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    Journals >Opto-Electronic Advances >Volume 2 >Issue 4 >Page 180030 > Article
    • Opto-Electronic Advances
    • Vol. 2, Issue 4, 180030 (2019)
    Revealing the plasmon coupling in gold nanochains directly from the near field
    Quan Sun1、2、*, Han Yu1, Kosei Ueno1, Shuai Zu1, Yasutaka Matsuo1, and Hiroaki Misawa1
    Author Affiliations
  • 1Research Institute for Electronic Science, Hokkaido University, Sapporo 001-0021, Japan
  • 2College of Electronic Science and Engineering, Jilin University, Changchun 130012, China
    • show less
    DOI: 10.29026/oea.2019.180030 Cite this Article
    Quan Sun, Han Yu, Kosei Ueno, Shuai Zu, Yasutaka Matsuo, Hiroaki Misawa. Revealing the plasmon coupling in gold nanochains directly from the near field[J]. Opto-Electronic Advances, 2019, 2(4): 180030 Copy Citation Text show less
    References

    [1] Maier S A. Plasmonics: Fundamentals and Applications (Springer, New York, 2007).MaierS APlasmonics: Fundamentals and Applications (Springer, New York, 2007)

    [2] K Ueno, H Misawa. Spectral properties and electromagnetic field enhancement effects on nano-engineered metallic nanoparticles. Phys Chem Chem Phys, 15, 4093-4099(2013).

    [3] K L Kelly, E Coronado, L L Zhao, G C Schatz. The optical properties of metal nanoparticles: the influence of size, shape, and dielectric environment. J Phys Chem B, 107, 668-677(2003).

    [4] N J Halas, S Lal, W S Chang, S Link, P Nordlander. Plasmons in strongly coupled metallic nanostructures. Chem Rev, 111, 3913-3961(2011).

    [5] X L Wang, P Gogol, E Cambril, B Palpant. Near- and far-field effects on the plasmon coupling in gold nanoparticle arrays. J Phys Chem C, 116, 24741-24747(2012).

    [6] H F Song, Q Sun, J Li, F Yang, J H Yang et al. Exotic mode suppression in plasmonic heterotrimer system. J Phys Chem C, 123, 1398-1405(2019).

    [7] S J Barrow, A M Funston, D E Gomez, T J Davis, P Mulvaney. Surface plasmon resonances in strongly coupled gold nanosphere chains from monomer to hexamer. Nano Lett, 11, 4180-4187(2011).

    [8] S A Maier, P G Kik, H A Atwater, S Meltzer, E Harel et al. Local detection of electromagnetic energy transport below the diffraction limit in metal nanoparticle plasmon waveguides. Nat Mater, 2, 229-232(2003).

    [9] Q H Wei, K H Su, S Durant, X Zhang. Plasmon resonance of finite one-dimensional Au nanoparticle chains. Nano Lett, 4, 1067-1071(2004).

    [10] M D Arnold, M G Blaber, M J Ford, N Harris. Universal scaling of local plasmons in chains of metal spheres. Opt Express, 18, 7528-7542(2010).

    [11] R De Waele, A F Koenderink, A Polman. Tunable nanoscale localization of energy on plasmon particle arrays. Nano Lett, 7, 2004-2008(2007).

    [12] M Quinten, A Leitner, J R Krenn, F R Aussenegg. Electromagnetic energy transport via linear chains of silver nanoparticles. Opt Lett, 23, 1331-1333(1998).

    [13] B Willingham, S Link. Energy transport in metal nanoparticle chains via sub-radiant plasmon modes. Opt Express, 19, 6450-6461(2011).

    [14] D Solis Jr, B Willingham, S L Nauert, L S Slaughter, J Olson et al. Electromagnetic energy transport in nanoparticle chains via dark plasmon modes. Nano Lett, 12, 1349-1353(2012).

    [15] M L Brongersma, J W Hartman, H A Atwater. Electromagnetic energy transfer and switching in nanoparticle chain arrays below the diffraction limit. Phys Rev B, 62, R16356-R16359(2000).

    [16] S A Maier, P G Kik, H A Atwater. Observation of coupled plasmon-polariton modes in Au nanoparticle chain waveguides of different lengths: estimation of waveguide loss. Appl Phys Lett, 81, 1714-1716(2002).

    [17] S A Maier, M L Brongersma, P G Kik, H A Atwater. Observation of near-field coupling in metal nanoparticle chains using far-field polarization spectroscopy. Phys Rev B, 65, 193408(2002).

    [18] H Y Chen, C L He, C Y Wang, M H Lin, D Mitsui et al. Far-field optical imaging of a linear array of coupled gold nanocubes: direct visualization of dark plasmon propagating modes. ACS Nano, 5, 8223-8229(2011).

    [19] S R Pocock, X F Xiao, P A Huidobro, V Giannini. Topological plasmonic chain with retardation and radiative effects. ACS Photonics, 5, 2271-2279(2018).

    [20] M Salerno, J R Krenn, A Hohenau, H Ditlbacher, G Schider et al. The optical near-field of gold nanoparticle chains. Opt Commun, 248, 543-549(2005).

    [21] T Shimada, K Imura, H Okamoto, M Kitajima. Spatial distribution of enhanced optical fields in one-dimensional linear arrays of gold nanoparticles studied by scanning near-field optical microscopy. Phys Chem Chem Phys, 15, 4265-4269(2013).

    [22] S I Kim, K Imura, S Kim, H Okamoto. Confined optical fields in nanovoid chain structures directly visualized by near-field optical imaging. J Phys Chem C, 115, 1548-1555(2011).

    [23] J R Krenn, A Dereux, J C Weeber, E Bourillot, Y Lacroute et al. Squeezing the optical near-field zone by plasmon coupling of metallic nanoparticles. Phys Rev Lett, 82, 2590-2593(1999).

    [24] T Coenen, E J R Vesseur, A Polman, A F Koenderink. Directional emission from plasmonic yagi-uda antennas probed by angle-resolved cathodoluminescence spectroscopy. Nano Lett, 11, 3779-3784(2011).

    [25] Z X Liu, M L Jiang, Y L Hu, F Lin, B Shen et al. Scanning cathodoluminescence microscopy: applications in semiconductor and metallic nanostructures. Opto, 1, 180007(2018).

    [26] A Kubo, K Onda, H Petek, Z J Sun, Y S Jung et al. Femtosecond imaging of surface plasmon dynamics in a nanostructured silver film. Nano Lett, 5, 1123-1127(2005).

    [27] A Kubo, N Pontius, H Petek. Femtosecond microscopy of surface plasmon polariton wave packet evolution at the silver/vacuum interface. Nano Lett, 7, 470-475(2007).

    [28] M Aeschlimann, T Brixner, A Fischer, C Kramer, P Melchior et al. Coherent two-dimensional nanoscopy. Science, 333, 1723-1726(2011).

    [29] L Douillard, F Charra, Z Korczak, R Bachelot, S Kostcheev et al. Short range plasmon resonators probed by photoemission electron microscopy. Nano Lett, 8, 935-940(2008).

    [30] F Schertz, M Schmelzeisen, R Mohammadi, M Kreiter, H J Elmers et al. , 2012, Near field of strongly coupled plasmons: uncovering dark modes. Nano Lett, 12, 1885-1890(2012).

    [31] R Könenkamp, R C Word, J P S Fitzgerald, A Nadarajah, S Saliba. Controlled spatial switching and routing of surface plasmons in designed single-crystalline gold nanostructures. Appl Phys Lett, 101, 141114(2012).

    [32] Q Sun, K Ueno, H Yu, A Kubo, Y Matsuo et al. Direct imaging of the near field and dynamics of surface plasmon resonance on gold nanostructures using photoemission electron microscopy. Light: Sci Appl, 2, e118(2013).

    [33] J H Yang, Q Sun, K Ueno, X Shi, T Oshikiri et al. Manipulation of the dephasing time by strong coupling between localized and propagating surface plasmon modes. Nat Commun, 9, 4858(2018).

    [34] H Yu, Q Sun, K Ueno, T Oshikiri, A Kubo et al. Exploring coupled plasmonic nanostructures in the near field by photoemission electron microscopy. ACS Nano, 10, 10373-10381(2016).

    [35] G Spektor, D Kilbane, A K Mahro, B Frank, S Ristok et al. Revealing the subfemtosecond dynamics of orbital angular momentum in nanoplasmonic vortices. Science, 355, 1187-1191(2017).

    [36] B Y Ji, X W Song, Y P Dou, H Y Tao, X Gao et al. Two-color multiphoton emission for comprehensive reveal of ultrafast plasmonic field distribution. New J Phys, 20, 073031(2018).

    [37] B Y Ji, Q Wang, X W Song, H Y Tao, Y P Dou et al. Disclosing dark mode of femtosecond plasmon with photoemission electron microscopy. J Phys D: Appl Phys, 50, 415309(2017).

    [38] K Ueno, V Mizeikis, S Juodkazis, K Sasaki, H Misawa. Optical properties of nanoengineered gold blocks. Opt Lett, 30, 2158-2160(2005).

    [39] K Ueno, S Juodkazis, V Mizeikis, K Sasaki, H Misawa. Clusters of closely spaced gold nanoparticles as a source of two-photon photoluminescence at visible wavelengths. Adv Mater, 20, 26-30(2008).

    [40] B T Wu, K Ueno, Y Yokota, K Sun, H P Zeng et al. Enhancement of a two-photon-induced reaction in solution using light-harvesting gold nanodimer structures. J Phys Chem Lett, 3, 1443-1447(2012).

    [41] K X Rong, F Y Gan, K B Shi, S S Chu, J J Chen. Configurable integration of on-chip quantum dot lasers and subwavelength plasmonic waveguides. Adv Mater, 30, 1706546(2018).

    [42] M Wang, M Cao, X Chen, N Gu. Subradiant plasmon modes in multilayer metal-dielectric nanoshells. J Phys Chem C, 115, 20920-20925(2011).

    [43] M Z Liu, T W Lee, S K Gray, P Guyot-Sionnest, M Pelton. Excitation of dark plasmons in metal nanoparticles by a localized emitter. Phys Rev Lett, 102, 107401(2009).

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    Quan Sun, Han Yu, Kosei Ueno, Shuai Zu, Yasutaka Matsuo, Hiroaki Misawa. Revealing the plasmon coupling in gold nanochains directly from the near field[J]. Opto-Electronic Advances, 2019, 2(4): 180030
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