Abstract
Hybrid materials formed by plasmonic nanostructures and J-aggregates provide a unique combination of highly localized and enhanced electromagnetic field in metal constituent with large oscillator strength and extremely narrow exciton band of the organic component. The coherent coupling of localized plasmons of the multispiked gold nanoparticles (nanostars) and excitons of JC1 dye J-aggregates results in a Rabi splitting reaching 260 meV. Importantly, broad absorption features of nanostars extending over a visible and near-infrared spectral range allowed us to demonstrate double Rabi splitting resulting from the simultaneous coherent coupling between plasmons of the nanostars and excitons of J-aggregates of two different cyanine dyes.
Avoid common mistakes on your manuscript.
Background
J-aggregates of the organic dyes are of significant interest for the development of advanced photonic technologies, thanks to their ability to delocalize and migrate excitonic energy over a large number of aggregated dye molecules [1]. The hybridization of electronic states in strongly coupled hybrid nanosystems consisting of plasmonic nanostructures and J-aggregates results in intriguing quantum electrodynamics phenomena such as Rabi splitting [2]. Optical transitions in this type of hybrid system are schematically illustrated in Figure 1. The absorption spectrum of J-aggregates is governed by optical transition from the electronic ground state │0〉 to a band of localized exciton states │1〉 , which is inhomogeneously broadened due to some energetic disorder which affects exciton localization [3]. In a hybrid metal/J-aggregate system, these exciton excitations can be strongly coupled to the localized surface plasmon (LSP) excitations of a metal nanostructure with a coherent exchange of energy between the excitonic and plasmonic systems, the so-called Rabi oscillation with frequency ΩR. This periodic energy exchange has an analogy with two coupled oscillators where new eigenmodes of the system arise, manifesting itself in the appearance of a double-peaked feature in transmission or absorption spectra [2]. The strength of the coupling is characterized by the value of energy of Rabi splitting, which can be estimated from the spectral distance between these two peaks.
In the strong coupling regime, the value of Rabi splitting depends on the oscillator strength of the exciton as well as on the increase in the local density of the electromagnetic modes and field enhancement both provided by noble metal nanostructures. To date, Rabi splitting arising from coherent coupling between electronic polarizations of plasmonic systems and molecular excitons in J-aggregates of cyanine dyes has been demonstrated for a variety of metal constituents, such as Au, Ag, and Au/Ag colloidal nanoparticles [4, 5], core-shell Au and Ag nanoparticles [6, 7], Ag films [8], spherical nanovoids in Au films [9], Au nanoshells [10], Au nanorods [11, 12], and arrays of Ag nanodisks [13].
Among different plasmonic nanostructures, multispiked gold nanoparticles with a star-like shape [14–17] are of particular interest for the development of photonic devices and sensors based on the strong coupling phenomenon. These nanoparticles consist of a core with typically five to eight arms [18], whose sharp tips give rise to the strong spatial confinement of the electromagnetic field, with enhancement factors similar to those in metallic nanoshell dimers [19, 20]. The coexistence of different plasmon resonances resulting from the hybridization of the core and the individual tips results in the increased number of localized plasmonic modes [19, 21] (as compared to spherical nanoparticles or nanorods) available for the coherent interaction with quantum emitters. Moreover, the hybridization of plasmons localized at the core and the tips of the stars results in the increased effective dipole moment of the tip plasmons and the enlarged cross section for plasmon excitation [19]. In this study, we use these advantages of gold nanostars to develop their hybrid structures with J-aggregates of different organic dyes operating in the strong coupling regime.
Methods
Gold nanostars were synthesized in an aqueous solution using cetyltrimethylammonium bromide (CTAB) as the capping and growth-regulating agent [17]. A transmission electron microscopy (TEM) image of nanostars (obtained using Philips CM20 TEM, Amsterdam, The Netherlands) is shown in Figure 2. TEM image of a single multispiked nanostar is shown as inset in Figure 2.
J-aggregates were formed from the following two dyes: JC1 (5,5′,6,6′-tetrachloro-1,1′,3,3′-tetraethyl-imidacarbocyanine iodide) and S2165 2-[3-[1,1-dimethyl-3-(4-sulfobutyl)-1,3-dihydro-benzo[e]indol-2-ylidene]-propenyl]-1,1-dimethyl-3-(4-sulfobutyl)-1H-benzo[e]indolium hydroxide. J-aggregates of the JC1 dye form spontaneously upon dissolution of this dye in deionized water at pH7, while the formation of J-aggregates of S2165 required the addition of polyethyleneimine (PEI). The reason why we choose these particular dyes was that upon aggregation they develop very narrow absorption bands (J-bands) both located very close to the maximum of nanostar absorption which favors the regime of strong plasmon-exciton coupling in hybrid systems.
Hybrid structures of gold nanostars and the J-aggregates of the JC1 dye were produced by the addition of the concentrated ethanol solution of the dye to an aqueous solution of gold nanostars in the presence of ammonia at pH8. Interactions between nanostars and JC1 molecules of J-aggregates resulted in the formation of chain-like tightly bound agglomerates of gold nanostars interconnected by an organic matter, with a typical appearance exemplified in the scanning electron microscopy image (obtained using an environmental scanning electron microscope Quanta 250 FEG, FEI, Hillsboro, OR, USA) in Figure 3. These agglomerates were separated from the excess of dye molecules or J-aggregates not bound to gold nanostars by centrifugation at 3,800 rpm for 2 min and redispersed in aqueous solution. CTAB, which was used in the synthesis of nanostars, is not only the shape-directing agent for anisotropic growth but also the stabilizer [17] which provides a net positive surface charge to the nanoparticles, making them suitable for the formation of agglomerates with oppositely charged species like J-aggregates due to electrostatic interactions [22–24]. In our case, these interactions favored the formation of chain-like organic/inorganic structures (Figure 3).
The formation of the hybrid structures of two constituent compounds has been further confirmed by surface-enhanced Raman scattering (SERS) measurements using a confocal Raman microscopy setup (Alpha300, 600 mm−1 grating, 3 cm−1 spectral resolution, continuous wave laser excitation at 532 nm, WITec, Ulm, Germany), as the hot spots provided by sharp tips of agglomerated Au nanostars are expected to enhance Raman scattering response of the attached organic compounds [18]. Indeed, the SERS spectrum of the hybrid nanostructures of gold nanostars and the JC1 J-aggregates (red curve in Figure 3) shows identical but by more than an order of magnitude enhanced features as compared to the conventional Raman spectrum of J-aggregates (black curve in Figure 3). Raman micromapping of hybrid gold nanostars/J-aggregate (JC1) complexes dispersed over a glass slide (Figure 3, right inset) directly demonstrates the strong enhancement of the Raman signal at the location of agglomerates.
Results and discussion
The absorption spectrum of Au nanostars exhibits a broad, intense band centered at 623 nm, along with a less intense shoulder at 827 nm (Figure 4a, black curve). J-aggregates of JC1 show a narrow absorption band (J-band) at 595 nm with a full width at half maximum of 7 nm, alongside with a broader absorption band, positioned at the lower wavelength side from the J-band (at 500 nm) which we assign to the absorption of JC1 monomers (Figure 4c) [25]. JC1 dye has extremely poor water solubility, which favors the formation of J-aggregates even at 0.1 μM concentration. For this reason, the peak associated with J-aggregates is always present in the spectra of aqueous solution of JC1, which makes it difficult to measure the absorption spectrum of the dye monomers alone [25]. To ensure that the 500-nm peak assignment to monomer absorption is consistent, we have measured the spectrum of JC1 dye dissolved in methanol where (due to high solubility of the dye) its aggregation is inhibited and only the absorption band of dye monomers can be detected (peak at 517 nm in Figure 4c, dashed line). Taking into account small bathochromic shift caused by solvatochromism [26], this spectrum confirms the 500-nm band assignment.
In the hybrid structure of both nanostars and J-aggregates, the pronounced dip at 590 nm (which corresponds to the absorption wavelength of the J-aggregates) appears as a result of strong coupling of the excited states of J-aggregates and plasmon modes of the nanostars (Figure 4a, blue curve). The wavelength separation between the two peaks in this spectrum (indicated by arrows in Figure 4) is 61 nm, giving the value of Rabi splitting of 213 meV. This value depends on the total absorbance or, in other words, on the concentration of J-aggregates [27], which, for cyanine dye molecules used in this work, can be influenced by the addition of charged polyelectrolytes [28]. This is demonstrated in Figure 4a (green curve), where positively charged polyelectrolyte PEI has been added to gold nanostars and to the JC1 molecules. As a result, Rabi splitting energy increased to 260 meV, which is 13% of the total transition energy (which corresponds to spectral position of the dip), indicating the strong coupling regime between the plasmons and the J-aggregate excitons.
To demonstrate the advantage of using Au nanostars for the strong coupling with J-aggregates, it would be instructive to compare the values of the achieved Rabi splitting with that of a hybrid system consisting of J-aggregates and gold nanorods [29] of similar volume as nanostars. Based on the TEM image (Figure 2), the effective volume of nanostars was estimated approximating their inner core part by a sphere to which the spikes are attached.
The absorption spectrum of Au nanorods used here (Figure 4b, violet curve) exhibits two main resonances: the red-shifted peak at 766 nm corresponds to the longitudinal surface plasmon resonance, whereas the spectral position of the two other bands spanning over the region between 450 and 650 nm is consistent with the wavelengths of the transverse plasmon modes. The absorption band of J-aggregates of JC1 dye (Figure 4c) falls within the spectral region of the blue-shifted band of the nanorods. In the hybrid system of Au nanorods and J-aggregates, which was fabricated in a similar fashion as that of the gold nanostars, a dip at 595 nm (Figure 4b, cyan curve) with Rabi splitting of 185 meV is observed, which is a much smaller value than that demonstrated above for the nanostar-based hybrid system.
Large number of localized plasmon modes in Au nanostars available for coherent coupling with integrated emitters provides the possibility to observe multiple Rabi splitting for the hybrid system where two (or more) different J-aggregate emitters are strongly coupled to gold nanostars. To demonstrate this possibility, we developed a more complex hybrid system integrating nanostars with J-aggregates of not only JC1 but also S2165 dye, whose absorption band is centered at 637 nm, and thus, more than 30 nm red-shifted with respect to the absorption band of JC1 J-aggregates (Figure 5). J-bands of both dyes still fall perfectly within the region of the main feature in the nanostar absorption spectrum. This matching provides a perfect condition for strong coupling. It is well known that the presence of charged polyelectrolytes enhances the tendency of cyanine dyes to form J-aggregates [28, 30, 31]. Moreover, as demonstrated above (Figure 4), the value of the Rabi splitting and therefore the strength of exciton-plasmon coupling can be increased by raising the concentration of J-aggregates, which, in turn, can be controlled by an addition of charged polyelectrolytes. For these reasons, the PEI polyelectrolyte has been used to induce the formation of J-aggregates of both dyes bound to gold nanostars. The absorption spectrum of the resulting complex hybrid system shows two pronounced dips at 590 and 642 nm (Figure 5, red curve), which correspond to the maximum absorption wavelengths of the J-aggregates of JC1 and S2165, respectively. Thus far, the double Rabi splitting was observed with the energies of 187 and 119 meV.
It is well known that in the strong coupling regime, the spectral lineshapes of the hybrid system can be interpreted interchangeably as a result of the plasmon-exciton hybridization (leading to the formation of two distinct mixed states (Rabi effect)) and also by the interference of different excitation pathways (Fano interference) [32]. In the last case, one of the paths is a discreet excitonic state and the other is a quasi-continuum plasmonic state (Figure 1). Depending on whether or not the plasmonic and excitonic resonances are exactly matching, the profile of Fano resonances goes from a symmetric dip to an asymmetric lineshape, respectively [33]. In line with this, the observed asymmetric profiles of both dips in Figure 5 can be interpreted as results of slight mismatch between main resonance in the spectrum of the nanostars and spectral positions of J-aggregate excitonic transitions.
The observed lineshape can be theoretically reproduced using the model of a hybrid nanostructure consisting of a gold nanostar core surrounded by two layers of different J-aggregates [10]. Because direct modeling of nanostar shape is very challenging, we used a more simple approach approximating their shape as an ellipsoid with three different radii and tried to match the experimental plasmon spectra of the nanostars. The dielectric constant of gold was described by the Drude model:
where ω is the frequency of the incident field, ωp is the bulk plasmon frequency, γ ∞ is the collision rate of electrons in Au, and ε∞ is the high-frequency component of the Au dielectric function. The dielectric constant of J-aggregates covering Au nanostars was modeled by a Lorentzian lineshape:
where f n is the reduced oscillator strength, γ n is the line width, ω0n is the transition frequency, and ε∞jn is the high-frequency component of dielectric function of the first (n = 1) and second (n = 2) types of J-aggregates.
The results from the model simulations (Figure 6) corroborated the experimental findings. As the positions of the excitonic resonances are shifted either to the red or to the blue with respect to the nanostar absorption maximum, distinctive asymmetric profiles can be seen in the spectrum of hybrid system.
Conclusions
In conclusion, we introduced hybrid structures consisting of Au nanostars and J-aggregates of the cyanine dyes, where the coherent coupling between the localized plasmons of the metal component and the excitons of the J-aggregates reveals itself in Rabi splitting with the energy up to 260 meV. Owing to the remarkably broad features in the absorption spectra of gold nanostars, we were able to realize double Rabi splitting through their surface plasmon coupling to the excitons of two different dyes. This experimental finding paves the way towards the development on advanced hybrid systems and further investigations of the interaction between multiple emitters mediated by localized plasmons of different metallic nanostructures in the quantum electrodynamics regime. Alongside with the other multicomponent hybrid plexcitonic structures [32, 34], hybrid systems realized and studied here offer a platform for the practical development of nanoscale optoelectronic and quantum information devices.
References
Wurthner F, Kaiser TE, Saha-Moller CR: J-aggregates: from serendipitous discovery to supramolecular engineering of functional dye materials. Angew Chem Int Ed 2011, 50: 3376–3410. 10.1002/anie.201002307
Lidzey DG, Bradley DDC, Virgili T, Armitage A, Skolnick MS, Walker S: Room temperature polariton emission from strongly coupled organic semiconductor microcavities. Phys Rev Lett 1999, 82: 3316–3319. 10.1103/PhysRevLett.82.3316
van Burgel M, Wiersma DA, Duppen K: The dynamics of one-dimensional excitons in liquids. J Chem Phys 1995, 102: 20–33. 10.1063/1.469393
Kometani N, Tsubonishi M, Fujita T, Asami K, Yonezawa Y: Preparation and optical absorption spectra of dye-coated Au, Ag, and Au/Ag colloidal nanoparticles in aqueous solutions and in alternate assemblies. Langmuir 2001, 17: 578–580. 10.1021/la0013190
Wiederrecht GP, Wurtz GA, Hranisavljevic J: Coherent coupling of molecular excitons to electronic polarizations of noble metal nanoparticles. Nano Lett 2004, 4: 2121–2125. 10.1021/nl0488228
Lekeufack DD, Brioude A, Coleman AW, Miele P, Bellessa J, De Zeng L, Stadelmann P: Core-shell gold J-aggregate nanoparticles for highly efficient strong coupling applications. Appl Phys Lett 2010, 96: 253107. 10.1063/1.3456523
Yoshida A, Kometani N: Effect of the interaction between molecular exciton and localized surface plasmon on the spectroscopic properties of silver nanoparticles coated with cyanine dye J-aggregates. J Phys Chem C 2010, 114: 2867–2872. 10.1021/jp9081454
Bellessa J, Bonnand C, Plenet JC, Mugnier J: Strong coupling between surface plasmons and excitons in an organic semiconductor. Phys Rev Lett 2004, 93: 036404. 036401/036404 036401/036404
Sugawara Y, Kelf TA, Baumberg JJ, Abdelsalam ME, Bartlett PN: Strong coupling between localized plasmons and organic excitons in metal nanovoids. Phys Rev Lett 2006, 97: 266808.
Fofang NT, Park T-H, Neumann O, Mirin NA, Nordlander P, Halas NJ: Plexcitonic nanoparticles: plasmon-exciton coupling in nanoshell-J-aggregate complexes. Nano Lett 2008, 8: 3481–3487. 10.1021/nl8024278
Wurtz GA, Evans PR, Hendren W, Atkinson R, Dickson W, Pollard RJ, Harrison W, Bower C, Zayats AV: Molecular plasmonics with tunable exciton-plasmon coupling strength in J-aggregate hybridized Au nanorod assemblies. Nano Lett 2007, 7: 1297–1303. 10.1021/nl070284m
Juluri BK, Lu M, Zheng YB, Huang TJ, Jensen L: Coupling between molecular and plasmonic resonances: effect of molecular absorbance. J Phys Chem C 2009, 113: 18499–18503. 10.1021/jp908215a
Bellessa J, Symonds C, Vynck K, Lemaitre A, Brioude A, Beaur L, Plenet JC, Viste P, Felbacq D, Cambril E, Valvin P: Giant Rabi splitting between localized mixed plasmon-exciton states in a two-dimensional array of nanosize metallic disks in an organic semiconductor. Phys Rev B 2009, 80: 033303.
Nehl CL, Liao H, Hafner JH: Optical properties of star-shaped gold nanoparticles. Nano Lett 2006, 6: 683–688. 10.1021/nl052409y
Rodríguez-Lorenzo L, Àlvarez-Puebla RA, Pastoriza-Santos I, Mazzucco S, Stéphan O, Kociak M, Liz-Marzán LM, García de Abajo FJ: Zeptomol detection through controlled ultrasensitive surface-enhanced Raman scattering. J Am Chem Soc 2009, 131: 4616–4618. 10.1021/ja809418t
Khoury CG, Vo-Dinh T: Gold nanostars for surface-enhanced Raman scattering: synthesis, characterization and optimization. J Phys Chem C 2008, 112: 18849–18859.
Sau TK, Rogach AL, Döblinger M, Feldmann J: One-step high-yield aqueous synthesis of size-tunable multispiked gold nanoparticles. Small 2011, 7: 2188–2194. 10.1002/smll.201100365
Hrelescu C, Sau TK, Rogach AL, Jackel F, Feldmann J: Single gold nanostars enhance Raman scattering. Appl Phys Lett 2009, 94: 153113. 10.1063/1.3119642
Hao F, Nehl CL, Hafner JH, Nordlander P: Plasmon resonances of a gold nanostar. Nano Lett 2007, 7: 729–732. 10.1021/nl062969c
Oubre C, Nordlander P: Finite-difference time-domain studies of the optical properties of nanoshell dimers. J Phys Chem B 2005, 109: 10042–10051. 10.1021/jp044382x
Shao L, Susha AS, Cheung LS, Sau TK, Rogach AL, Wang J: Plasmonic properties of single multispiked gold nanostars: correlating modeling with experiments. Langmuir 2012, 28: 8979–8984. 10.1021/la2048097
Yao H, Morita Y, Kimura K: Effect of organic solvents on J aggregation of pseudoisocyanine dye at mica/water interfaces: morphological transition from three-dimension to two-dimension. J Colloid Interface Sci 2008, 318: 116–123. 10.1016/j.jcis.2007.10.003
Ma X, Urbas A, Li Q: Controllable self-assembling of gold nanorods via on and off supramolecular noncovalent interactions. Langmuir 2012, 28: 16263–16267. 10.1021/la303424x
Maiti NC, Mazumdar S, Periasamy N: J- and H-aggregates of porphyrin-surfactant complexes: time-resolved fluorescence and other spectroscopic studies. J Phys Chem A 1998, 102: 1528–1538.
Dressler C, Beuthan J, Mueller G, Zabarylo U, Minet O: Fluorescence imaging of heat-stress induced mitochondrial long-term depolarization in breast cancer cells. J Fluoresc 2006, 16: 689–695. 10.1007/s10895-006-0110-z
Renge I, Wild UP: Solvent, temperature, and excitonic effects in the optical spectra of pseudoisocyanine monomer and J-aggregates. J Phys Chem A 1997, 101: 7977–7988. 10.1021/jp971371d
Agranovich VM, Litinskaia M, Lidzey DG: Cavity polaritons in microcavities containing disordered organic semiconductors. Phys Rev B 2003, 67: 085311.
Peyratout C, Donath C, Daehne L: Electrostatic interactions of cationic dyes with negatively charged polyelectrolytes in aqueous solution. J Photochem Photobiol Chem 2001, 142: 51–57. 10.1016/S1010-6030(01)00490-7
Nikoobakht B, El-Sayed MA: Preparation and growth mechanism of gold nanorods (NRs) using seed-mediated growth method. Chem Mater 2003, 15: 1957–1962. 10.1021/cm020732l
Peyratout C, Daehne L: Aggregation of thiacyanine derivatives on polyelectrolytes. Phys Chem Chem Phys 2002, 4: 3032–3039. 10.1039/b111581b
Gadde S, Batchelor EK, Kaifer AE: Controlling the formation of cyanine dye H- and J-aggregates with cucurbituril hosts in the presence of anionic polyelectrolytes. Chem Eur J 2009, 15: 6025–6031. 10.1002/chem.200802546
Manjavacas A, de Abajo FJ G, Nordlander P: Quantum plexcitonics: strongly interacting plasmons and excitons. Nano Lett 2011, 11: 2318–2323. 10.1021/nl200579f
Neubrech F, Pucci A, Cornelius TW, Karim S, Garcia-Etxarri A, Aizpurua J: Resonant plasmonic and vibrational coupling in a tailored nanoantenna for infrared detection. Phys Rev Lett 2008, 101: 157403–157404.
Savasta S, Saija R, Ridolfo A, Di Stefano O, Denti P, Borghese F: Nanopolaritons: vacuum Rabi splitting with a single quantum dot in the center of a dimer nanoantenna. ACS Nano 2010, 4: 6369–6376. 10.1021/nn100585h
Acknowledgements
This work was supported by the ETORTEK 2011–2013 project ‘nanoIKER’ from the Department of Industry of the Basque Government and by the Visiting Fellowship program of Ikerbasque Foundation. Helpful discussions with Dr. J. Aizpurua and Prof. A. Chuvilin are gratefully acknowledged.
Author information
Authors and Affiliations
Corresponding author
Additional information
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
AS and DS carried out the synthesis, the assembly of hybrid structures, and the characterization experiments. DM designed and performed the experiments on optical properties of the samples and drafted the manuscript. AR and YR supervised the work and finalized the manuscript. All authors read and approved the final manuscript.
Authors’ original submitted files for images
Below are the links to the authors’ original submitted files for images.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 2.0 International License ( https://creativecommons.org/licenses/by/2.0 ), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
About this article
Cite this article
Melnikau, D., Savateeva, D., Susha, A. et al. Strong plasmon-exciton coupling in a hybrid system of gold nanostars and J-aggregates. Nanoscale Res Lett 8, 134 (2013). https://doi.org/10.1186/1556-276X-8-134
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/1556-276X-8-134