric ceramic has received much attention for years, due to the fact that this issue is critical in many electrical applications. Though great efforts have been made, the mechanism of dielectric breakdown is still under debate. The reason is that the electrical breakdown is a complex process related to electrical, thermal, and light effects. In the present work, we investigate the breakdown process of Pb0.99(Zr0.95Ti0.05)0.98Nb0.02O3(PZT95/5) ceramic, which is a kind of typical ferroelectric ceramic working in the high voltage environments. The high voltage pulse generator is used in the breakdown experiments to apply a square pulsed voltage with an amplitude of 10 kV and a width of 7 s. The resistivity change in the breakdown process is recorded by the high-frequency oscillograph in nano-second. The results show that there are two different breakdown types for our sample, i.e. body-breakdown and flashover. To better understand the breakdown mechanism of the PZT95/5 ceramic, the formation of the conductive channel in ceramic in the process is investigated by comparing the resistivity development in body-breakdown and flashover processes. The development of the conductive channel formation can be divided into three steps in body-breakdown. In the first step that lasts for the first 40 ns of breakdown, the conductive channel starts forming, with the equivalent resistance sharply decreasing to about 105 in the mean time. Then, i.e. in the second step, conductive path grows into a stable one with the equivalent resistance decreasing to the magneitude of about 102 . The resistance decreases slowly to about 130 in the third step, which means that the conductive channel is completely formed. The channel formation of flashover can also be divided into three steps. The first step is similar to that of body-breakdown, with the equivalent resistance decreasing to about 105 in about 40 ns. In the second step of flashover, the conductive path keeps growing into a stable one with the equivalent resistance decreasing to 102 , but with a different resistance changing rate from that in body-breakdown, and the resistance decreases slowly to about 20 in the end. Different behavior between the body-breakdown and the surface flashover can be explained by different carrier densities on the conductive paths in the two breakdown processes. In the body-breakdown, the carrier density in the conductive channel is higher than that in the surface flashover, which improves the electron transfer and reduces the resistance. This may explain the reason why the channel formation in body-breakdown is faster than in flashover. This study is helpful for further materials design and applications.
      Corresponding author: Yang Jia, whuyj168@126.com;z.p.gao@foxmail.com ; Gao Zhi-Peng, whuyj168@126.com;z.p.gao@foxmail.com
    • Funds: Project supported by the Science and Technology Foundation of National Key Laboratory of Shock Wave and Detonation Physics (Grant No. 2016Z-04).
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    Hall D A, Evans J D S, Covey-Crump S J, Holloway R F, Oliver E C, Moria T, Withers P J 2010 Acta Mater. 58 6584

    [17]

    Wang J X, Wang J, Yang S Y, Bian L 2009 J. Lanzhou Univ. Technol. 35 22 (in Chinese) [王军霞, 王进, 杨世源, 边亮 2009 兰州理工大学学报 35 22]

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    Lysne P C 1977 J. Appl. Phys. 48 4565

    [19]

    Wen D Y, Lin Q W 1997 Detonation and Shock Waves 3 27 (in Chinese) [温殿英, 林其文 1997 爆轰波与冲击波 3 27]

    [20]

    Jiang Y X, Wang S Z, He H L 2014 Chin. J. High Pressure Phys. 28 680 (in Chinese) [蒋一萱, 王省哲, 贺红亮 2014 高压物理学报 28 680]

    [21]

    Zhang F P, Du J M, Liu Y S, Liu Y, Liu G M, He H L 2011 Acta Phys. Sin. 60 057701 (in Chinese) [张福平, 杜金梅, 刘雨生, 刘艺, 刘高旻, 贺红亮 2011 物理学报 60 057701]

    [22]

    Pakhotin V A, Zakrevskii V A, Sudar N T 2015 Tech. Phys. 60 1149

    [23]

    He L, Ji Y Z, Liu G C 2007 J. Changchun Univ. 28 165 (in Chinese) [贺莉, 纪跃芝, 刘国彩 2007长春工业大学学报 28 165]

    [24]

    Zhang F H 2008 Ph. D. Dissertation (Xi'an: Shaanxi University of Science Technology) (in Chinese) [张方晖 2008 博士学位论文 (西安: 陕西科技大学)]

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    Lu Q M, Yang W H, Liu W D 2004 Nucl. Fusion Plasma Phys. 24 33

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    Slutsker A I, Hilyarov V L 2011 Phys. Solid State 53 1325

  • [1]

    Farouk A M 2014 High Voltage Engineering (Boca Raton: CRC press) pp299-349

    [2]

    Hemmert D, Holt S, Krile J 2007 Proceedings of 10th Annual Directed Energy Symposium Huntsville, USA, November 5-8, 2007 p5

    [3]

    Matsushima H, Okino H, Mochizuki K, Yamada R 2016 J. Appl. Phys. 119 154506

    [4]

    Kim S C, Heo H, Moon C, Nam S H 2016 IEEE Trans. Plasma Sci. 44 687

    [5]

    Du J F, Liu D, Bai Z, Yu Q 2016 Jpn. J. Appl. Phys. 55 054301

    [6]

    Shkuratov S I, Talantsev E F, Menon L, Temkin H, Baird J 2004 Rev. Sci. Instrum. 75 2766

    [7]

    Forster E O 1990 J. Phys. D Appl. Phys. 23 1507

    [8]

    Whitehead S 1953 Dielectric Breakdown of Solids (Oxford: Clarendon Press) pp37-54

    [9]

    Tu D M, Wang X S 1993 Acad. J. Xi'an Jiaotong Univ. 27 33 (in Chinese) [屠德民, 王新生 1993 西安交通大学学报 27 33]

    [10]

    Qu Y F 2007 Physical Behavior of Functional Ceramics (Beijing: Chemical Industry Press) pp107-118 (in Chinese) [曲远方 2007 功能陶瓷的物理性能 (北京: 化学工业出版社) 第107-118页]

    [11]

    Wang Y L 2003 Properties and Applications of Functional Ceramics (Beijing: Science Press) pp146-154 (in Chinese) [王永龄 2003功能陶瓷性能与应用(北京: 科学出版社) 第146-154页]

    [12]

    Han S M, Huh C S 2016 IEEE Trans. Plasma Sci. 44 1429

    [13]

    Hu Y H, Yao H Y, Yu Z J, Wang Y Z 2016 Rare Metal Mat. Eng. 45 571

    [14]

    Du J M, Zhang Y, Zhang F P, He H L, Wang H Y 2006 Acta Phys. Sin. 55 2584 (in Chinese) [杜金梅, 张毅, 张福平, 贺红亮, 王海晏 2006 物理学报 55 2584]

    [15]

    Lan C F, Nie H C, Chen X F, Wang J X, Wang G S, Dong X L, Liu Y S, He H L 2013 J. Inorg. Mater. 28 503 (in Chinese) [兰春锋, 聂恒昌, 陈学锋, 王军霞, 王根水, 董显林, 刘雨生, 贺红亮 2013 无机材料学报 28 503]

    [16]

    Hall D A, Evans J D S, Covey-Crump S J, Holloway R F, Oliver E C, Moria T, Withers P J 2010 Acta Mater. 58 6584

    [17]

    Wang J X, Wang J, Yang S Y, Bian L 2009 J. Lanzhou Univ. Technol. 35 22 (in Chinese) [王军霞, 王进, 杨世源, 边亮 2009 兰州理工大学学报 35 22]

    [18]

    Lysne P C 1977 J. Appl. Phys. 48 4565

    [19]

    Wen D Y, Lin Q W 1997 Detonation and Shock Waves 3 27 (in Chinese) [温殿英, 林其文 1997 爆轰波与冲击波 3 27]

    [20]

    Jiang Y X, Wang S Z, He H L 2014 Chin. J. High Pressure Phys. 28 680 (in Chinese) [蒋一萱, 王省哲, 贺红亮 2014 高压物理学报 28 680]

    [21]

    Zhang F P, Du J M, Liu Y S, Liu Y, Liu G M, He H L 2011 Acta Phys. Sin. 60 057701 (in Chinese) [张福平, 杜金梅, 刘雨生, 刘艺, 刘高旻, 贺红亮 2011 物理学报 60 057701]

    [22]

    Pakhotin V A, Zakrevskii V A, Sudar N T 2015 Tech. Phys. 60 1149

    [23]

    He L, Ji Y Z, Liu G C 2007 J. Changchun Univ. 28 165 (in Chinese) [贺莉, 纪跃芝, 刘国彩 2007长春工业大学学报 28 165]

    [24]

    Zhang F H 2008 Ph. D. Dissertation (Xi'an: Shaanxi University of Science Technology) (in Chinese) [张方晖 2008 博士学位论文 (西安: 陕西科技大学)]

    [25]

    Lu Q M, Yang W H, Liu W D 2004 Nucl. Fusion Plasma Phys. 24 33

    [26]

    Slutsker A I, Hilyarov V L 2011 Phys. Solid State 53 1325

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  • 收稿日期:  2016-12-12
  • 修回日期:  2017-01-23
  • 刊出日期:  2017-06-05

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