Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules

Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules

The simultaneous measurement of Raman and fluorescence signals was proposed to find out the molecule-metal distance. The ratio between Raman and fluorescence intensities was used to estimate molecule-metal distance in nanometer scale. A low-value intensity of the fluorescence of the dye molecules wa...

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Datum:2011
Hauptverfasser: Dvoynenko, M.M., Kazantseva, Z.I., Strelchuk, V.V., Kolomys, O.F., Bortshagovsky, E.G., Venger, E.F., Tronc, P.
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Veröffentlicht: Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України 2011
Schriftenreihe:Semiconductor Physics Quantum Electronics & Optoelectronics
Online Zugang:https://nasplib.isofts.kiev.ua/handle/123456789/117718
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spelling nasplib_isofts_kiev_ua-123456789-1177182025-06-03T16:28:46Z Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules Dvoynenko, M.M. Kazantseva, Z.I. Strelchuk, V.V. Kolomys, O.F. Bortshagovsky, E.G. Venger, E.F. Tronc, P. The simultaneous measurement of Raman and fluorescence signals was proposed to find out the molecule-metal distance. The ratio between Raman and fluorescence intensities was used to estimate molecule-metal distance in nanometer scale. A low-value intensity of the fluorescence of the dye molecules was found using the photobleaching effect. Made was a comparison of experimental results with a theoretical model, which showed well agreement. The authors are thankful to S.A. Zenyo for preparation of Au substrate film. This work was supported by Ukrainian-French projects “Dnipro” of State fund for fundamental researches of Ukraine 2011 Article Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules / M.M. Dvoynenko, Z.I. Kazantseva, V.V. Strelchuk, O.F. Kolomys, E.G. Bortshagovsky, E.F. Venger // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2011. — Т. 14, № 2. — С. 195-199. — Бібліогр.: 22 назв. — англ. 1560-8034 PACS 33.50.-j, 34.35.+a, 73.20.Mf, 78.30.-j https://nasplib.isofts.kiev.ua/handle/123456789/117718 en Semiconductor Physics Quantum Electronics & Optoelectronics application/pdf Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description The simultaneous measurement of Raman and fluorescence signals was proposed to find out the molecule-metal distance. The ratio between Raman and fluorescence intensities was used to estimate molecule-metal distance in nanometer scale. A low-value intensity of the fluorescence of the dye molecules was found using the photobleaching effect. Made was a comparison of experimental results with a theoretical model, which showed well agreement.
format Article
author Dvoynenko, M.M.
Kazantseva, Z.I.
Strelchuk, V.V.
Kolomys, O.F.
Bortshagovsky, E.G.
Venger, E.F.
Tronc, P.
spellingShingle Dvoynenko, M.M.
Kazantseva, Z.I.
Strelchuk, V.V.
Kolomys, O.F.
Bortshagovsky, E.G.
Venger, E.F.
Tronc, P.
Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules
Semiconductor Physics Quantum Electronics & Optoelectronics
author_facet Dvoynenko, M.M.
Kazantseva, Z.I.
Strelchuk, V.V.
Kolomys, O.F.
Bortshagovsky, E.G.
Venger, E.F.
Tronc, P.
author_sort Dvoynenko, M.M.
title Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules
title_short Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules
title_full Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules
title_fullStr Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules
title_full_unstemmed Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules
title_sort probing plasmonic system by the simultaneous measurement of raman and fluorescence signals of dye molecules
publisher Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
publishDate 2011
url https://nasplib.isofts.kiev.ua/handle/123456789/117718
citation_txt Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules / M.M. Dvoynenko, Z.I. Kazantseva, V.V. Strelchuk, O.F. Kolomys, E.G. Bortshagovsky, E.F. Venger // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2011. — Т. 14, № 2. — С. 195-199. — Бібліогр.: 22 назв. — англ.
series Semiconductor Physics Quantum Electronics & Optoelectronics
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AT kazantsevazi probingplasmonicsystembythesimultaneousmeasurementoframanandfluorescencesignalsofdyemolecules
AT strelchukvv probingplasmonicsystembythesimultaneousmeasurementoframanandfluorescencesignalsofdyemolecules
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first_indexed 2025-11-24T15:46:47Z
last_indexed 2025-11-24T15:46:47Z
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fulltext Semiconductor Physics, Quantum Electronics & Optoelectronics, 2011. V. 14, N 2. P. 195-199. PACS 33.50.-j, 34.35.+a, 73.20.Mf, 78.30.-j Probing plasmonic system by the simultaneous measurement of Raman and fluorescence signals of dye molecules M.M. Dvoynenko1, Z.I. Kazantseva1, V.V. Strelchuk1, O.F. Kolomys1, E.G. Bortshagovsky1, E.F. Venger1, P. Tronc2 1V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine, 41, prosp. Nauky, 03028 Kyiv, Ukraine 2Centre National de la Recherche Scientifique, Ecole Superieure de Physique et de Chimie Industrielles de la Ville de Paris, 10 rue Vauquelin, 75005 Paris, France Abstract. The simultaneous measurement of Raman and fluorescence signals was proposed to find out the molecule-metal distance. The ratio between Raman and fluorescence intensities was used to estimate molecule-metal distance in nanometer scale. A low-value intensity of the fluorescence of the dye molecules was found using the photobleaching effect. Made was a comparison of experimental results with a theoretical model, which showed well agreement. Keywords: SERS, photobleaching effect, fluorescence, dye molecule, Au surface. Manuscript received 14.10.10; accepted for publication 16.03.11; published online 30.06.11. 1. Introduction There is a great interest to surface plasmon and related phenomena [1]. Surface and tip enhanced Raman spectroscopies (SERS and TERS) [2], surface plasmon enhanced light emission [3-5] are in a researchers’ focus of interest. The intensity of surface-enhanced fluorescence and SERS depends on the local field and energy transfer from an excited molecule to a metal particle, which depends on the distance between the molecule and metal particle. Thus, to control the molecule-metal distance is of great importance to describe the plasmon system. Dependence of the fluorescence lifetime of dyes on the molecule-metal distance was studied at wavelength [6]- and nm [7]-scale distances. The molecule – single nanoparticle distance dependence of both fluorescence [8, 9] and TERS [10] intensities was experimentally demonstrated. However, separate fluorescence and Raman studies in experiments with many molecules have a problem associated with various molecule numbers. Additionally, the number of molecules situated in light spot during the measurement can be decreased due to photobleaching. Since the photobleaching time depends on the molecule- nanoparticle distance, the distance behaviors of the Raman and fluorescence intensities will be changed for different accumulation times. Simultaneous Raman and fluorescence measurements [11] could resolve this general problem. Indeed, on the one hand, both Raman and fluorescence intensities are determined by the same studying molecule’ numbers, on the other hand, there is a difference between them. Both Raman and fluorescence intensities depend on the electromagnetic enhancement factor [11-13], while the fluorescence intensity depends also on the decay rate [11-13] for molecules, which just reflects the energy transfer from the excited molecule to metal. As a consequence, the ratio between simultaneously measured Raman and fluorescence intensities, cancelling the associated molecule quantity and electromagnetic enhancement factor, is only a function of the decay rate of these molecules that in its turn is strongly sensitive to the molecule-metal distance. The simultaneous Raman and fluorescence measurement was proposed [11] as a way to find the chemical enhancement factor. In the absence of the chemical enhancement it can be used [14] to find the molecular lifetime in steady-state spectroscopy without resorting to time-resolved spectroscopy. Note that the simultaneous observation of Raman and fluorescence signals was reported [15] but there was no analysis or proposals to investigate the distance dependence. Recently [16], the simultaneous measurement of the Raman and fluorescence intensities and an analysis of the molecule-metal distance dependence were done for dye molecules of rhodamine 6G. In this paper, we experimentally study the distance behavior of the ratio between Raman and fluorescence intensities for dye molecules of 2-(4-(p-dimethyl- aminophenyl)-1,3-butadienyl)-3-ethylbenzothoazolium perchlorat (LDS 721 or styryl 8). © 2011, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 195 Semiconductor Physics, Quantum Electronics & Optoelectronics, 2011. V. 14, N 2. P. 195-199. 2. Experiment In this paper, we experimentally demonstrate and analyze the distance dependence of the ratio between Raman and fluorescence intensities of dye molecules of LDS 751 spaced by a thin polymer film at nm-scale distance at a gold substrate. A smooth flat metal surface is chosen because all measured molecules are approximately at the same distance to the metal surface in contrast to island metal films [15]. A smooth gold film with the thickness about 100 nm was prepared by thermal evaporation on a glass substrate. Monolayers prepared using polymer (polyimide) solution in chloroform were investigated by R&K (Wiesbaden, Germany) equipment for Langmuir-Blodgett film (LBF) preparation. LBFs [17] were formed in the standard way of vertical transfer under control of the transfer coefficient and π-A – diagrams. The LBFs were deposited at the surface tension of 20 mN/m by upstrokes to form Z-type structure on the substrates. The dipping rate was 2 mm/min. The LBF thickness was measured ellipsometrically using a laser beam (λ = 0.623 µm; incidence angle 60°). The reversed ellipsometric problem was solved numerically for the “substrate-optically transparent film” model. Ellipsometric measurements with a ten-layer film give both refractive index 1.64 and thickness 0.85±0.15 nm per layer. The refractive index 1.64 is comparable to that obtained previously [18]. LDS 751 molecules were deposited by the dipping with the speed 1 mm/s in water solution of the dye with the concentration of . The confocal micro-Raman and fluorescence spectra were measured by the T64000 Jobin Yvons spectrometer with a thermoelectrically cooled charge coupled device detector. The 514.5-nm line of an Ar M10 5− +/Kr+-ion laser was used as the excitation source. After being reflected from a sharp-edge Raman filter, the laser beam was then focused by an Olympus BX41 microscope equipped with an objective ×100 (numerical aperture (NA) = 0.90) on the sample surface. The net laser intensity on the sample surface was ~5×107 W/m2. The light scattered backward was collected through the same objective and detected with the integration time 20 s. All spectra were measured at the room temperature (T = 300 K). 3. Results and discussion Due to the photobleaching effect, the studied frequency region ( ) was chosen in such a way that a spectrum was measured without rotating the monochromator grating. On the other hand, this frequency range had a maximal value in order to compare various active Raman modes of LDS 751 molecules. The Raman and fluorescence spectra of LDS 751 deposited on a gold substrate with the accumulation time 300 s are shown in Fig. 1.The most pronounced Raman peaks are at 1130, 1280 and . The peak at with the maximal magnitude is in focus of our study. The fluorescence spectrum of LDS 751 is broad with the peak at approximately 751 nm. The Raman and fluorescence spectra at the spacer thicknesses 0.85, 2.55 and 4.25 nm are shown in Fig. 2, which correspond to the number N = 1, 3, 5 of the polyimide monolayers. At the first sight, it can seem that the Raman intensity decreases with the thickness of the spacer. The local field near a flat surface consists of incident and reflected fields. At very small thicknesses (few nanometers) of the spacer, the reflected field can be changed insignificantly. It is likely that the surface to be not enough smooth and the electromagnetic enhancement factor decreases with the distance to some inhomogeneity (the enhancement factor practically does not depend at such nm-scale distances to the surface for ideal plane surface). However, the main reason in the decrease of the Raman intensity with the distance consists in the photobleaching effect during the measurement. As the photobleaching time being a result of a competition between the energy transfer from excited molecule to the metal and relaxation to a triplet state [19] strongly decreases with the spacer thickness, the average number of measured molecules decreases with the distance to metal surface, too. 1cm2500500 −− 1cm1564 − 1cm1564 − Fig. 1. The Raman and fluorescence spectra of LDS 751 deposited on a gold substrate. Fig. 2. The confocal micro-Raman and fluorescence intensities of the LDS 751 on the Raman shift Ω. The characters (a, b, c) indicate curves with the numbers N = 1, 3 and 5 of the polyimide monolayers, respectively. © 2011, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 196 Semiconductor Physics, Quantum Electronics & Optoelectronics, 2011. V. 14, N 2. P. 195-199. Contrary to the Raman signal, the fluorescence intensity cannot be found directly from the data in Fig. 2 due to a small value of the signal and the absence of the information about zero level at the wing of the Rayleigh line. In order to resolve this problem, we used the photobleaching effect. Spectra of LDS 751 at N = 1 obtained for various illumination times before measurements are presented in Fig. 3. The subtraction between the different spectra gives the value of the Raman and fluorescence intensities of molecules that were photo-oxidized. For example, the subtractions Ia–Ib between the curves a and b and Ib–Ic between the curves b and c in Fig. 3 give the correct (without background) Raman and fluorescence intensities of the molecules that were photo-oxidized during the illumination times 20 and 80 s, respectively. By this way, the background level was cancelled and the ratio between Raman and fluorescence intensities IR / Ifl was found for the Raman shifts for all spacer thicknesses. 1cm1564 −=Ω © 2011, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine Fig. 3. The confocal micro-Raman and fluorescence spectra at N = 1 measured after preliminary light illumination at the operation wavelength and intensity for duration 0 (a), 20 (b), and 80 s (c). Fig. 4. Experimental (vertical lines) and theoretical (solid curve) dependences of IR / Ifl on the monolayer number N. Typically, IR / Ifl little increases with the illumination time. It can be simply explained. Indeed, in the absence of the chemical enhancement IR / Ifl ~ γ [11], where γ is the decay rate of the molecule that is the value to be inversed to the lifetime of the excited molecule. The higher lifetime of an excited molecule leads to a higher probability to be situated in a metastable triplet energy state and consequently to transfer of the energy to oxygen. Thus, the photo-oxidation of the molecules having the higher lifetime has the higher probability. Since in the electrostatic approximation and in the absence of the physical spacer layer γ ~ z–3 (z is the molecule-surface distance) for the case of the volume damping [20], one can say that the photobleaching is able to selectively “delete” the most remote dye molecules. One more trend- like property is an increase of the fluctuation of IR / Ifl with the spacer thickness decrease. The highest fluctuations are at N = 1. This property is clearly seen taking into account the distance dependence of the decay rate. Indeed, z zΔ = γ γΔ 3 for the case of the volume damping. Thus, the fluctuation of the molecule-surface distance essentially increases at small mean distances. If there is the spacer layer and the distance between the molecule and surface of the spacer is not equal to zero, then we obtain even in the electrostatic approximation γ ~ ( ) ( ) ( ) ⎟ ⎟ ⎠ ⎞ ⎜ ⎜ ⎝ ⎛ + + + + + + ... 32 3 3 3 2 3 1 hz A hz A hz A , where are some coefficients. The latter expression represents multiple reflections in the spacer film. Note that the multiple reflections still keeps the general feature about an increase of the fluctuations at smaller spacer thicknesses. ,...,, 321 AAA The main result of the molecule-surface distance behavior is depicted in Fig. 4. The diapasons of the values IR / Ifl for the Raman shift are presented as vertical lines at the five number values of the spacer layers. It is seen that the fluctuation decreases with the spacer thickness. Theoretical calculation is presented by the solid line supposing that I 1cm1564 −=Ω R / Ifl = 1.23 at N = 1. This calculation is made at the following parameters: the distance of the point-like source to surface should be 1 nm and the thickness of one monolayer should be 0.85 nm. The dielectric function ε of the polyimide spacer is taken as ε = 2.8. Theoretical calculation of the non-radiative relaxation rate based on the classical theory delineated in Ref. [20] was performed. Briefly, the relaxation rate of a dipole, p, placed near a metallic surface is given by γ ∝ Im (p∗·ER), where ER is the reaction field containing direct incident (radiated) field and reflected field from the surface. From the latter equation, one can get γ ∝ (( rrGp ii ))rr,,Im2 ω , where (( rrGii ))rr,,ω is the corresponding component of the electrodynamics Green tensor. In the case of a substrate with the spacer layer, the Green function can be found elsewhere [21]. Supposing the case of the physical adsorbed molecule 197 Semiconductor Physics, Quantum Electronics & Optoelectronics, 2011. V. 14, N 2. P. 195-199. © 2011, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine )) (the dipole moment does not change), one can get IR / Ifl ~ (( rrGii rr ,,Im ω . This expression is presented in Fig. 4 by the solid line. Of course, the coefficient in the equation IR / Ifl ~ (( rrGii ))rr,,Im ω depends on many parameters, in particular, on the excitation and radiation wavelengths, kind of molecules, temperature, etc. However, it does not depend on the nanoplasmon system. Thus, finding once the coefficient at the fixed above mentioned parameters, one can make a diagnostic of the nanoplasmonic system only on the basis of the ratio between Raman and fluorescence intensities. One can see that the theoretical dependence describes the experimental behavior quite well. However, there is a tendency for this behavior to be disagreed with theoretical dependence at small spacer thicknesses. A similar tendency [16] took place in the case of rhodamine 6G molecules. This tendency can be caused by both certain inhomogeneity in the spacer layer and the deposited dye film as well as by the presence of background. One can see that the value of the ratio IR / Ifl is less than the theoretical prediction. It looks like there is an additional fluorescence not taken into account. This fluorescence can be caused by an additional background. Nevertheless, though the subtraction should cancel the background associated with the fluorescence of Au and the wing of the Rayleigh scattering, an additional background can exist. Indeed, it has been reported recently [22] that non-fluorescent molecules (in our case dye molecules) can give some background. This background cannot be cancelled by the proposed subtraction procedure. 4. Conclusion In conclusion, we have performed an experiment on simultaneous measurement of Raman and fluorescence intensities of molecules LDS 751 located at various distances from a flat Au surface. It was shown that the ratio between the Raman and fluorescence intensities is well described by the classical model of the energy transfer from the molecule to metal. We believe that this ratio can be used to find the distance between molecule and metal surface. The authors are thankful to S.A. Zenyo for preparation of Au substrate film. This work was supported by Ukrainian-French projects “Dnipro” of State fund for fundamental researches of Ukraine References 1. W.L. Barnes, A. Dereux, and T.W. Ebbesen, Surface plasmon subwavelength optics // Nature, 424, p. 824-830 (2003). 2. For recent reviews, see: Surface-Enhanced Raman Scattering. Physics and Applications, edited by K. Kneip, M. Moskovits, and H. Kneip // Topics in Applied Physics, 103, p. 1-464 (2006). 3. K. Okamoto, I. Niki, A. Shvartser, Y. Narukava, T. Mukai, and A. Scherer, Surface-plasmon- enhanced light emitters based on InGaN quantum wells // Nature Materials, 3, p. 601-605 (2004). 4. E. Fort and S. Gr´esillon, Surface-enhanced fluorescence // J. Phys. D: Appl. Phys.41, 013001- 013031 (2008). 5. J.R. Lakowitcz, Ch.D. Geddes, I. Gryczynski, J. Malicka, Z. Gryszynski, K. Aslan, J. Lukomska, E. Matveevs, J. Zhang, R. Badugu, and J. Huang, Advances in surface-enhanced fluorescence // J. Fluorescence, 14, p. 425-441 (2004). 6. K.H. Drexhage, Influence of a dielectric interface on fluorescence decay time // J. Luminescence, 1-2, p. 693-701 (1970). 7. G. Cnossen, K.E. Drabe, and D.A. Wiersma, Fluorescence properties of submonolayers of rhodamine 6G in front of a mirror // J. Chem. Phys., 98, p. 5276-5280 (1993). 8. P. Anger, P. Bgaradwaj, and L. Novotny, Enhancement and quenching of single-molecule fluorescence // Phys. Rev. Lett., 96, 113002-1 – 113002-4 (2006). 9. S. Kuhn, U. Hakanson, L. Rogobette, and V. Sandoghdar, Enhancement of single-molecule fluorescence using a gold nanoparticle as an optical nanoantenna // Phys. Rev. Lett., 97, 017402-1 – 017402-4 (2006). 10. A. Hartschuh, E.J. Sanchez, X.S. Xie, and L. Novotny, High-resolution near-field Raman microscopy of single-walled carbon nanotubes // Phys. Rev. Lett., 90, 095503-1 – 095503-4 (2003). 11. M.M. Dvoynenko and J.-K. Wang, Finding electromagnetic and chemical enhancement factors of surface-enhanced Raman scattering // Opt. Lett. 32, p. 3552-3554 (2007). 12. H. Xu, X-H. Wang, M.P. Persson, H.Q. Xu, M. Kall, and P. Johansson, Unified treatment of fluorescence and Raman scattering processes near metal surfaces // Phys. Rev. Lett., 93, 243002-1 – 243002-4 (2004). 13. P. Johansson, H. Xu, and M. Kall, Surface- enhanced Raman scattering and fluorescence near metal nanoparticles // Phys. Rev. B, 72, 035427-1 – 035427-17 (2005). 14. C.M. Galloway, P.G. Etchegoin, and E.C. Le Ru, Ultrafast nonradiative decay rates on metallic surfaces by comparing surface-enhanced Raman and fluorescence signals of single molecules // Phys. Rev. Lett., 103, 063003-1 – 063003-4 (2009). 15. A.E. German and G.A. Gachko, Dependence of the amplification of giant Raman scattering and fluorescence on the distance between an adsorbed molecule and a metal surface // J. Appl. Spectr. 68, p. 987-992 (2001). 16. M.M. Dvoynenko, Z.I. Kazantseva, V.V. Strelchuk, O.F. Kolomys, E.F. Venger, and J.-K. Wang, Molecular ruler based on concurrent measurements 198 Semiconductor Physics, Quantum Electronics & Optoelectronics, 2011. V. 14, N 2. P. 195-199. of enhanced Raman scattering and fluorescence // Opt. Lett., 35, p. 3802-3804 (2010). 17. T. Akatsuka, H. Tanaka, J. Toyama, T. Nakamura, M. Matsumoto, and Y. Kawabata, Properties of liquid crystal cells of pyrolyzed polyimide Langmuir-Blodgett films // Thin Solid Films, 210/211, p. 458-460 (1992). © 2011, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 18. P.A. Kawka and R.O. Buckius, Optical properties of polyimide films in the infrared // Intern. J. Thermophys., 22, p. 517-534 (2001). 19. R. Zondervan, F. Kulzer, M.A. Kol’chenko, and M. Orrit, Photobleaching of rhodamine 6G in poly(vinyl alcohol) at the ensemble and single- molecule levels // J. Phys. Chem. A, 108, p. 1657- 1665 (2004). 20. R.R. Chance, A. Prock, and R. Silbey, Molecular fluorescence and energy transfer // Adv. Chem. Phys., 37, p. 1-65 (1978). 21. A.K. Zvezdin and V.I. Belotelov, Electrodynamic Green-function technique for investigating the magneto-optics of low-dimensional systems and nanostructures // J. Opt. Soc. Amer. B, 22, p. 228- 229 (2005). 22. S. Mahajan, R.M. Cole, J.D. Speed, S.H. Pelfrey, A.E. Russell, P.N. Bartlett, S.M. Barnett, and J.J. Baumberg, Understanding the surface- enhanced Raman spectroscopy “background” // J. Phys. Chem. C, 114, p. 7242-7250 (2010). 199

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