Hybrid photonic-plasmonic molecule based on metal/Si disks Qing Wang, 1 Hang Zhao,1 Xu Du, 1 Weichun Zhang,1 Min Qiu,1, 2 and Qiang Li 1,* 1

State Key Laboratory of Modern Optical Instrumentation, Department of Optical Engineering, Zhejiang University, 310027, Hangzhou, China 2 School of Information and Communication Technology, KTH Royal Institute of Technology, Electrum 229, 16440, Kista, Sweden * [email protected]

Abstract: Optical properties of two identical coupled disks forming a “hybrid photonic-plasmonic molecule” are investigated. Each disk is a metal-dielectric structure supporting hybrid plasmonic-photonic whispering-gallery (WG) modes. The WG modes of a molecule split into two groups of nearly-degenerate modes, i.e., bonding and anti-bonding modes. The oscillation of quality factor (Q) with the inter-disk gap d and significant enhancement at certain inter-disk gaps can be observed. An enhanced Q factor of 1821 for a hybrid photonic-plasmonic molecule composed of two 1.2 μm-diameter disks, compared with that for a single disk, is achieved. The corresponding Purcell factor is 191, making the hybrid photonic-plasmonic molecule an optimal choice for subwavelengthscale device miniaturization and light-matter interactions. Moreover, the far-field emission pattern of the hybrid photonic-plasmonic molecule exhibits an enhanced directional light output by tuning the azimuthal mode number for both bonding and anti-bonding modes. ©2013 Optical Society of America OCIS codes: (250.5403) Plasmonics; Subwavelength structures, nanostructures.

(230.4555)

Coupled

resonators;

(310.6628)

References and links 1.

M. Bayer, T. Gutbrod, J. P. Reithmaier, A. Forchel, T. L. Reinecke, P. A. Knipp, A. A. Dremin, and V. D. Kulakovskii, “Optical modes in photonic molecules,” Phys. Rev. Lett. 81(12), 2582–2585 (1998). 2. H. Lin, J. H. Chen, S. S. Chao, M. C. Lo, S. D. Lin, and W. H. Chang, “Strong coupling of different cavity modes in photonic molecules formed by two adjacent microdisk microcavities,” Opt. Express 18(23), 23948– 23956 (2010). 3. E. I. Smotrova, A. I. Nosich, T. M. Benson, and P. Sewell, “Threshold reduction in a cyclic photonic molecule laser composed of identical microdisks with whispering-gallery modes,” Opt. Lett. 31(7), 921–923 (2006). 4. E. I. Smotrova, A. I. Nosich, T. M. Benson, and P. Sewell, “Optical coupling of whispering-gallery modes of two identical microdisks and its effect on photonic molecule lasing,” IEEE J. Sel. Top. Quantum Electron. 12(1), 78–85 (2006). 5. S. Ishii, A. Nakagawa, and T. Baba, “Modal characteristics and bistability in twin microdisk photonic molecule lasers,” IEEE J. Sel. Top. Quantum Electron. 12(1), 71–77 (2006). 6. J. W. Ryu, S. Y. Lee, C. M. Kim, and Y. J. Park, “Directional interacting whispering-gallery modes in coupled dielectric microdisks,” Phys. Rev. A 74(1), 013804 (2006). 7. J. V. Hryniewicz, P. P. Absil, B. E. Little, R. A. Wilson, and P. T. Ho, “Higher order filter response in coupled microring resonators,” IEEE Photon. Technol. Lett. 12(3), 320–322 (2000). 8. M. D. Barnes, S. M. Mahurin, A. Mehta, B. G. Sumpter, and D. W. Noid, “Three-dimensional photonic “molecules” from sequentially attached polymer-blend microparticles,” Phys. Rev. Lett. 88(1), 015508 (2001). 9. V. N. Astratov, J. P. Franchak, and S. P. Ashili, “Optical coupling and transport phenomena in chains of spherical dielectric microresonators with size disorder,” Appl. Phys. Lett. 85(23), 5508–5510 (2004). 10. Y. P. Rakovich, J. F. Donegan, M. Gerlach, A. L. Bradley, T. M. Connolly, J. J. Boland, N. Gaponik, and A. Rogach, “Fine structure of coupled optical modes in photonic molecules,” Phys. Rev. A 70(5), 051801 (2004). 11. E. Ozbay, M. Bayindir, I. Bulu, and E. Cubukcu, “Investigation of localized coupled-cavity modes in twodimensional photonic bandgap structures,” IEEE J. Quantum Electron. 38(7), 837–843 (2002). 12. S. V. Boriskina, T. M. Benson, and P. Sewell, “Photonic molecules made of matched and mismatched

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11037

13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42.

microcavities: new functionalities of microlasers and optoelectronic components,” Proc. SPIE 6452, 64520X, 64520X-10 (2007). L. Shang, L. Liu, and L. Xu, “Single-frequency coupled asymmetric microcavity laser,” Opt. Lett. 33(10), 1150–1152 (2008). F. Xia, M. Rooks, L. Sekaric, and Y. Vlasov, “Ultra-compact high order ring resonator filters using submicron silicon photonic wires for on-chip optical interconnects,” Opt. Express 15(19), 11934–11941 (2007). A. A. Savchenkov, V. S. Ilchenko, A. B. Matsko, and L. Maleki, “High-order tunable filters based on a chain of coupled crystalline whispering gallery-mode resonators,” IEEE Photon. Technol. Lett. 17(1), 136–138 (2005). M. J. Hartmann, F. G. S. L. Brandao, and M. B. Plenio, “Quantum many-body phenomena in coupled cavity arrays,” Laser Photon. Rev. 2(6), 527–556 (2008). T. W. Lu and P. T. Lee, “Ultra-high sensitivity optical stress sensor based on double-layered photonic crystal microcavity,” Opt. Express 17(3), 1518–1526 (2009). S. V. Boriskina, “Spectrally engineered photonic molecules as optical sensors with enhanced sensitivity: a proposal and numerical analysis,” J. Opt. Soc. Am. B 23(8), 1565–1573 (2006). S. V. Boriskina, “Theoretical prediction of a dramatic Q-factor enhancement and degeneracy removal of whispering gallery modes in symmetrical photonic molecules,” Opt. Lett. 31(3), 338–340 (2006). S. V. Boriskina, “Photonic molecules and spectral engineering,” in Photonic microresonator research and applications, I. Chremmos, O. Schwelb, and N. Uzonoglu, eds. (Springer, New York, 2010). S. V. Boriskina, T. M. Benson, P. Sewell, and A. I. Nosich, “Effect of a layered environment on the complex natural frequencies of two-dimensional WGM dielectric-ring resonators,” J. Lightwave Technol. 20(8), 1563– 1572 (2002). J. Yang, C. Sauvan, A. Jouanin, S. Collin, J. L. Pelouard, and P. Lalanne, “Ultrasmall metal-insulator-metal nanoresonators: impact of slow-wave effects on the quality factor,” Opt. Express 20(15), 16880–16891 (2012). S. V. Boriskina, V. Pishko, and A. V. Boriskin, “Optical spectra and output coupling engineering in hybrid WGmode micro-and meso-scale cavity structures,” in Transparent Optical Networks, 2006 International Conference on (IEEE, 2006), pp. 84–87. B. Min, E. Ostby, V. Sorger, E. Ulin-Avila, L. Yang, X. Zhang, and K. Vahala, “High-Q surface-plasmonpolariton whispering-gallery microcavity,” Nature 457(7228), 455–458 (2009). M. Kuttge, F. J. García de Abajo, and A. Polman, “Ultrasmall mode volume plasmonic nanodisk resonators,” Nano Lett. 10(5), 1537–1541 (2010). S. H. Kwon, “Deep subwavelength plasmonic whispering-gallery-mode cavity,” Opt. Express 20(22), 24918– 24924 (2012). Y. Song, J. Wang, M. Yan, and M. Qiu, “Subwavelength hybrid plasmonic nanodisk with high Q factor and Purcell factor,” J. Opt. 13(7), 075001 (2011). S. V. Boriskina and B. M. Reinhard, “Adaptive on-chip control of nano-optical fields with optoplasmonic vortex nanogates,” Opt. Express 19(22), 22305–22315 (2011). Y. Hong, M. Pourmand, S. V. Boriskina, and B. M. Reinhard, “Enhanced light focusing in self-assembled optoplasmonic clusters with subwavelength dimensions,” Adv. Mater. 25(1), 115–119 (2013). M. A. Santiago-Cordoba, S. V. Boriskina, F. Vollmer, and M. C. Demirel, “Nanoparticle-based protein detection by optical shift of a resonant microcavity,” Appl. Phys. Lett. 99(7), 073701 (2011). S. V. Boriskina and B. M. Reinhard, “Spectrally and spatially configurable superlenses for optoplasmonic nanocircuits,” Proc. Natl. Acad. Sci. U.S.A. 108(8), 3147–3151 (2011). S. V. Boriskina, M. Povinelli, V. N. Astratov, A. V. Zayats, and V. A. Podolskiy, “Collective phenomena in photonic, plasmonic and hybrid structures,” Opt. Express 19(22), 22024–22028 (2011). R. F. Oulton, V. J. Sorger, D. A. Genov, D. Pile, and X. Zhang, “A hybrid plasmonic waveguide for subwavelength confinement and long-range propagation,” Nat. Photonics 2(8), 496–500 (2008). M. Z. Alam, J. Meier, J. S. Aitchison, and M. Mojahedi, “Super mode propagation in low index medium,” in CLEO 2007, paper JTHD112. K. S. Yee, “Numerical solution of initial boundary value problems involving Maxwell's equations in isotropic media,” IEEE Trans. Antenn. Propag. 14(3), 302–307 (1966). J. P. Berenger, “A perfectly matched layer for the absorption of electromagnetic waves,” J. Comput. Phys. 114(2), 185–200 (1994). P. B. Johnson and R. W. Christy, “Optical constants of the noble metals,” Phys. Rev. B 6(12), 4370–4379 (1972). K. A. Atlasov, K. F. Karlsson, A. Rudra, B. Dwir, and E. Kapon, “Wavelength and loss splitting in directly coupled photonic-crystal defect microcavities,” Opt. Express 16(20), 16255–16264 (2008). S. V. Boriskina, T. M. Benson, P. D. Sewell, and A. I. Nosich, “Directional emission, increased free spectral range, and mode Q-factors in 2-D wavelength-scale optical microcavity structures,” IEEE J. Sel. Top. Quantum Electron. 12, 1175–1182 (2006). K. Oda, N. Takato, and H. Toba, “A wide-FSR waveguide double-ring resonator for optical FDM transmission systems,” J. Lightwave Technol. 9(6), 728–736 (1991). X. Wu, H. Li, L. Liu, and L. Xu, “Unidirectional single-frequency lasing from a ring-spiral coupled microcavity laser,” Appl. Phys. Lett. 93(8), 081105 (2008). S. V. Boriskina, T. M. Benson, P. Sewell, and A. I. Nosich, “Q factor and emission pattern control of the WG modes in notched microdisk resonators,” IEEE J. Sel. Top. Quantum Electron. 12(1), 52–58 (2006).

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11038

43. A. Taflove, Computational Electrodynamics: The Finite-Difference Time-Domain Method (Artech House, inc., Norwood, MA, 1995). 44. M. T. Hill, H. J. Dorren, T. De Vries, X. J. Leijtens, J. H. Den Besten, B. Smalbrugge, Y. S. Oei, H. Binsma, G. D. Khoe, and M. K. Smit, “A fast low-power optical memory based on coupled micro-ring lasers,” Nature 432(7014), 206–209 (2004). 45. D. Englund, D. Fattal, E. Waks, G. Solomon, B. Zhang, T. Nakaoka, Y. Arakawa, Y. Yamamoto, and J. Vucković, “Controlling the spontaneous emission rate of single quantum dots in a two-dimensional photonic crystal,” Phys. Rev. Lett. 95(1), 013904 (2005).

1. Introduction Photonic molecules composed of a cluster of mutually-coupled optical microcavities have aroused keen interest in the last decade [1]. Conventional configurations of photonic molecules include two or more optical resonators, such as microdisks, microrings, microspheres and point-defect cavities in photonic crystals, etc [2–12]. By playing with the structures and the compositions of the microcavities, photonic molecules can be optimized to exhibit many unique optical properties including light confinements in the wavelength-scale. Therefore, the photonic molecule is regarded as one of key components for a variety of optical applications, such as low-threshold semiconductor microlasers [3, 12, 13], optical filters and switches [7, 14, 15], information processing [16], biochemical sensing [17, 18], et al. Most optical microcavities designed so far are based on dielectric materials. Hence a further size reduction is hindered by the diffraction [19–21]. Moreover, as the size of a disk cavity decreases, the total internal reflection of the microcavity becomes weak, resulting into an increase in the mode radiation loss and an exponential decrease in the quality factor (Q) [20]. Thus the desire for a high Q and that for device miniaturization seem contradictory. Recently the plasmonic cavities, which are capable of further reducing the mode volume to subwavelength scale while maintaining a relatively high Q due to the effect of surface plasmon polaritons (SPPs), are proposed as an alternative [22–27]. Earlier efforts dedicated to the plasmonic microcavities mainly focused on a single disk [22–27]. Few of them have investigated the coupling between plasmonic disks. Previous studies on the hybrid photonic-plasmonic geometry have shown many functionalities [28– 32]. Ref [28] has shown cascaded nanoscale hot-spot intensity enhancement in a hybrid photonic-plasmonic structure composed of an Au nanoparticle dimer and a dielectric microcavity. Ref [29] has demonstrated significant enhancement and redistribution of the magnetic field in the hybrid metallo-dielectric clusters. Ref [30] has shown a whisperinggallery-mode biosensor based on wavelength shifts of a hybrid photonic-plasmonic structure composed of a gold nanoparticle and a silica microsphere. Ref [31] has demonstrated a spectrally and spatially configurable hybrid photonic-plasmonic superlens composed of a polystyrene microsphere and two Au nanodimers. In this paper, a hybrid photonic-plasmonic molecule consisting of two identical metal/Si microdisks is investigated. Unlike previous hybrid metallo-dielectric structures composed of nanoparticles and microcavities [28–32], the hybrid photonic-plasmonic molecule reported here can achieve a good field confinement and enhancement [27, 33, 34]. Moreover, the characteristics of whispering gallery (WG) mode splitting can be observed in the hybrid photonic-plasmonic molecule. The single-disk mode splits into red-shifted bonding modes and blue-shifted anti-bonding modes. The shift of resonant wavelength decreases with inter-disk gap d varying from 0 to 1200 nm. Meanwhile, a highly enhanced Q factor of 1821 corresponding to a high Purcell factor of 191 can be achieved at the resonant wavelength of 1025 nm. This is an extremely large improvement over conventional photonic molecules in terms of reducing the mode volume while maintaining a relatively high Q factor [4, 19, 20]. In addition, the far-field emission patterns in the H-plane and the E-plane for the bonding modes and the anti-bonding modes are studied. The possibility of manipulating the emission pattern by tuning the azimuthal mode number is demonstrated.

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11039

2. The structure of the hybrid photonic-plasmonic molecule The hybrid photonic-plasmonic molecule consists of two identical 1.2 μm-diameter disks on a silica substrate. As shown in Fig. 1, the disk is a sandwich-like geometry, which is composed of the top silver layer, the middle alumina and the bottom silicon. Numerical simulation based on our home-made three-dimensional finite-difference time-domain (FDTD) code is conducted to model the hybrid photonic-plasmonic molecule [35, 36]. The total computation domain is 4.4 μm × 4 μm × 1.2 μm along the x, y and z directions. The spatial resolution is 15 nm in the x and y direction and 10 nm in the z direction. The absorbing boundary condition used in the simulation is perfectly matched layers (PMLs). The permittivities of the silica substrate and the silicon layer are ε SiO = 2.1 and ε Si = 11.9, 2

respectively. The lower index layer is alumina with a permittivity of ε Al2 O3 = 3. The dispersive permittivity of silver is modeled according to the Drude model which is fitted with experimental data [37]. The heights of each layer are hSi = 250 nm, hAg = 100 nm and hAl2 O3 = 50 nm, respectively. For a practical device, a layer of silica is usually deposited atop

to prevent it from oxidizing.

Fig. 1. Schematic diagram of the hybrid photonic- plasmonic molecule consisting of two disks.

Two kinds of modes can be excited in the proposed structure, i.e., transverse electric (TE) mode and transverse magnetic (TM) mode. For the hybrid photonic-plasmonic TM mode, most portion of energy is confined in the low-index layer. While for the dielectric TE mode, most portion of energy is stored in the silicon layer. Therefore, the TM mode is more promising for achieving subwavelength application than the TE mode and we only discuss the TM mode in this paper. Resonant WG modes in individual microdisk are double degenerate and characterized by two mode numbers, corresponding to the radial mode number (n) and the azimuthal mode number (m) [20]. The fundamental modes (with n = 1) are mostly related to practical applications because of their high Q factors and small mode volumes. So we only classify the modes of the hybrid photonic-plasmonic disks in terms of the azimuthal mode number m. 3. Mode splitting in the hybrid photonic-plasmonic molecule Similar to the photonic molecules, when two hybrid photonic-plasmonic atoms (disks) are brought into proximity, their WG modes will couple and split into two double-degenerate WG modes, i.e., bonding (even) and anti-bonding (odd) modes, depending on symmetry of the mode with respect to the y-axis. If we consider the mode symmetry with respect to the xaxis further, the bonding (even) mode includes x-even/y-even (EE) mode and x-odd/y-even

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11040

(OE) mode. While for the anti-bonding (odd) mode, it includes x-even/y-odd (EO) mode and x-odd/y-odd (OO) mode. Figure 2 illustrates the mode-splitting behavior in a hybrid photonic-plasmonic molecule composed of two 1.2 μm diameter disks. For a single disk, there is a resonant mode with the azimuthal number m = 8 at the wavelength λ = 1025 nm. When the two disks are brought together with an inter-disk gap of d = 120 nm, the singledisk mode splits into red-shifted bonding modes (resonant wavelength λ = 1028 nm (OE) and λ = 1026 nm (EE)) and blue-shifted anti-bonding modes (resonant wavelength λ = 1023 nm (OO) and λ = 1022 nm (EO)). The profile of the dominant electric field component Ez over the x-y plane in the center of the alumina layer is shown in Fig. 2(a). Figure 2(b) shows the profile of the electric field Ez in the x-z plane for EE mode. Most of the electric field is confined within the disk edge of the middle layer, yielding a rather small mode volume.

Fig. 2. Mode splitting in a hybrid photonic-plasmonic molecule with an inter-disk gap d = 120 nm. (a) The profiles of the electric field Ez in the x-y plane of bonding (OE, EE) and antibonding (OO, EO) modes for m = 8. (b) The profile of the electric field Ez in the x-z plane for EE mode.

To gain more insight into the mode splitting, the resonant wavelength against the interdisk gap is plotted in Fig. 3(a). The resonant wavelength differences decrease when the distance increases from 0 to 320 nm due to an increasingly weakened coupling strength. When the distance increases further from 320 nm to 1200 nm, oscillations of the resonant wavelengths can be observed. The oscillations can be attributed to oscillatory behavior of the evanescent field. This oscillatory behavior has also been shown in Refs [3, 4, 18, 19]. When the inter-disk separation is large enough, the four split molecule modes converge to a single resonant wavelength. The coupling strength between the WG modes of disks (which is represented by the difference between the resonant wavelengths of the bonding and the antibonding modes) decreases with the increasing distance. The difference of the resonant wavelength Δλ is also related to the azimuthal mode number. For increasing azimuthal mode number, the resonant wavelengths of WG modes shift to short wavelengths, similar to the case of photonic molecules demonstrated by previous study [3]. The hybrid photonicplasmonic molecule shows excellent ability to bind the short wavelength modes; therefore, the coupling strength decreases as the azimuthal mode number increases. As shown in Fig. 3(b), the difference of the resonant wavelengths λOE–λOO decreases from 22 nm to 5 nm with the azimuthal mode ranging from 4 to 8, while the λEE –λEO decreases from 20 nm to 4 nm.

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11041

Fig. 3. (a) The resonant wavelengths of anti-bonding (OO, EO) and bonding modes(OE, EE) as functions of the distance between the two atoms for the azimuthal-order m = 8, (b) Wavelength differences between bonding modes and anti-bonding modes versus the azimuthal mode number when d = 120 nm.

4. Q factor enhancement of hybrid photonic-plasmonic molecule modes Optical performance of a resonator cavity is evaluated by three major parameters: 1) the quality factor Q, which represents the power of the optical disks to enhance light-matter interactions, is calculated using a combination of FDTD techniques and Padé approximation with Baker's algorithm [35, 36]. 2) the effective mode volume Veff which is vital for the sizereduction of optical devices and 3) the Purcell factor FP, which is related to the ratio of the Q factor and mode volume as [27]: 3

FP =

3  λ0   Q    4π 2  n  V eff 

(1)

where λ0 is the resonant wavelength in free space and n is the refractive index of the lowerindex layer. The effective mode volume is calculated as [27]: 2

V eff =

 ε (x , y , z ) E (x , y , z ) dx dydz

(2) . 2 max{ε (x , y , z ) E (x , y , z ) } A cavity system with a high Q factor and a small mode volume and thus a high Purcell factor is in favor of practical applications. Previous studies have shown that a resonator of a larger size can achieve a higher Q factor and the Q factor increases with the azimuthal mode number m [4, 27]. Here we investigate the case of a high-azimuthal-order (m = 8) in the coupling system. The dependencies of the Q factors for the OE, OO, EE, and EO modes on the distance between disks d are plotted in Fig. 4 and Q factors are found to oscillate with respect to d, which can be explained by “loss splitting” due to an imperfect destructive interference between the WG modes referred in [38]. The highest Q factor of 1821 is obtained for the anti-bonding mode (OO) at d = 540 nm. This is a three times enhancement with respect to that of an isolated hybrid photonic-plasmonic atom (Q = 608). We also plot effective mode volume Veff against the azimuthal mode number ranging from 4 to 8 for all modes at d = 120 nm and d = 540 nm. Figure 5 shows that the increase of effective mode volume is nearly linear with respect to the increasing azimuthal number m. For the same azimuthal mode, Veff keeps almost the same for different modes (OE, OO, EE, and EO modes) at different inter-disk distances (120 nm and 540 nm). The effective mode volume of the hybrid photonic-plasmonic molecule is approximately two times of that of the single disk. So the effect of coupling between the two atoms in the hybrid photonic-plasmonic

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11042

molecule on the mode volume is not significant. The mode volume is predominantly determined by the azimuthal mode number and the number of disks in the coupling system.

Fig. 4. The Q factor as functions of the distance between disks for bonding modes (OE, EE) and anti-bonding modes (OO, EO). The azimuthal-order m is 8. For comparison, the Q factor of an isolated disk (m = 8) is also plotted (dash dot line).

5

0

((λ /2n)3)

6

Mode volume V

eff

4 3 2

OE d = 120 nm OO d = 120 nm EE d = 120 nm EO d = 120 nm OE d = 540 nm OO d = 540 nm EE d = 540 nm EO d = 540 nm single disk

1 0 4

5

6 7 Azimuthal mode number

8

Fig. 5. The effective mode volume Veff against the azimuthal mode number for the bonding modes (OE, EE) and the anti-bonding modes (OO, EO) at d = 120 nm and 540 nm. For comparison, the mode volume of a single disk is also plotted (triangle).

As shown in Fig. 4, the highest Q factor of the hybrid photonic-plasmonic molecule is Q = 1821 at d = 540 nm. Correspondingly, a large Purcell factor FP = 191 can be realized for the hybrid photonic-plasmonic molecule at 1025 nm resonant wavelength. Those properties offered by the hybrid photonic-plasmonic molecule demonstrate a way of reducing the microcavity size to the order of subwavelength scale while maintaining a relatively high Q factor.

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11043

5. The far-field pattern from hybrid photonic-plasmonic molecule High directional radiation and selective mode enhancement are desirable for the applications of microcavities [39–42]. For a single microcavity, the disadvantage of multi-beam emission pattern hinders its further optical applications. When two identical disks are brought into proximity, the far-field emission properties of the hybrid photonic-plasmonic molecule are modified by near-field coupling. The exact emission patterns of the hybrid photonicplasmonic molecule can be quite different among different WG modes. Appropriate control of the mutual coupling between individual cavities forming the hybrid photonic-plasmonic molecule enables enhancement of the directional emission. In our FDTD calculation, the whole structure is first enclosed in a cube to collect nearfield electromagnetic components at resonant wavelengths. Then the far-field patterns are calculated from the Fourier transformed near-field electromagnetic components based on the Green’s theorem [43]. The observed near-field distributions of the hybrid photonicplasmonic molecule are analogous to those of multi-dipoles (m = 7 and 8) arranged along the edge of circle disks. Their far-field emission patterns results from the multi-dipoles (m = 7 and 8) of individual disk and the interactions between coupled disks. The radiations from multi-dipoles of individual disk for m = 7 and m = 8 are different. The interactions between coupled disks further complicate the radiation patterns, leading to a substantial difference between the patterns for m = 7 and m = 8. Figure 6 shows the normalized H-plane emission patterns of the WG modes of m = 7 for individual atom and a hybrid photonic-plasmonic molecule. As for a single disk, there exists multi-beam emission (Fig. 6(a)), while the number of main emission beams decreases in the hybrid photonic-plasmonic molecule. There are main emission beams in the direction of φ = 90° and 270° for OE and EE modes, while these beams disappear for OO and EO modes. Meanwhile, there are negligible emission beams in the direction of φ = 0° and 180° for OE and OO modes. The far-field emission patterns of the hybrid photonic-plasmonic molecule for m = 8 are shown in Fig. 7. The emission pattern for a single disk is similar to that of m = 7. In contrast to the case of bonding modes (OE and EE), the anti-bonding modes (OO and EO) have a better directional emission with four main beams of emission shown in Fig. 7(c) and 7(e).

Fig. 6. The far-field emission patterns of H-plane (a) for the individual disk of WG modes of m = 7, (b), (d) the bonding modes (OE and EE) and (c), (e) the anti-bonding modes (OO and EO) for hybrid photonic-plasmonic molecule.

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11044

Fig. 7. The far-field emission patterns of H-plane (a) for the individual disk of WG modes of m = 8, (b), (d) the bonding modes (OE and EE) and (c), (e) the anti-bonding modes (OO and EO) for hybrid photonic-plasmonic molecule.

Figure 8 shows the normalized E-plane emission patterns of the WG modes of m = 7 for individual hybrid photonic-plasmonic atom and a hybrid photonic-plasmonic molecule. From Fig. 8, the E-plane emission concentrates mainly in the direction of φ = 0° and 180° for the individual disk, OE and EE modes, whereas the electric field emit downward for OO and EO modes. The E-plane emission patterns of m = 8 are shown in Fig. 9, which shows that the directions of main emission beam slope are unique for the four modes. However, there is no emission energy in the direction of φ = 90° and 270° for both a single disk and a hybrid photonic-plasmonic molecule owing to the top silver layer.

Fig. 8. The far-field emission patterns of E-plane (a) for the individual disk of WG modes of m = 7, (b), (d) the bonding modes (OE and EE) and (c), (e) the anti-bonding modes (OO and EO) for hybrid photonic-plasmonic molecule.

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11045

Fig. 9. The far-field emission patterns of E-plane (a) for the individual disk of WG modes of m = 8, (b), (d) the bonding modes (OE and EE) and (c), (e) the anti-bonding modes (OO and EO) for hybrid photonic-plasmonic molecule.

The far-field emission patterns of the hybrid photonic-plasmonic molecule can be efficiently manipulated by varying the azimuthal mode number. Furthermore, the emission pattern of OE mode m = 7 shows enhanced directivity in the H-plane. 6. Conclusions A new type of coupled resonator named “hybrid photonic-plasmonic molecule” comprising of two identical disks is studied. For the molecule, each azimuthal mode can split into two groups of nearly-degenerate modes, i.e., the bonding (OE, EE) and anti-bonding (EO, OO) modes. The coupling strength and shifted resonant wavelength of the two modes decrease with the inter-disk distance. Compared with the photonic molecule, the hybrid photonicplasmonic molecule can acquire a high Purcell factor 191 accompanied by a Q factor of 1821. Moreover, the far-field emission patterns of the coupling WG modes are investigated. The emission patterns of the hybrid photonic-plasmonic molecule show an enhanced directivity in the H-plane with fewer main beams of emission for both bonding and antibonding coupling modes by varying the azimuthal mode number. Compared with photonic molecule geometries, the hybrid photonic-plasmonic molecule cannot only further reduce the cavity size to the subwavelength dimension but also lower the threshold of WG modes lasers, while a high Q factor and a small mode volume are maintained. These capabilities drive its potential applications in a single photon source, laser, optical memory, etc [20, 44]. For example, when a quantum dot is embedded in the hybrid photonic-plasmonic molecule, the optical cavities with increased local density of optical states can enhance the emission rate, which is beneficial for single photon sources [45]. Acknowledgments This work is supported by the National Natural Science Foundation of China (Grant Nos. 61205030, 61275030 and 61235007), the Opened Fund of State Key Laboratory of Advanced Optical Communication Systems and Networks, the Opened Fund of State Key Laboratory on Integrated Optoelectronics, the Fundamental Research Funds for the Central

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11046

Universities (2012QNA5003), Doctoral Fund of Ministry of Education of China (Grant No 20120101120128), the Swedish Foundation for Strategic Research (SSF) and the Swedish Research Council (VR).

#186860 - $15.00 USD Received 12 Mar 2013; revised 23 Apr 2013; accepted 24 Apr 2013; published 29 Apr 2013 (C) 2013 OSA 6 May 2013 | Vol. 21, No. 9 | DOI:10.1364/OE.21.011037 | OPTICS EXPRESS 11047