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钛离子辐照对MgB2超导薄膜的载流能力和磁通钉扎能力的影响

王银博 薛驰 冯庆荣

钛离子辐照对MgB2超导薄膜的载流能力和磁通钉扎能力的影响

王银博, 薛驰, 冯庆荣
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  • 利用混合物理化学气相沉积法(hybrid physical-chemical vapor deposition, HPCVD)可以制备出高性能的MgB2超导薄膜, 再对薄膜进行钛(Ti)离子辐照处理.经过辐照处理后的样品被掺入了Ti元素, 与未处理的干净MgB2样品相比,其超导转变温度没有出现大幅度的下降, 而在外加磁场下的临界电流密度得到了明显的提高,同时样品的上临界磁场也得到了提高. 在温度5 K, 外加垂直磁场为4 T的情况下, Ti离子辐照剂量为1 1013/cm2的样品的临界电流密度达到了1.72 105 A/cm2, 比干净的MgB2要高出许多,而其超导转变温度仍能维持在39.9 K的较高水平.
    • 基金项目: 国家重点基础研究发展计划(批准号:2006CD601004, 2011CB605904, 2011CBA00104)和国家基础科学人才培养基金(批准号: J0630311)资助的课题.
    [1]

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    [2]

    Iwasa Y, Larbalestier D C, Okada M, Penco R, Sumption M D, Xi X X 2006 IEEE Trans. Appl. Supercond. 16 1457

    [3]

    Larbalestier D C, Cooley L D, Rikel M O, Polyanskii A A, Jiang J, Patnaik S, Cai X Y, Feldmann D M, Gurevich A, Squitieri A A, Naus M T, Eom C B, Hellstrom E E, Cava R J, Regan K A, Rogado N, Hayward M A, He T, Slusky J S, Khalifah P, Inumaru K,Haas M K 2001 Nature 410 186

    [4]

    Eom C B, Lee M K, Chol J H, Belenky L J, Song X, Cooley L D, Naus M T, Patnaik S, Jiang J, Rikel M, Polyanskii A, A Gurevich, Cai X Y, Bu S D, Babcock S E, Hellstrom E E, Larbalestier D C, Rogado N, Regan K A, Hayward M A, He T, Slusky J S, Inumaru K, Haas M K, Cava R J 2002 Nature 411 558

    [5]

    Bhatia M, Sumption M D, Coolings E W 2005 IEEE Transactions on Applied Superconductivity 15 3204

    [6]

    Kim J H, Dou S X, Hossain M S A, Xu X, Wang J L, Shi D Q, Nakane T, Kumakura H 2007 Supercond. Sci. Technol. 20 715

    [7]

    Krutzler C, Zchetmayer M, Eisterer M, Weber H W, Zhigadlo N D, Karpinski J 2007 Physical Review B 75 224510

    [8]

    Kumar R, Agrawal H, Kushwaha R, Kanjilal D 2007 Nucl. Instr. and Meth. in Phys. Res. B 263 414

    [9]

    Soltanian S, Horvat J,Wang X L, Munroe P, Dou S X 2003 Physica C 390 185

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    Zhuang C G, Meng S, Yang H, Jia Y, Wen H H, Xi X X, Feng Q R, Gan Z Z 2008 Supercond. Sci. Technol. 21 082002

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    Kazakov S M, Puzniak R, Rogacki K, Mironov A V, Zhigadlo N D, Jun J, Soltmann C, Batlogg B, Karpinski J 2005 Physical Review B 71 024533

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    Zhao Y, Ionescu M, Horvat J, Li A H, Dou S X 2004 Supercond. Sci. Technol. 17 1247

    [13]

    Kusevic I, Babic E, Husnjak E, Saltanian S, Wang X L, Dou S X 2004 Solid State Communications 132 761

    [14]

    Zhang C Y, Wang Y B, Hu W W, Feng Q R 2010 Supercond. Sci. Technol. 23 065017

    [15]

    Haigh S, Kovac P, Prikhna T A, Savchuk Y M, Kilburn M R, Salter C, Hutchison J, Grovenor C 2005 Supercond. Sci. Technol. 18 1190

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    Zhao Y, Feng Y, Shen T M, Li G, Yang Y, Cheng C H 2006 Journal of Applied Physics 100 123902

    [17]

    Fu B Q, Feng Y, Yan G, Zhao Y, Pradhan A K, Cheng C H, Ji P, Liu X H,. Liu C F, Zhou L, Yau K F 2002 Journal of Applied Physics 92 7341

    [18]

    Yang Y, Zhao D, Shen T M, Li G, Zhang Y, Feng Y, Chen C H, Zhang Y P, Zhao Y 2008 Physica C 468 1202

    [19]

    Anderson Jr. N E, Straszheim W E, Budko S L, Canfield P C, Finnemore D K, Suplinskas R J 2003 Physica C 390 11

    [20]

    Zeng X H. Pogrebnyakov A J, Kotcharov A, Jones J E, Xi X X, Lysczek E M, Redwing J M, Xu S Y, Li Q, Lettieri J, Schlom D G, Tia W, Pan X Q, Liu Z K 2002 Nat. Mater. 1 1

    [21]

    Xi X X, Pogrebnyakov A V, Xu S Y, Chen K, Cui Y, Maertz E C, Zhuang C G, Li Q, Lamborn D R, Redwing J M, Liu Z K, Soukiassian A, Schlom D G, Weng X J, Dickey E C, Chen Y B, Tian W, Pan X Q, Cybart S A, Dynes R C 2007 Physica C 456 22

    [22]

    Ribeiro R A, Bud S L,Petrovic C, Canfield P C 2003 Physica C 384 227

    [23]

    Zao Y, Feng Y, Huang D X, Machi T, Cheng C H, Nakao K, Chikumoto N, Fudamoto Y, Koshozuka N, Murakami M 2002 Physica C 378-381 122

    [24]

    Fu B Q, Feng Y, Yan G, Zhao Y, Pradhan A K, Cheng C H, Ji P, Liu X H, Liu C F, Zhou L, Yau K F 2002 Journal of Applied Physics 93 7341

    [25]

    Cheng C H, Zao Y, Feng Y, Zhu X T, Koshozuka N, Murakami M 2003 Supercond. Sci. Technol. 16 125

    [26]

    Zao Y, Cheng C H, Machi T, Koshozuka N, Murakami M 2002 Appl. Phys. Lett. 80 2311

    [27]

    Tinkham M 1996 Introduction to Superconductivity (2nd Ed.) (New York: McGraw- Hill) p123

    [28]

    Bean C P 1962Phys. Rev. Lett.8 250

    [29]

    Dew-Hughes D 1974 Phil. Mag. 30 293

    [30]

    Dew-Hughes D 1987 Phil. Mag. 55 459

    [31]

    Kramer E J 1973 J. Appl. Phys. 44 1360

    [32]

    Chen J, Ferrando V, Orgiani P, Pogrebnyakov A V, Wilke R, Betts J, Mielke C, Redwing J, Xi X X, Li Q 2006 Phys. Rev. B 74 174511

  • [1]

    Nagamatsu J, Nakagawa N, Muranaka T, Zentani Y, Akimitsu J 2001 Nature 410 63

    [2]

    Iwasa Y, Larbalestier D C, Okada M, Penco R, Sumption M D, Xi X X 2006 IEEE Trans. Appl. Supercond. 16 1457

    [3]

    Larbalestier D C, Cooley L D, Rikel M O, Polyanskii A A, Jiang J, Patnaik S, Cai X Y, Feldmann D M, Gurevich A, Squitieri A A, Naus M T, Eom C B, Hellstrom E E, Cava R J, Regan K A, Rogado N, Hayward M A, He T, Slusky J S, Khalifah P, Inumaru K,Haas M K 2001 Nature 410 186

    [4]

    Eom C B, Lee M K, Chol J H, Belenky L J, Song X, Cooley L D, Naus M T, Patnaik S, Jiang J, Rikel M, Polyanskii A, A Gurevich, Cai X Y, Bu S D, Babcock S E, Hellstrom E E, Larbalestier D C, Rogado N, Regan K A, Hayward M A, He T, Slusky J S, Inumaru K, Haas M K, Cava R J 2002 Nature 411 558

    [5]

    Bhatia M, Sumption M D, Coolings E W 2005 IEEE Transactions on Applied Superconductivity 15 3204

    [6]

    Kim J H, Dou S X, Hossain M S A, Xu X, Wang J L, Shi D Q, Nakane T, Kumakura H 2007 Supercond. Sci. Technol. 20 715

    [7]

    Krutzler C, Zchetmayer M, Eisterer M, Weber H W, Zhigadlo N D, Karpinski J 2007 Physical Review B 75 224510

    [8]

    Kumar R, Agrawal H, Kushwaha R, Kanjilal D 2007 Nucl. Instr. and Meth. in Phys. Res. B 263 414

    [9]

    Soltanian S, Horvat J,Wang X L, Munroe P, Dou S X 2003 Physica C 390 185

    [10]

    Zhuang C G, Meng S, Yang H, Jia Y, Wen H H, Xi X X, Feng Q R, Gan Z Z 2008 Supercond. Sci. Technol. 21 082002

    [11]

    Kazakov S M, Puzniak R, Rogacki K, Mironov A V, Zhigadlo N D, Jun J, Soltmann C, Batlogg B, Karpinski J 2005 Physical Review B 71 024533

    [12]

    Zhao Y, Ionescu M, Horvat J, Li A H, Dou S X 2004 Supercond. Sci. Technol. 17 1247

    [13]

    Kusevic I, Babic E, Husnjak E, Saltanian S, Wang X L, Dou S X 2004 Solid State Communications 132 761

    [14]

    Zhang C Y, Wang Y B, Hu W W, Feng Q R 2010 Supercond. Sci. Technol. 23 065017

    [15]

    Haigh S, Kovac P, Prikhna T A, Savchuk Y M, Kilburn M R, Salter C, Hutchison J, Grovenor C 2005 Supercond. Sci. Technol. 18 1190

    [16]

    Zhao Y, Feng Y, Shen T M, Li G, Yang Y, Cheng C H 2006 Journal of Applied Physics 100 123902

    [17]

    Fu B Q, Feng Y, Yan G, Zhao Y, Pradhan A K, Cheng C H, Ji P, Liu X H,. Liu C F, Zhou L, Yau K F 2002 Journal of Applied Physics 92 7341

    [18]

    Yang Y, Zhao D, Shen T M, Li G, Zhang Y, Feng Y, Chen C H, Zhang Y P, Zhao Y 2008 Physica C 468 1202

    [19]

    Anderson Jr. N E, Straszheim W E, Budko S L, Canfield P C, Finnemore D K, Suplinskas R J 2003 Physica C 390 11

    [20]

    Zeng X H. Pogrebnyakov A J, Kotcharov A, Jones J E, Xi X X, Lysczek E M, Redwing J M, Xu S Y, Li Q, Lettieri J, Schlom D G, Tia W, Pan X Q, Liu Z K 2002 Nat. Mater. 1 1

    [21]

    Xi X X, Pogrebnyakov A V, Xu S Y, Chen K, Cui Y, Maertz E C, Zhuang C G, Li Q, Lamborn D R, Redwing J M, Liu Z K, Soukiassian A, Schlom D G, Weng X J, Dickey E C, Chen Y B, Tian W, Pan X Q, Cybart S A, Dynes R C 2007 Physica C 456 22

    [22]

    Ribeiro R A, Bud S L,Petrovic C, Canfield P C 2003 Physica C 384 227

    [23]

    Zao Y, Feng Y, Huang D X, Machi T, Cheng C H, Nakao K, Chikumoto N, Fudamoto Y, Koshozuka N, Murakami M 2002 Physica C 378-381 122

    [24]

    Fu B Q, Feng Y, Yan G, Zhao Y, Pradhan A K, Cheng C H, Ji P, Liu X H, Liu C F, Zhou L, Yau K F 2002 Journal of Applied Physics 93 7341

    [25]

    Cheng C H, Zao Y, Feng Y, Zhu X T, Koshozuka N, Murakami M 2003 Supercond. Sci. Technol. 16 125

    [26]

    Zao Y, Cheng C H, Machi T, Koshozuka N, Murakami M 2002 Appl. Phys. Lett. 80 2311

    [27]

    Tinkham M 1996 Introduction to Superconductivity (2nd Ed.) (New York: McGraw- Hill) p123

    [28]

    Bean C P 1962Phys. Rev. Lett.8 250

    [29]

    Dew-Hughes D 1974 Phil. Mag. 30 293

    [30]

    Dew-Hughes D 1987 Phil. Mag. 55 459

    [31]

    Kramer E J 1973 J. Appl. Phys. 44 1360

    [32]

    Chen J, Ferrando V, Orgiani P, Pogrebnyakov A V, Wilke R, Betts J, Mielke C, Redwing J, Xi X X, Li Q 2006 Phys. Rev. B 74 174511

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钛离子辐照对MgB2超导薄膜的载流能力和磁通钉扎能力的影响

  • 1. 北京大学物理学院,北京大学人工微结构与介观国家重点实验室,北京大学应用超导研究中心, 100871
    基金项目: 

    国家重点基础研究发展计划(批准号:2006CD601004, 2011CB605904, 2011CBA00104)和国家基础科学人才培养基金(批准号: J0630311)资助的课题.

摘要: 利用混合物理化学气相沉积法(hybrid physical-chemical vapor deposition, HPCVD)可以制备出高性能的MgB2超导薄膜, 再对薄膜进行钛(Ti)离子辐照处理.经过辐照处理后的样品被掺入了Ti元素, 与未处理的干净MgB2样品相比,其超导转变温度没有出现大幅度的下降, 而在外加磁场下的临界电流密度得到了明显的提高,同时样品的上临界磁场也得到了提高. 在温度5 K, 外加垂直磁场为4 T的情况下, Ti离子辐照剂量为1 1013/cm2的样品的临界电流密度达到了1.72 105 A/cm2, 比干净的MgB2要高出许多,而其超导转变温度仍能维持在39.9 K的较高水平.

English Abstract

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