Scatterings and wavefront manipulations of surface plasmon polaritons

Guan Fu-Xin; Dong Shao-Hua; He Qiong; Xiao Shi-Yi; Sun Shu-Lin; Zhou Lei

doi:10.7498/aps.69.20200614

Abstract

Surface plasmon polaritons (SPPs) have found many important applications in on-chip signal transportation, enhanced nonlinear/Raman effect, biological/chemical sensing, super resolution imaging, etc. In these applications, the near-field propagation and far-field scattering of SPPs play a vital role. However, there has been strong desire to understand these physical effects. In this paper, we first briefly review the history and progress of SPPs. Next, we mainly focus on the near-field propagation and far-field scattering of SPPs, including their fundamental theories and practical applications. Finally, we review several different approaches to manipulating the near-field wavefronts of SPPs. These researches offer us a more in-depth understanding and the ability to more strongly control the scattering characteristics of SPPs, which may promote the scientific researches and practical applications of SPPs in the future.

Keywords:

Authors and contacts

1.
Department of Physics, Fudan University, Shanghai 200433, China
2.
Department of Optical Science and Engineering, Fudan University, Shanghai 200433, China
3.
Department of Communication & Information Engineering, Shanghai University, Shanghai 200444, China

Corresponding author: Sun Shu-Lin, sls@fudan.edu.cn ; Zhou Lei, phzhou@fudan.edu.cn

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References

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Cited By

图 1 (a) SPPs的复杂散射效应; (b) SPPs遇到金属表面缺陷时的散射效应; (c) SPPs的反射和折射效应^[16]; (d) 亚波长等离激元纳米激光器^[17]; (e) SPPs的三维远场聚焦效应^[18]

Figure 1. (a) Complex scattering effects of SPPs; (b) scattering effect of SPPs striking a defect on the plasmonic metal; (c) reflection and refraction effects of SPPs^[16]; (d) subwavelength plasmonic nano-laser^[17]; (e) three-dimensional far-field focusing effect of SPPs^[18].

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图 2 (a) SPPs在介质波导中的传输及辐射^[22]; (b) SPPs聚焦装置^[24]

Figure 2. (a) Propagation and radiation of SPPs inside a dielectric waveguide^[22]; (b) anano-device for SPPs focusing^[24].

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图 3 (a), (b)等离激元金属/真空对接系统(上下为完美电导体边界)中的表面等离极化激元反射谱^[33]; (c), (d) 等离激元波导对接系统中的SPPs反射系数^[35]; (e), (f) 金属/介质开放体系中的SPPs的散射系数(R, T, S)^[36]

Figure 3. (a), (b) SPPs reflectance spectrum of a plasmonic metal/vacuum junction system surrounded by perfect electric conductors^[33]; (c), (d) SPPs reflection coefficients of a plasmonic waveguide junction^[35]; (e), (f) scattering coefficients $ (R, T, S) $ of SPPs inside a jointed metal/dielectric open system^[36].

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图 4 (a) 周期性等离激元体对接结构; 特定等离激元周期结构中的(b) SPPs和散射模式以及(c)倏逝波模式的色散关系^[38]

Figure 4. (a) Periodic plasmonic junction system; dispersion relations of (b) SPPs and scattering modes, and (c) evanescent modes inside a typical plasmonic superlattice^[38].

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图 5 (a) 等离激元波导对接体系; (b), (c) 不同金属和不同介质对接的波导体系中SPPs的反射率谱线; (d) 开放式等离激元对接体系; (e) 反射率的变化谱线; (f) 体系中存在一阶波导模式时的场分布^[38]

Figure 5. (a) Plasmonic waveguide junction system; (b), (c) SPPs reflectance spectra in a waveguide junction system with different metals or dielectrics; (d) an open plasmonic junction system; (e) SPPs reflection amplitude as function of periodicity P in such system; (f) field distributions inside such plasmonic system with the first-order scattering modes appearing^[38].

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图 6 (a) 等离激元体Y型分流器和Mach-Zehnder干涉仪^[43]; (b) 基于纳米薄膜的SPPs全反射^[44]; (c) SPPs的180°转向效应^[45]

Figure 6. (a) Plasmonic Y-splitter and Mach-Zehnder interferometer^[43]; (b) total reflection of SPPs based on a nano-layer system^[44]; (c) 180° bending effect of SPPs^[45].

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图 7 (a) SPPs彩色全息术; (b) 重建的三色苹果全息图像^[46]; (c), (d) SPPs远场聚焦^[49]

Figure 7. (a) Colorful holography of SPPs; (b) reconstructed image of 3D colorful apple^[46]; (c), (d) far-field focusing of SPPs^[49].

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图 8 (a) 半无限大等离激元体金属对接系统; (b) 远场散射强度随着散射角度$\varphi $和$\sqrt {\left| {{\varepsilon _2}} \right|} $的变化; (c) 特定等离激元对接体系中的远场散射角分布^[59]

Figure 8. (a) Semi-infinite plasmonic metal junction system; (b) scattering far-field intensity as function of $\varphi $ and $\sqrt {\left| {{\varepsilon _2}} \right|} $; (c) scattering far-field angular distribution of SPPs in a typical plasmonic junction system^[59].

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图 9 (a) 理想的半无限大二维等离激元体系统; (d) 半无限大人工金属网栅结构; (b), (e)相应体系中的SPPs的色散关系; (c), (f) 相应体系中的SPPs散射远场角谱分布^[59]

Figure 9. (a) An ideal semi-infinite 2D plasmonic system; (d) a semi-infinite artificial metallic mesh structure; (b), (e) dispersion relations and (c), (f) scattering far-field angular distributions of SPPs in two plasmonic systems^[59].

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图 10 (a), (b) 利用不同形状的介质光学器件来调控SPPs的波前^[66,67]; (c) 利用纳米颗粒阵列实现SPPs折射^[68]

Figure 10. (a), (b) SPPs wavefront manipulations with dielectric optical elements of different shapes^[66,67]; (c) refraction of SPPs with nanoparticle array^[68].

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图 11 基于(a)纳米颗粒阵列^[69]和(b)介质光栅^[71]的SPPs布拉格反射; (c) SPPs全息^[72]; (d) SPPs的艾里光束激发^[73]

Figure 11. Bragg reflections based on (a) nanoparticle array^[69] and (b) dielectric grating^[71]; (c) SPP holography^[72]; (d) SPPs Airy beam generation^[73].

DownLoad: Full-Size Img PowerPoint

图 12 (a) 真实的超构表面结构及(b)其对SPPs的反射系数^[89]

Figure 12. (a) Practical metasurface and (b) corresponding SPPs reflection coefficients^[89].

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图 13 (a) 超构表面样品; (b), (c) 模拟和(d) 实验验证SPPs异常反射^[89]

Figure 13. (a) Metasurface sample and (b), (c) numerical / (d) experimental verifications of SPPs anomalous reflection^[89].

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图 14 超构表面实现(a) SPPs贝塞尔光束激发和(b)SPPs聚焦效应^[89]

Figure 14. Metasurfaces for (a) SPPs Bessel beam generation and (b) SPPs focusing^[89].

DownLoad: Full-Size Img PowerPoint

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[9]	Hutter E, Fendler J H 2004 Adv. Mater. 16 1685 Google Scholar
[10]	Mühlschlegel P, Eisler H J, Martin O J F, Hecht B, Pohl D W 2005 Science 308 1607 Google Scholar
[11]	Beeck O, Ritchie AW 1950 Discuss. Faraday Soc. 8 159 Google Scholar
[12]	Pendry J B, Martin-Moreno L, Garcia-Vidal F J 2004 Science 305 847 Google Scholar
[13]	Hibbins A P, Evans B R, Sambles J R 2005 Science 308 670 Google Scholar
[14]	Maier S A, Andrews S R, Martín-Moreno L, García-Vidal F J 2006 Phys. Rev. Lett. 97 176805 Google Scholar
[15]	Sun S, He Q, Xiao S, Xu Q, Li X, Zhou L 2012 Nat. Mater. 11 426 Google Scholar
[16]	Elser J, Podolskiy V A 2008 Phys. Rev. Lett. 100 066402 Google Scholar
[17]	Oulton R F, Sorger V J, Zentgraf T, Ma R M, Gladden C, Dai L, Bartal G, Zhang X 2009 Nature 461 629 Google Scholar
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[21]	Maier S A, Brongersma M L, Kik P G, Meltzer S, Requicha A A G, Atwater H A 2001 Adv. Mater. 13 1501 Google Scholar
[22]	Law M, Sirbuly D J, Johnson J C, Goldberger J, Saykally R J, Yang P 2004 Science 305 1269 Google Scholar
[23]	Ditlbacher H, Hohenau A, Wagner D, Kreibig U, Rogers M, Hofer F, Aussenegg F R, Krenn J R 2005 Phys. Rev. Lett. 95 257403 Google Scholar
[24]	Yin L, Vlasko-Vlasov V K, Pearson J, Hiller J M, Hua J, Welp U, Brown D E, Kimball C W 2005 Nano. Lett. 5 1399 Google Scholar
[25]	Wei H, Wang Z, Tian X, Käll M, Xu H 2011 Nat. Commun. 2 387 Google Scholar
[26]	Zia R, Schuller J A, Chandran A, Brongersma M L 2006 Mater. Today 9 20 Google Scholar
[27]	Ekmel Ozbay 2006 Science 311 189 Google Scholar
[28]	Lal S, Link S, Halas N J 2007 Nat. Photonics 1 641 Google Scholar
[29]	Ebbesen T W, Genet C, Bozhevolnyi S I 2008 Phys. Today 61 44 Google Scholar
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[31]	Verhagen E, Spasenović M, Polman A, Kuipers L 2009 Phys. Rev. Lett. 102 203904 Google Scholar
[32]	Gramotnev D K, Bozhevolnyi S I 2010 Nat. Photonics 4 83 Google Scholar
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[34]	Stegeman G I, Glass N E, Maradudin A A, Shen T P, Wallis R F 1983 Opt. Lett. 8 626 Google Scholar
[35]	Kocabaş Ş E, Veronis G, Miller D A B, Fan S 2008 IEEE 14 1462 Google Scholar
[36]	Oulton R F, Pile D F P, Liu Y, Zhang X 2007 Phys. Rev. B 76 035408 Google Scholar
[37]	Chaves A J, Amorim B, Bludov Y V., Gonçalves P A D, Peres N M R 2018 Phys. Rev. B 97 035434 Google Scholar
[38]	Guan F, Sun S, Ma S, Fang Z, Zhu B. Li X, He Q, Xiao S, Zhou L 2018 J. Phys. Condens. Matter 30 114002 Google Scholar
[39]	Hao J, Zhou L 2008 Phys. Rev. B 77 094201 Google Scholar
[40]	Tang S, Zhu B, Jia M, He Q, Sun S, Mei Y, Zhou L 2015 Phys. Rev. B 91 174201 Google Scholar
[41]	Li J, Zhou L, Chan C T, Sheng P 2003 Phys. Rev. Lett. 90 083901 Google Scholar
[42]	Hessel A, Oliner A A 1965 Appl. Opt. 4 1275 Google Scholar
[43]	Bozhevolnyi S I, Volkov V S, Devaux E, Laluet J Y, Ebbesen T W 2006 Nature 440 508 Google Scholar
[44]	Stockman M I 2006 Nano Lett. 6 2604 Google Scholar
[45]	Liu Y, Zentgraf T, Bartal G, Zhang X 2010 Nano Lett. 10 1991 Google Scholar
[46]	Miyu O, Kato J, Kawata S 2011 Science 332 218 Google Scholar
[47]	Yu L, Lin D, Chen Y, Chang Y, Huang K, Liaw J, Yeh J, Liu J, Yeh C, Lee C 2005 Phys. Rev. B 71 041405(R)Google Scholar
[48]	Kim S, Lim Y, Kim H, Park J, Lee B 2008 Appl. Phys. Lett. 92 013103 Google Scholar
[49]	Kumar M S, Piao X, Koo S, Yu S, Park N 2010 Opt. Express 18 8800 Google Scholar
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[51]	Jiang Q, Bao Y, Lin F, Zhu X, Zhang S, Fang Z 2018 Adv. Funct. Mater. 28 1705503 Google Scholar
[52]	Maradudin A A, Visscher W M 1985 Z. Phys. B: Condens. Matter 60 215 Google Scholar
[53]	Shchegrov A, Novikov I, Maradudin A 1997 Phys. Rev. Lett. 78 4269 Google Scholar
[54]	Sanchez-Gil J A, Maradudin A A 1999 Phys. Rev. B 60 8359 Google Scholar
[55]	Evlyukhin A B, Bozhevolnyi S I 2015 Phys. Rev. B 92 245419 Google Scholar
[56]	Nikitin A Y, López-Tejeira F, Martín-Moreno L 2007 Phys. Rev. B 75 035129 Google Scholar
[57]	Brucoli G, Martín-Moreno L. 2011 Phys. Rev. B 83 045422 Google Scholar
[58]	Al-Bader S, Jamid H 2007 Phys. Rev. B 76 235410 Google Scholar
[59]	Guan F, Sun S, Xiao S, He Q, Zhou L 2019 Sci. Bull. 64 802 Google Scholar
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