Top

Published in:

2015 | OriginalPaper | Chapter

9. Planar Hybrid Plasmonic-Photonic Crystals

Author : Sergei G. Romanov

Published in: Nanomaterials and Nanoarchitectures

Publisher: Springer Netherlands

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

The invention of hybrid crystals brought about the simultaneous usage of different mechanisms of light transfer into effect in one and the same architecture. We have discussed the preparation, structure and optical properties of planar hybrid metal-dielectric crystals, light in which is carried by photons and plasmons.

Studied hybrids are based on the monolayers of spheres – the planar hexagonal packages of colloidal beads on a substrate. Two basic modifications, the monolayer on a flat metal film and the corrugated metal film on the monolayer have been prepared. Owing to their topology, hybrid crystals respond to the incident light depending on the wavelength, the polarization and the propagation direction with different optical resonances. The respective resonances are the light diffraction in the planar lattice, the diffraction of surface plasmon polaritons in the periodically profiled film, the localized particle and cavity plasmons in metal semishells and Fabry-Perot oscillations. Besides, interpenetration of plasmonic and photonic crystals results in the efficient hybridization of photonic and plasmonic modes. Overlay of different resonances leads to their further modification described by Fano process.

The apparent complexity of the optical properties is paired by their broad variability either by means of tuning the topology and composition of hybrids or through external stimuli. The simple and inexpensive technology in combination with very rich physics ensures the attractiveness of hybrid crystals for fundamental research and practical applications.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Plasmonic Gas and Chemical Sensing

next chapter Fundamentals and Applications of Organised Molecular Films

Bykov VP (1972) Spontaneous emission in a periodic structure. Sov Phys JETP 35:269; Zengerle R (1987) Light propagation in singly and doubly periodic planar waveguides. J Mod Optics 34:1589; Yablonovitch E (1987) Inhibited spontaneous emission in solid-state physics and electronics. Phys Rev Lett 58:2059; John S (1987) Strong localization of photons in certain disordered dielectric superlattices. Phys Rev Lett 58:2486

John S (1995) Localization of light. In: Soukoulius CM (ed) Photonic band gap materials. Kluwer, Dordrecht, pp 563–735

Mie G (1908) Beitraгge zur Optik truеber Medien, speziell kolloidaler Metalloеsungen. Annalen der Physik, 330, IV Folge, 25(3):377–445; Debye P (1909) Der Lichtdruck auf Kugeln von beliebigem Material. Annalen der Physik, 335, IV Folge, 30(11):57–136

Arnold S (2001) Microspheres, photonic atoms and the physics of nothing. Am Sci 89:414; Arnold S, Folan LM (1989) Energy transfer and the photon lifetime within an aerosol particle. Opt Lett 14:387

Lidorikis E, Sigalas MM, Economou EN, Soukoulis CM (1998) Tight-binding parametrization for photonic band gap materials. Phys Rev Lett 82:1405CrossRef

Kohmoto M, Sutherland B, Iguchi K (1987) Localization of optics: quasiperiodic media. Phys Rev Lett 58:2436–2438; Valy Vardeny Z, Nahata A, Agrawal A (2013) Optics of photonic quasicrystals. Nat Photonics 7:177–187

Romanov SG, Yates HM, Pemble ME, De La Rue RM (2000) Opal-based photonic crystal with double photonic bandgap structure. J Phys: Cond Matter 12:8221; Istrate E, Sargent EH (2006) Photonic crystal heterostructures and interfaces. Rev Mod Phys 78:455

Ivchenko EL, Poddubnyi AN (2013) Resonant diffraction of electromagnetic waves from solids (a review). Phys Solid State 55:905CrossRef

Toader O, John S (2004) Photonic band gap enhancement in frequency-dependent dielectrics. Phys Rev E 70:46605CrossRef

10.

Ivchenko EL, Nezvizhevskii AN, Jorda S (1994) Bragg reflection of light from quantum-well structures. Phys Solid State 36:1156; Kochereshko VP, Pozina GR, Ivchenko EL, Yakovlev DR, Waag A, Ossau W, Landwehr G, Hellmann R, Göbel EO (1994) Giant exciton resonance reflectance in Bragg MQW structures. Superlatt Microstruct 15:471; Merle d’Aubigne Y, Wasiela A, Mariette H, Dietl T (1996) Polariton effects in multiple-quantum-well structures of CdTe/Cd1−xZnxTe. Phys Rev B 54:14003

11.

Fujita T, Sato Y, Kuitani T, Ishihara T (1998) Tunable polariton absorption of distributed feedback microcavities at room temperature. Phys Rev B 57:12428; Yablonskii AL, Muljarov EA, Gippius NA, Tikhodeev SG, Fujita T, Ishihara T (2001) Polariton effect in distributed feedback microcavities. J Phys Soc Jpn 70:1137; Shimada R, Yablonskii AL, Tikhodeev SG, Ishihara T (2002) Transmission properties of two-dimensional photonic crystal slab with an excitonic resonance. IEEE J Quantum Electron 38:872

12.

Matsko AB, Savchenkov AA, Liang W, Ilchenko VS, Seidel D, Maleki L (2009) Collective emission and absorption in a linear resonator chain. Opt Express 17:15210CrossRef

13.

Wood RW (1902) XLII. On a remarkable case of uneven distribution of light in a diffraction grating spectrum. Philos Mag 4:396; Fano U (1941) The theory of anomalous diffraction gratings and of quasi-stationary waves on metallic surfaces (Sommerfeld’s waves). J Opt Soc Am 31:213

14.

Ebbesen TW, Lezec HJ, Ghaemi HF, Thio T, Wolff PA (1998) Extraordinary optical transmission through sub-wavelength hole arrays. Nature 391:667CrossRef

15.

Christ A, Tikhodeev SG, Gippius NA, Kuhl J, Giessen H (2003) Waveguide-plasmon polaritons: strong coupling of photonic and electronic resonances in a metallic photonic crystal slab. Phys Rev Lett 91:183901CrossRef

16.

Barnes WL, Kitson SC, Preist TW, Sambles JR (1997) Photonic surfaces for surface-plasmon polaritons. J Opt Soc Am A 14:1654; Kretschmann M, Maradudin AA (2002) Band structures of two-dimensional surface-plasmon polaritonic crystals. Phys Rev B 66:245408

17.

Teperik TV, Popov VV, García de Abajo FJ (2005) Void plasmons and total absorption of light in nanoporous metallic films. Phys Rev B 71:085408; Teperik TV, García de Abajo FJ, Borisov AG, Abdelsalam M, Bartlett PN, Sugawara Y, Baumberg JJ (2008) Omnidirectional absorption in nanostructured metal surfaces. Nat Photonics 2:299

18.

Chen H, Chan CT, Sheng P (2010) Transformation optics and metamaterials. Nat Mater 9:387CrossRef

19.

Leonhardt U (2006) Optical conformal mapping. Science 312:1777CrossRef

20.

Veselago VG (1968) The electrodynamics of substances with simultaneously negative values of e and μ. Sov Phys Usp 10:509CrossRef

21.

Romanov SG, Regensburger A, Korovin AV, Peschel U (2011) Hybrid colloidal plasmonic photonic crystals. Adv Mater 23:2515CrossRef

22.

Romanov SG (2012) Hybrid metal-dielectric plasmonic-photonic crystals on colloidal platforms. In: Limonov M, De La Rue R (eds) Optical properties of photonic structures: interplay of order and disorder, ch. 8. Taylor & Francis, Oxford, UK

23.

Sanders JV (1964) Colour of precious opal. Nature 204(4964):1151CrossRef

24.

Bogomolov V, Kumzerov Y, Romanov S (1992) Fabrication of three-dimensional superlattices of nanostructures. In: Davies JH, Long AR (eds) Physics of nanostructures. IOP Publishing, Bristol, pp 317–321

25.

Astratov VN, Bogomolov VN, Kaplyanskii AA, Prokofiev AV, Samoilovich LA, Samoilovich SM, Vlasov Yu. A (1995) Optical spectroscopy of opal matrices with CdS embedded in its pores: quantum confinement and photonic band gap effects. Il Nuovo Cimento 17D:1349; Romanov SG, Fokin AV, Tretiakov VV, Butko VY, Alperovich VI, Johnson NP, Sotomayor Torres CM (1996) Optical properties of ordered 3-dimensional arrays of structurally confined semiconductors. J Cryst Growth 159:857

26.

Galisteo-López JF, Ibisate M, Sapienza R, Froufe-Pérez LS, Blanco Á, López C (2011) Self‐assembled photonic structures. Adv Mater 23:30; Bardosova M, Pemble ME, Povey IM, Tredgold RH (2010) The Langmuir-Blodgett approach to making colloidal photonic crystals from silica spheres. Adv Mater 22:3104

27.

Romanov SG, Sotomayor Torres CM (2000) Three-dimensional lattices of nanostructures – template approach. In: Nalwa HS (ed) Handbook of nanostructured materials and technology, vol 4, ch 4. Academic Press, Waltham, pp 231–323CrossRef

28.

Wang Z, Chan CT, Zhang W, Ming N, Sheng P (2001) Three-dimensional self-assembly of metal nanoparticles: possible photonic crystal with a complete gap below the plasma frequency. Phys Rev B 64:113108CrossRef

29.

Romanov SG, Susha AS, Sotomayor Torres CM, Liang Z, Caruso F (2005) Surface plasmon resonance in gold nanoparticle infiltrated dielectric opals. J Appl Phys 97:086103; Jiang Y, Whitehouse C, Li J, Tam WY, Chan CT, Sheng P (2003) Optical properties of metallo-dielectric microspheres in opal structures. J Phys: Condens Matter 15:5871

30.

Moroz A (2002) Metallo-dielectric diamond and zinc-blende photonic crystals. Phys Rev B 66:115109CrossRef

31.

Lu Y, Yin Y, Li Z-Y, Xia Y (2002) Synthesis and self-assembly of Au@SiO₂ core−shell colloids. Nano Lett 2:785; Rodrıguez-Gonzalez B, Salgueirino-Maceira V, Garcıa-Santamarıa F, Liz-Marzan LM (2002) Fully accessible gold nanoparticles within ordered macroporous solids. Nano Lett 2:471

32.

Eradat N, Huang JD, Vardeny ZV, Zakhidov AA, Khayrullin I, Udod I, Baughman RH (2001) Optical studies of metal-infiltrated opal photonic crystals. Synth Metals 116:501; Wang D, Li J, Chan CT, SalgueiriÇo-Maceira VА, Liz-Marzan LM, Romanov S, Caruso F (2005) Optical properties of nanoparticle-based metallodielectric inverse opals. Small 1:122; Perez N, Huls A, Puente D, Gonzalez-Vinas W, Castano E, Olaizola SM (2007) Fabrication and characterization of silver inverse opals. Sensors and Actuators B 126:86; Kozlov МE, Murthy NS, Udod I, Khayrullin II, Baughman RH, Zakhidov AA (2007) Preparation, structural, and calorimetric characterization of bicomponent metallic photonic crystals. Appl Phys A 86:421; Lytle JC, Stein A (2006) Recent progress in synthesis and applications of inverse opals and related macroporous materials prepared by colloidal templating. In: Cao G, Brinker CJ (eds) Annual reviews of nano research, vol 1, ch 1. World Scientific Publishing, New Jersey

33.

Le F, Brandl DW, Urzhumov YA, Wang H, Kundu J, Halas NJ, Aizpurua J, Nordlander P (2008) Metallic nanoparticle arrays: a common substrate for both surface-enhanced Raman scattering and surface-enhanced infrared absorption. ACS Nano 2:707CrossRef

34.

Pennington RC, D’Alessandro G, Baumberg JJ, Kaczmarek M (2009) Spectral properties and modes of surface microcavities. Phys Rev A 79:043822CrossRef

35.

Inoue M (1987) Enhancement of local field by a two-dimensional array of dielectric spheres placed on a substrate. Phys Rev B 36:2852; Kurokawa Y, Miyazaki H, Jimba Y (2004) Optical band structure and near-field intensity of a periodically arrayed monolayer of dielectric spheres on dielectric substrate of finite thickness. Phys Rev B 69:155117

36.

Dushkin CD, Nagayama K, Miwa T, Kralchevsky PA (1993) Colored multilayers from transparent submicrometer spheres. Langmuir 9:3695CrossRef

37.

Shi L, Liu X, Yina H, Zi J (2010) Optical response of a flat metallic surface coated with a monolayer array of latex spheres. Phys Lett A 374:1059; Yu X, Shi L, Han D, Zi J, Braun PV (2010) High quality factor metallodielectric hybrid plasmonic–photonic crystals. Adv Funct Mater 20:1910; Lopez-Garcıa M, Galisteo-Lopez JF, Blanco A, Sanchez-Marcos J, Lopez C, Garcıa-Martın A (2010) Enhancement and directionality of spontaneous emission in hybrid self-assembled photonic–plasmonic crystals. Small 6:1757

38.

Romanov SG, Bardosova M, Povey I, Pemble M, Sotomayor Torres CM (2008) Understanding of transmission in the range of high-order photonic bands in thin opal film. Appl Phys Lett 92:191106; Romanov SG, Bardosova M, Pemble M, Sotomayor Torres CM (2006) (2+1)-dimensional photonic crystals from Langmuir-Blodgett colloidal multilayers. Appl Phys Lett 89:43105

39.

Romanov SG, Vogel N, Bley K, Landfester K, Weiss CK, Orlov S, Korovin AV, Chuiko GP, Regensburger A, Romanova AS, Kriesch A, Peschel U (2012) Probing guided modes in a monolayer colloidal crystal on a flat metral film. Phys Rev B 86:195145CrossRef

40.

Jonson PB, Christy RW (1972) Optical constants of the noble metals. Phys Rev B 6:4370CrossRef

41.

Nikoma J, Loudon R, Tilley DR (1974) Elementary properties of surface polaritons. J Phys: Solid State Phys 7:3547

42.

Mueller KG, Veith M, Mittler-Neher S, Knoll W (1997) Plasmon surface polariton coupling with dielectric gratings and the thermal decomposition of these dielectric gratings. J Appl Phys 82:4172; Li X, Han D, Wu F, Xu C, Liu X, Zi J (2008) Flat metallic surfaces coated with a dielectric grating: excitations of surface plasmon-polaritons and guided modes. J Phys: Condens Matter 20:485001

43.

Vainshtein BK, Fridkin VM, Indenbom VL (2000) Modern crystallography series, vol 2. Springer, Berlin, p 520. ISBN 3-540-67474-8CrossRef

44.

Bobbert PA, Vlieger J (1986) Light scattering by a sphere on a substrate. Phys A 137:209CrossRef

45.

Fucile E, Denti P, Borghese F, Saija R, Sindoni OI (1997) Optical properties of aggregated spheres in the vicinity of a plane surface. J Opt Soc Am A 14:1505CrossRef

46.

Arnoldus HF (2005) Reflection and refraction of multipole radiation by an interface. J Opt Soc Am A 22:190CrossRef

47.

Weber MJ (2003) Handbook of optical materials. CRC Press LLCV, Boca Raton, p 536. ISBN 0-8493-3512-4

48.

Bogomolov VN (1978) Liquids in ultrathin channels (filament and cluster crystals). Sov Phys Usp 21:77CrossRef

49.

Takei H (1999) Surface-adsorbed polystyrene spheres as a template for nanosized metal particle formation: optical properties of nanosized Au particle. J Vac Sci Technol B 17:1906; Himmelhaus M, Takei H (2000) Cap-shaped gold nanoparticles for an optical biosensor. Sens Actuators B Chem 63:24

50.

Aden AL, Kerker M (1951) Scattering of electromagnetic waves from two concentric spheres. J Appl Phys 22:1242; Prodan E, Lee A, Nordlander P (2002) Electronic structure and polarizability of metallic nanoshells. Chem Phys Lett 360:325

51.

Martin-Moreno L, Garcia-Vidal FJ, Lezec HJ, Pellerin KM, Thio T, Pendry JB, Ebbesen TW (2001) Theory of extraordinary optical transmission through subwavelength hole arrays. Phys Rev Lett 86:1114CrossRef

52.

Bonod N, Enoch S, Li L, Popov E, Neviere M (2003) Resonant optical transmission through thin metallic films with and without holes. Opt Express 11:482CrossRef

53.

Farcau C, Astilean S (2007) Probing the unusual optical transmission of silver films deposited on two-dimensional regular arrays of polystyrene microspheres. J Opt A: Pure Appl Opt 9:S345–S349; Landström L, Brodoceanu D, Piglmayer K, Bäuerle D (2006) Extraordinary optical transmission. Appl Phys A 84:373–377; Zhan P, Wang Z, Dong H, Sun J, Wu J, Wang H-T, Zhu S, Ming N, Zi J (2006) The anomalous infrared transmission of gold films on two‐dimensional colloidal crystals. Adv Mater 18:1612–1616; Lezec HJ, Thio T (2004) Diffracted evanescent wave model for enhanced and suppressed optical transmission through subwavelength hole arrays. Optics Express 12:3629

54.

Landstrom L, Brodoceanu D, Bauerle D, Garcia-Vidal FJ, Rodrigo SG, Martin-Moreno L (2009) Extraordinary transmission through metal-coated monolayers of microspheres. Opt Express 17:761CrossRef

55.

Fano U (1961) Effects of configuration interaction on intensities and phase shifts. Phys Rev 124:1866–1875; Genet C, van Exter MP, Woerdman JP (2003) Fano-type interpretation of red shifts and red tails in hole array transmission spectra. Opt Comm 225:331; Miroshnichenko AE, Flach S, Kivshar YS (2010) Fano resonances in nanoscale structures. Rev Mod Phys 82:2257

56.

Ghaemi HF, Thio T, Grupp DE, Ebbesen TW, Lezec HJ (1998) Surface plasmons enhance optical transmission through subwavelength holes. Phys Rev B 58:6779CrossRef

57.

Maaroof AI, Cortie MB, Harris N, Wieczorek L (2008) Mie and Bragg plasmons in subwavelength silver semi-shells. Small 4:2292CrossRef

58.

Ursu I, Mihailescu IN, Prokhorov AM, Konov VI, Tokarev VN (1985) On the role of the periodical structures induced by powerful laser irradiation of metallic surfaces in the energy coupling process. Phys B+C 132:395CrossRef

59.

Charnay C, Lee A, Man S-Q, Moran CE, Radloff C, Bradley RK, Halas NJ (2003) Reduced symmetry metallodielectric nanoparticles: synthesis and plasmonic properties. J Phys Chem B 107:7327CrossRef

Title: Planar Hybrid Plasmonic-Photonic Crystals
Author: Sergei G. Romanov
Publisher: Springer Netherlands
Book: Nanomaterials and Nanoarchitectures
Print ISBN: 978-94-017-9920-1

Electronic ISBN: 978-94-017-9921-8

Copyright Year: 2015
DOI: https://doi.org/10.1007/978-94-017-9921-8_9

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Premium Partners