等离子体光子晶体研究进展综述
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摘要
光子晶体作为控制电磁波传输的一种新型材料,以其优越的性能和广阔的应用前景近年来受到了国内外学者的广泛关注。如何制作结构参数可调的光子晶体,特别是如何加强其可重构性、可控性是当前光子晶体领域的一项重要课题。针对于此,本文对一种新型可调等离子体光子晶体超材料的研究进展进行了系统讨论。简要回顾了等离子体光子晶体的发展历史,介绍了等离子体光子晶体的实验产生方式和分类,阐明了等离子体光子晶体不同理论研究方法,并对其未来发展趋势进行了展望。从理论和实验两方面对等离子体光子晶体进行了深入分析。本工作为今后该领域的深入发展以及广泛应用提供了一定借鉴意义。
As a new type of material to control electromagnetic wave transmission,photonic crystal(PC)has attracted increasing attention in recent years due to its excellent performance and wide application prospects. How to make tunable photonic crystals,especially how to strengthen its reconfigurability and controllability is one of the most important issue in this field. In this manuscript,the brief history,fabrication method and classifications of plasma photonic crystals are discussed,respectively. Different theoretical methods to calculate dispersion relations of the plasma photonic crystals are demonstrated.Both experimental and theoretical of plasma photonic crystals are presented. The work would be helpful for further development and wide applications of plasma photonic crystals in the future.
As a new type of material to control electromagnetic wave transmission,photonic crystal(PC)has attracted increasing attention in recent years due to its excellent performance and wide application prospects. How to make tunable photonic crystals,especially how to strengthen its reconfigurability and controllability is one of the most important issue in this field. In this manuscript,the brief history,fabrication method and classifications of plasma photonic crystals are discussed,respectively. Different theoretical methods to calculate dispersion relations of the plasma photonic crystals are demonstrated.Both experimental and theoretical of plasma photonic crystals are presented. The work would be helpful for further development and wide applications of plasma photonic crystals in the future.
引文
[1] Yablonovitch E. Inhibited spontaneous emission in solid-state physics and electronics[J]. Phys. Rev. Lett,1987,58(20):2059-2061.
[2] John S. Electronic physical localization of photons in certain disordered dielectric superlattices[J]. Phys. Rev. Lett.,1987,58(23):2486-2489.
[3] Yablonovitch E,Gmitter T J,Meade R D,et al. Donor and acceptor modes in photonic band structure[J]. Phys. Rev. Lett.,1991,67(24):3380.
[4] Yanik M F,Fan S,Soljacic M. High-contrast all-optical bistable switching in photonic crystal microcavities[J]. Appl. Phys. Lett.,2003,83(14):2739.
[5] Zhang H F,Liu S B,Kong X K,et al. Omnidirectional photonic band gap enlarged by one-dimensional ternary unmagnetized plasma photoniccrystals based on a new Fibonacci quasiperiodic structure[J]. Phys. Plasmas,2012,19(11):112102.
[6] Joannopoulos J J,Villeneuve P R,Fan S,et al. Photonic crystals:putting new twist on light[J]. Nature,1997,386(6621):143-149.
[7] Leung K M,Liu Y F. Full vector wave calculation of photonic band structures in face-centered-cubic dielectric media[J]. Phys. Rev. Lett.,1990,65(21):2646-2649.
[8] Sakai O,Tachibana K. Plasmas as metamaterials:a review[J]. Plasma Sources Sci. Technol,2012,21:013001.
[9] Chaudhari M. K. Chaudhari S. Tuning photonic bands in plasma metallic photonic crystals[J]. Phys. Plasmas,2016,23:112118.
[10] Wang B. Cappelli M. A. A tunable microwave plasma photonic crystal filter[J]. Appl. Phys. Lett.,2015,107:171107.
[11] Yin Y,Xu H,Yu M,et al. Bandgap characteristics of one-dimensional plasma photonic crystal[J]. Phys. Plasmas,2009,16,102103.
[12] Shukla S,Prasad S,Singh V,Properties of surface modes in one dimensional plasma photonic crystals[J]. Phys. Plasmas,2015,22,022122.
[13] Li C,Liu S,Kong X,et al. A novel comb-like plasma photonic crystal filter in the presence of evanescent wave[J]. IEEE Trans. Plasma Sci.,2011,39(10):1969-1973.
[14] Hojo H,Mase A. Dispersion relation of electromagnetic waves in one-dimensional plasma photonic crystals[J]. Plasma Fusion Res.,2004,80(2):90.
[15] Lehmann G,Spatschek K H. Transient Plasma Photonic Crystals for High-Power Lasers[J]. Phys. Rev. Lett.,2016,116:225002.
[16] Lo J,Sokoloff J,Boeuf J P,et al. Reconfigurable electromagnetic band gap device using plasma as a localized tunable defect[J]. Appl. Phys.Lett.,2010,96:251501.
[17] Sakai1 O,Yamaguchi1 S,Nakamura Y,et al. Plasma metamaterials as cloaking and nonlinear media[J]. Plasma Phys. Control. Fusion,2017,59:014042.
[18] Varault S,Gabard B,Sokoloff J R,et al. Plasma-based localized defect for switchable coupling applications.[J]. Appl. Phys. Lett.,2011,98(13):134103.
[19] Qi L,Yang Z,Fu T,et al. Defect modes in one-dimensional magnetized plasma photonic crystals with a dielectric defect layer[J]. Phys.Plasmas,2012,19(1):012509.
[20] Kong X K,Liu S B,Zhang H F,et al. A novel tunable filter featuring defect mode of the TE wave from one-dimensional photonic crystals doped by magnetized plasma[J]. Phys. Plasmas,2010,17(10):103506.
[21] Zhang H F,Liu S B,et al. The properties of the extraordinary mode and surface plasma modes in the three dimensional magnetized plasma photonic crystals based on the magneto-optical Voigt effects[J]. Phys. Plasmas,2014,21:062115.
[22]刘鸿娟,叶志清,邓海东,等.用转移矩阵方法计算一维光子晶体的禁带结构[A].江西师范大学学报(自然科学版),2004,28(2):105-109.
[23]刘少斌,顾长青,周建江,等.磁化等离子体光子晶体的FDTD分析[J].物理学报,2006,55(3):1283-1288.
[24]寸焕尧,谭仁兵,王荣丽,等.用平面波展开法计算二维方形光子晶体的带隙结构[A].半导体学报,2006,27:65-67.
[25]李伟,张海涛,巩马理,等.等离子体光子晶体[J].光学技术,2004,30(3):263-266.
[26] Hai F Z,Yu Q C. The properties of two-dimensional fractal plasma photonic crystals with Thue-Morse sequence[J]. Phys. Plasmas,2017,42:042116.
[27]章海峰,刘少斌,非磁化等离子体光子晶体缺陷态的研究[J].物理学报,2008,57(8):5089-5094.
[28]章海峰,马力,刘少斌,磁化等离子体光子晶体的缺陷态的研究[J].物理学报,2009,58(2):1071-1076.
[29] Sakaguchi T,Sakai O,Kunihide T,et al. Photonic bands in two-dimensional microplasma arrays. II. Band gaps observed in millimeter and subterahertz ranges[J]. Journal of Applied Physics,2007,101:073305.
[30] Wang B,Cappelli M A. A plasma photonic crystal bandgap device[J]. Appl. Phys. Lett.,2016,108:161101.
[31] Wang B,Cappelli M A,Colon R,et al. A microstrip photonic crystal bandgap device with a switchable negative epsilion plasma element[J].Microw. Guided W.,2017,59:3097-3101.
[32] Ouyang J T,Liu Y Y,He F,et al. Evolution of Striation in Pulsed Glow Discharges[J]. Plasma Sci. Technol. 2016,18:29-34.
[33] Gregório J,Parsons S,Hopwood J,et al. Reconfigurable photonic crystal using self-initiated gas breakdown[J]. Plasma Sci. Technol. 2017,26:02LT03.
[34] Dong L,Fan W. Tunable one-dimensional plasma photonic crystal in dielectric barrier discharge[J]. Phys. Plasmas,2016,17:073506.
[35] Dong L,Fan W,Zhang X,et al. Two-dimensional plasma photonic crystals in dielectric barrier discharge[J]. Phys. Plasmas,2010,17:113501.
[36] Dong L,Wang W,Liu W,et al. Generation of tunable plasma photonic crystals in meshed dielectric barrier discharge[J]. Phys. Plasmas,2014,21:073505.
[2] John S. Electronic physical localization of photons in certain disordered dielectric superlattices[J]. Phys. Rev. Lett.,1987,58(23):2486-2489.
[3] Yablonovitch E,Gmitter T J,Meade R D,et al. Donor and acceptor modes in photonic band structure[J]. Phys. Rev. Lett.,1991,67(24):3380.
[4] Yanik M F,Fan S,Soljacic M. High-contrast all-optical bistable switching in photonic crystal microcavities[J]. Appl. Phys. Lett.,2003,83(14):2739.
[5] Zhang H F,Liu S B,Kong X K,et al. Omnidirectional photonic band gap enlarged by one-dimensional ternary unmagnetized plasma photoniccrystals based on a new Fibonacci quasiperiodic structure[J]. Phys. Plasmas,2012,19(11):112102.
[6] Joannopoulos J J,Villeneuve P R,Fan S,et al. Photonic crystals:putting new twist on light[J]. Nature,1997,386(6621):143-149.
[7] Leung K M,Liu Y F. Full vector wave calculation of photonic band structures in face-centered-cubic dielectric media[J]. Phys. Rev. Lett.,1990,65(21):2646-2649.
[8] Sakai O,Tachibana K. Plasmas as metamaterials:a review[J]. Plasma Sources Sci. Technol,2012,21:013001.
[9] Chaudhari M. K. Chaudhari S. Tuning photonic bands in plasma metallic photonic crystals[J]. Phys. Plasmas,2016,23:112118.
[10] Wang B. Cappelli M. A. A tunable microwave plasma photonic crystal filter[J]. Appl. Phys. Lett.,2015,107:171107.
[11] Yin Y,Xu H,Yu M,et al. Bandgap characteristics of one-dimensional plasma photonic crystal[J]. Phys. Plasmas,2009,16,102103.
[12] Shukla S,Prasad S,Singh V,Properties of surface modes in one dimensional plasma photonic crystals[J]. Phys. Plasmas,2015,22,022122.
[13] Li C,Liu S,Kong X,et al. A novel comb-like plasma photonic crystal filter in the presence of evanescent wave[J]. IEEE Trans. Plasma Sci.,2011,39(10):1969-1973.
[14] Hojo H,Mase A. Dispersion relation of electromagnetic waves in one-dimensional plasma photonic crystals[J]. Plasma Fusion Res.,2004,80(2):90.
[15] Lehmann G,Spatschek K H. Transient Plasma Photonic Crystals for High-Power Lasers[J]. Phys. Rev. Lett.,2016,116:225002.
[16] Lo J,Sokoloff J,Boeuf J P,et al. Reconfigurable electromagnetic band gap device using plasma as a localized tunable defect[J]. Appl. Phys.Lett.,2010,96:251501.
[17] Sakai1 O,Yamaguchi1 S,Nakamura Y,et al. Plasma metamaterials as cloaking and nonlinear media[J]. Plasma Phys. Control. Fusion,2017,59:014042.
[18] Varault S,Gabard B,Sokoloff J R,et al. Plasma-based localized defect for switchable coupling applications.[J]. Appl. Phys. Lett.,2011,98(13):134103.
[19] Qi L,Yang Z,Fu T,et al. Defect modes in one-dimensional magnetized plasma photonic crystals with a dielectric defect layer[J]. Phys.Plasmas,2012,19(1):012509.
[20] Kong X K,Liu S B,Zhang H F,et al. A novel tunable filter featuring defect mode of the TE wave from one-dimensional photonic crystals doped by magnetized plasma[J]. Phys. Plasmas,2010,17(10):103506.
[21] Zhang H F,Liu S B,et al. The properties of the extraordinary mode and surface plasma modes in the three dimensional magnetized plasma photonic crystals based on the magneto-optical Voigt effects[J]. Phys. Plasmas,2014,21:062115.
[22]刘鸿娟,叶志清,邓海东,等.用转移矩阵方法计算一维光子晶体的禁带结构[A].江西师范大学学报(自然科学版),2004,28(2):105-109.
[23]刘少斌,顾长青,周建江,等.磁化等离子体光子晶体的FDTD分析[J].物理学报,2006,55(3):1283-1288.
[24]寸焕尧,谭仁兵,王荣丽,等.用平面波展开法计算二维方形光子晶体的带隙结构[A].半导体学报,2006,27:65-67.
[25]李伟,张海涛,巩马理,等.等离子体光子晶体[J].光学技术,2004,30(3):263-266.
[26] Hai F Z,Yu Q C. The properties of two-dimensional fractal plasma photonic crystals with Thue-Morse sequence[J]. Phys. Plasmas,2017,42:042116.
[27]章海峰,刘少斌,非磁化等离子体光子晶体缺陷态的研究[J].物理学报,2008,57(8):5089-5094.
[28]章海峰,马力,刘少斌,磁化等离子体光子晶体的缺陷态的研究[J].物理学报,2009,58(2):1071-1076.
[29] Sakaguchi T,Sakai O,Kunihide T,et al. Photonic bands in two-dimensional microplasma arrays. II. Band gaps observed in millimeter and subterahertz ranges[J]. Journal of Applied Physics,2007,101:073305.
[30] Wang B,Cappelli M A. A plasma photonic crystal bandgap device[J]. Appl. Phys. Lett.,2016,108:161101.
[31] Wang B,Cappelli M A,Colon R,et al. A microstrip photonic crystal bandgap device with a switchable negative epsilion plasma element[J].Microw. Guided W.,2017,59:3097-3101.
[32] Ouyang J T,Liu Y Y,He F,et al. Evolution of Striation in Pulsed Glow Discharges[J]. Plasma Sci. Technol. 2016,18:29-34.
[33] Gregório J,Parsons S,Hopwood J,et al. Reconfigurable photonic crystal using self-initiated gas breakdown[J]. Plasma Sci. Technol. 2017,26:02LT03.
[34] Dong L,Fan W. Tunable one-dimensional plasma photonic crystal in dielectric barrier discharge[J]. Phys. Plasmas,2016,17:073506.
[35] Dong L,Fan W,Zhang X,et al. Two-dimensional plasma photonic crystals in dielectric barrier discharge[J]. Phys. Plasmas,2010,17:113501.
[36] Dong L,Wang W,Liu W,et al. Generation of tunable plasma photonic crystals in meshed dielectric barrier discharge[J]. Phys. Plasmas,2014,21:073505.