Abstract
Cascaded optical field enhancement (CFE) can be realized in some specially designed multiscale plasmonic nanostructures, in which the generation of extremely strong fields at nanoscale volume is crucial for many applications, for example, surface-enhanced Raman spectroscopy (SERS). In this paper, we propose a strategy for realizing a high-quality plasmonic nanoparticle-in-cavity (PIC) nanoantenna array, in which strong coupling between a nanoparticle (NP) dark mode with a high-order nanocavity bright mode can produce strong Fano resonance at the target wavelength. The Fano resonance can effectively boost the CFE in a PIC. A cost-effective and reliable nanofabrication method is developed using room temperature nanoimprinting lithography to manufacture high-quality PIC arrays. This technique guarantees the generation of only one gold NP at the bottom of each nanocavity, which is crucial for the generation of the expected CFE. To demonstrate the performance and application of the PIC array, the PIC array is employed as an active SERS substrate for detecting 4-aminothiophenol molecules. An experimental SERS enhancement factor of 2 × 107 is obtained, which verifies the field enhancement and the potential of this device.
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Introduction
Metallic nanostructures that support surface plasmons (SPs) have attracted significant attention due to their peculiar optical properties and important applications.1,2 SPs can be considered to be the resonant photon-induced collective oscillations of free electrons confined on the surfaces of metallic nanostructures, which can be driven by an incident light field. The importance of these photon–electron interactions is their ability to concentrate light energy in nanoscale volumes in the metallic nanostructures and subsequently boost the intensity of the optical near field by several orders of magnitude.2,3,4,5 Due to these properties, localized SPs can facilitate many applications based on the enhanced light–matter interaction, such as the detection of trace element chemical varieties in the vicinity of metallic nanostructures by surface-enhanced Raman spectroscopy (SERS). The detection limit can be reduced to a single molecular level.6,7
The SP-enhanced optical near field (also referred to as the field ‘hot spot’6,7) is typically and predominantly localized in very small geometric features of metallic nanostructures, such as nano-grooves,2 nanogaps,8 and nanotips.9 Although certain advances have been achieved regarding the fabrication of nanostructures with extremely small feature sizes,10 these tiny features remain formidable tasks for nanofabrication. Alternatively, extreme field localization and enhancement via a cascaded optical field enhancement (CFE) mechanism may be realized. This concept was proposed by Stockman et al. with a self-similar chain of gold nanoparticles (NPs),2,3 in which the light energy can be focused to a nanoscale volume via the intercoupling of localized SPs among the aligned NPs with decreasing sizes. Field enhancement is achieved by a relatively large metallic NP that is resonantly excited by the incident light. Then, the enhanced field simultaneously excites the field of the adjacent smaller NP via SP coupling. The process continues until the smallest NP is excited and the light energy is predominantly confined in the tiniest nanogap.3 Although self-similar chains of NPs have shown great potential, fabrication of these nanofocusing systems in practice is challenging. The cascaded energy focusing effect exists not only in the self-similar chains of metal NPs3 but also in many other metallic nanostructures with multiscale features, such as V-grooves,2 nanostars,8 ellipsoidal NP dimers,11 and asymmetric π-shaped metamaterials.12 Few experimental verifications of the CFE effect in certain geometries have been reported.13 Recently, Kravets et al. noted CFE in a composite plasmonic system, in which each unit is composed of two or three nanodisks.14,15 Novotny et al. demonstrated CFE in arrays of gold NPs that were assembled into dimmer or trimer nanoantennas.16 These novel CFE plasmonic nanostructures show great potential for applications such as SERS with a single molecular level,7 high-sensitivity reflective index sensing,17 and super-resolution imaging.9,18 In our previous study of M-shaped nanograting, strong CFE can be achieved by the intercoupling between the localized SPs in two adjacent V-grooves, which produces pronounced enhancement of the SERS sensitivity.19
Another effective method of tuning the resonance in a complex plasmonic system is mode hybridization, which results from the interference between two or more plasmonic modes.1,5 A plasmonic mode can be either subradiant (referred to as the dark mode) or super-radiant (referred to as the bright mode), depending on how strong the incident light can be coupled to the plasmonic mode.20,21 Analogous to a classical Fano resonance system,1,5,22 plasmonic Fano resonance may also occur from the interference between a continuum of incident photons or a spectrally broad resonance (e.g., caused by a super-radiant bright mode) with a narrow resonance (e.g., caused by a subradiant dark mode). The intercoupling between the bright mode and the dark mode occurs when the near field of one mode overlaps with and excites the near field of the other mode, which can be generated in certain coupled plasmonic nanostructures, such as the symmetry breaking nanocavity-NP system,21 the nonconcentric ring-disk cavity,23 the plasmonic nanoshell,24 NP oligomer chains,25 nanovoids,26,27,28,29,30 nanostars,31 and nanogratings.32 The plasmonic Fano interference usually results in an asymmetric resonant peak dressing within a broad spectrum.33
Complex plasmonic nanostructures, in which individual tiny metal NPs are coupled to certain extended metallic structures, are ideal systems for generating both CFE and mode hybridization, such as the plasmonic nanoparticle-in-cavity (PIC) nanoantenna array.26,27,28,29,30 Cole et al. have systematically analyzed the excited fields and energies of various localized modes in empty truncated plasmonic nanocavities embedded in a metal film, in which various bonding and anti-bonding hybridized modes can be generated.26,27,28,29 Huang et al. have theoretically analyzed a PIC structure and revealed that the CFE can be effectively induced by the intercoupling between the 0D mode of the empty void and a ‘NP mode’ induced by the gold NP located at the bottom of the cavity under oblique incidence.30 To verify the CFE effect, they fabricated PIC structures (with 20 nm Ag NPs in 600 nm Au voids) and employed them as SERS substrates to probe 4-aminothiophenol (4-ATP) molecules, from which a SERS enhancement factor of 3.1 × 104 was achieved.30 This SERS enhancement factor is relatively low because the assembly method cannot precisely control the number and allocation of Ag NPs in the Au voids. Approximately 10% Au voids surface was coated with randomly distributed Ag NPs after the bare Au void substrate was immersed in a 20 nm Ag NPs solution. Even within the coated area, some voids may contain no NP or may contain several NPs (which may even aggregate to form larger NPs). Therefore, the expected CFE effect cannot be readily and efficiently realized. In addition, the coupling between the 0D mode and the NP mode in the PIC for generating the CFE requires adequate control of an oblique incident angle of approximately 60°, which is crucial for applications. Efforts were also made by other researchers regarding the fabrication of PICs by other methods, such as nanosphere lithography assisted by an oblique deposition technique and annealing treatment.26,27,28,29,30,34,35,36,37 However, obtaining a single gold NP dressing in each nanovoid is difficult and the PIC array can only be arranged in closely packed hexagonal lattice. The randomness of the NP allocation in these fabricated PIC structures is a significant problem that substantially degrades the expected CFE effect.
By summarizing the previous studies on PICs and attempting to achieve their practical SERS applications, we determine the need to solve the following main issues: first, a relatively simple PIC design is required for generating strong CFE for a SERS excitation wavelength, preferably under normal incidence rather than the oblique incidence at a fixed angle.30 Second, small PICs with void diameters less than 200 nm and a NP size less than 30 nm are important for generating Fano resonance and CFE in visible to near-infrared spectra to fit SERS excitation wavelengths, which have been less examined. Third, a cost-effective and robust fabrication method is necessary to fabricate high-quality PICs with a strong CFE effect. Only one NP should be located at the bottom of each void because the slight change in the location, aggregation, and number of NPs in the void may significantly influence the mode hybridization and the induced CFE effect.30
In this study, we propose a strategy for realizing a high-quality plasmonic PIC nanoantenna array by considering the three previously mentioned main issues. Our objective is to achieve a strong CFE effect boosted by Fano resonance with normal incidence at a given wavelength. A cost-effective, efficient, and reliable nanofabrication technique that involves room temperature nanoimprinting lithography (RT-NIL)19 and anisotropic reactive ion etching (RIE) is developed to manufacture the PICs. Because the PICs can potentially produce extremely strong CFE, which may be even stronger than the CFE produced by other plasmonic oligomers (such as dimers,38 trimers,39 and nanofingers40), they can be potentially exploited for single molecular sensing. To analyze the sensing performance of the PIC array, we employ the PIC arrays as SERS substrates for probing 4-ATP molecules; the SERS enhancement factor is experimentally evaluated.
Materials and methods
The geometry of the PIC nanoantenna unit is depicted in Figure 1a. A gold NP with the diameter dp is located at the bottom of a truncated gold cavity with the diameter dc. The cavity is formed by etching a gold nanocube with side lengths of l and a height (which is also the height of the truncated nanocavity) of t. The nanoantenna array is situated on a fused silica substrate. The lattice constants along the x and z directions are p. The PIC array is assumed to be illuminated by an x-polarized plane wave at normal incidence from the top side. It is designed to produce strong CFE at an expected SERS excitation wavelength of 720 nm.
The optical response of the structure is numerically simulated with a commercial full-wave software CST Microwave Studio based on the finite integral method.41 A 3 nm thick Cr adhesion layer is situated between the gold layer and the quartz substrate. The permittivity function of Au and Cr are obtained from the experimental data and the Palik database.42 The refractive index of the fused silica substrate is assumed to be 1.5 by neglecting its small dispersion. To understand the physics and unique properties of the PIC array, we compare it with a truncated empty nanocavity (ENC) array in the following analyses. The structural parameters of the ENC array are equivalent to the structural parameters of the PIC array; the only difference is that there is no NP in each nanocavity of the ENC array.
We have developed a reliable technique involving RT-NIL and anisotropic RIE to fabricate the PIC array, which is one of the main contributions of this study. Figure 2a describes the nanofabrication process. Two layers of photoresists, including a hydrogen silsesquioxane (HSQ, Fox-14, Dow Corning Inc.) top layer with a thickness of 150 nm and a polymethylmethacrylate-co-polystyrene copolymer (PMMA-b-PS, which is a homemade imprinting resist with PMMA/PS: 21 000/64 000 g·mol−1) bottom layer with a thickness of 250 nm, were spin-coated onto a 60 nm thick gold film coated on a fused silica substrate. After prebaking, the RT-NIL process was operated with a pressure of 50 psi at room temperature. The silicon stamp consists of a crossed grating with cubic profiles fabricated by standard electron-beam lithography; the lattice constants along the x and z directions are 250 nm, and the width and depth of the cubic unit are 150 nm and 250 nm, respectively. After releasing, the HSQ in the imprinted grooves was removed by a RIE process with pure CF4 (40 sccm, 2 Pa, 40 W, 10 sec). Then, another O2/CF4 composite RIE process (20 sccm/48 sccm, 2 Pa, 40 W, 90 sec) was operated to etch the residual PMMA in the grooves and simultaneously etch the top HSQ layer.
Prior to the subsequent procedures, an important step of thermal annealing is necessary to induce the phase separation in the PMMA-b-PS photoresist. The sample was rapidly heated to 175 °C in one minute, maintained at this temperature for 5–7 min, and rapidly cooled to 25 °C within 10–30 sec. The PMMA-b-PS layer received an intersurface tension between PMMA and PS during the annealing,43 which caused PMMA to diffuse outward while PS remained relatively stable. Consequently, the PMMA-b-PS layer became a gradient resist with varying etching resistance from the center to the outer area. The induced tensile stress and diffusion of PMMA cause the collapse of the resist in the central area of the cubic resist block and the formation of a resist cavity with an aggregated resist particle at the bottom. Then, this anisotropic bilayer resist with a special geometry serves as the mask for etching the gold film located underneath.
With the HSQ and PMMA-b-PS bilayer mask, an anisotropic RIE process was employed with O2 5 sccm/Ar 20 sccm/Cl2 10 sccm plasma. During this process, the bowl-shaped cavity was transferred to the gold layer by dry etching (70 W, 16 Pa, 120 sec); because the central small resist particle in the cavity is thicker than the adjacent resist, the gold underneath this resist particle was etched more slowly than the gold in the adjacent area. In this manner, the gold NP in the cavity was gradually formed with an appropriately selected etching time and recipe. For details on the fabrication process (including the dry etching of the gold film, the preparation of the bilayer resist mask, the formation of the gold NP during RIE, the control of the gold NP size and position, and the stability and purity of the fabricated gold PIC array), readers may refer to Section 1 of the Supplementary Information.
Note that the size of the gold NPs can be controlled by tuning the anisotropic RIE parameters. For example, with a RIE recipe of O2 10 sccm/Ar 20 sccm/Cl2 10 sccm, 16 Pa, 70 W, and 150 sec, an ENC array without gold NPs can be formed. After etching, the residual resists were completely cleaned by soaking the sample in an acetone solvent for 30 min and implementing an ultrasonic bath for 3 min. The cleaned PIC nanostructures consist of pure gold without any residual resist, which was verified by energy dispersive X-ray spectroscopy characterization (refer to Section 1 of the Supplementary Information for details). The quality and geometry of the fabricated structures were examined by scanning electronic microscopy (SEM, FEI Serion 2000).
Results and discussion
The PIC array is designed to produce strong CFE at an expected SERS excitation wavelength of 720 nm. As previously mentioned, strong Fano resonance may be generated in the PIC array via the coupling between the NP mode and the cavity mode of the nanovoid. Therefore, the array should be designed to achieve cavity resonance at a target wavelength of approximately 720 nm. By numerical simulations (refer to the details in Section 2 of the Supplementary Information) and according to previous studies,26,27,28,29,30 we determined that although the cavity resonance modes are generated by individual cavities, their spectral positions can be effectively influenced by the lattice constant when the cavities are arranged in a periodic lattice. By numerical optimization and considering the fabrication capabilities, we select the array period p = 250 nm, the nanocube width l = 150 nm (by which the coupling between the adjacent PIC units is prevented), the cavity diameter dc = 120 nm, and the height of the truncated cavity t = 60 nm. With these parameters, the far-field reflectance and transmittance spectra of the ENC array were simulated and shown in Figure 1c. The reflectance spectrum has two evident resonance peaks in the wavelength range of 700 nm to 1000 nm, which are attributed to the 1D+ and 1P+ modes of the truncated nanocavity under normal incidence.28 This can be verified by the simulated field distributions in the ENC in Figure 3e and f. Note that our ENC array is situated on a silica substrate, which differs from the case of Cole et al.28, in which the empty nanovoids are embedded in an infinitely thick gold substrate. This situation explains why the simulated field distributions of the two modes slightly differ from the simulated field distributions in Cole et al.28. However, the key features of the mode profiles remain identical, which indicates the excitation of the two modes. With these selected void parameters, the 1D+ mode is tuned to be very close to the target wavelength of 720 nm. We are especially interested in this mode because the field hot spots of this mode (refer to Figure 3e) are primarily located at the bottom of the void to ensure strong coupling with the field of the gold NP.
The last important parameter to be determined for the PIC array is the size of the gold NP. As demonstrated by the simulated reflectance spectrum of a PIC array with 20 nm gold NPs (i.e., diameter dp = 20 nm) in Figure 1b, the main consequence of introducing a gold NP in each nanovoid is the generation of an additional peak between the 1D+ and 1P+ peaks. The peak positions of the 1D+ and 1P+ cavity modes also slightly shift due to the perturbation by the gold NP. This additional peak is caused by a ‘NP mode’ that is induced by the coupling between the gold NP and its image.30 Compared with the nanocavity modes 1D+ and 1P+, which cause relatively broad resonances (the super-radiant bright modes), the NP mode is a subradiant dark mode and causes narrow resonance. When the NP mode is close to the 1D+ mode, they have strong interference that causes strong Fano resonance, which is manifest as an asymmetric resonance peak in the transmittance spectrum of the PIC array (refer to the red curve in Figure 1b) and does not exist in the ENC array (refer to the red curve in Figure 1c). We have also thoroughly investigated the influence of the NP size on the Fano resonance peak position and the maximum field enhancement factor at the target wavelength 720 nm, as shown in Figure 1e and f. With an increase in NP size, the Fano resonance peak develops a red shift (as indicated by the arrows in Figure 1f). When dp = 20 nm, the Fano peak is tuned to be exactly located at the target wavelength of 720 nm and the corresponding maximum field enhancement factor is also attained at this wavelength (as shown in Figure 1e). Thus, we select dp = 20 nm in our PIC array design. Note that when the NP size is increased, the NP mode peak may causes red shift, which results in weaker interference with the 1D+ mode but stronger interference with the 1P+ mode (as denoted by the pink curve in Figure 1f).
To verify the far-field responses of the PIC array, we have measured the transmittance of the fabricated PIC and ENC arrays by the spectroscopic ellipsometer VASE (J. A. Woollam Co.) in the wavelength range from 400 nm to 900 nm under normal incidence, as shown in Figure 1d. The experimental spectra are consistent with the theoretical predictions, which verifies the expected Fano resonance. The slight differences in the spectra are most likely attributed to the deviation in the structural parameters of the fabricated samples from theoretical designs.
As previously discussed, the ultimate goal of generating and tuning Fano resonance by mode hybridization in the plasmonic PIC system is to produce a strong CFE effect. We have simulated field distributions in the PIC array, as shown in Figure 3a–d. The 1D+ mode (Figure 3a) and 1P+ mode (Figure 3d) retain their mode profile features (although perturbed somehow by the gold NP). The Fano interference of the 1D+ mode with the NP mode (Figure 3b) produces remarkable CFE at the target wavelength of 720 nm (as shown in Figure 3c), which result in significantly enhanced field hot spots and a slight change in the distribution of the hot spots in the cavity. These results are very important and beneficial for enhancing the light–matter interaction in the cavities. The maximum simulated field enhancement factor (i.e., the normalized field amplitude |E/E0|, where E0 is the amplitude of the incident electric field) is 1.2 × 103, whereas the enhancement factor in the ENC array without the CFE effect is only 102, which demonstrates that the CFE effect can significantly improve the field enhancement factor.
Note that we did not consider the finite contact area between the gold NP and the gold void in these simulations, that is, the contact between the NP and the void was assumed to be an ideal point. In the fabricated samples, the physical contact formed during the etching process must have a nonzero area. In Section 3 of the Supplementary Information, we examined the influence of the contact area on both the far-field and near-field responses of the PIC array. The findings indicate that an increase in the contact area may cause a slight decrease in the Fano resonance peak (although the resonance peak profile remains almost unchanged) and a decrease in the near-field enhancement. For example, when the radius of the contact area is assumed to be 4 nm, the maximum near-field enhancement factor in the PIC decreases to approximately 4 × 102. Therefore, the calculated field enhancement factor of 1.2 × 103 is the most optimistic value. In practical samples, the field enhancement may be degraded due to the finite contact area and other fabrication defects.
To corroborate the field enhancement in the PIC array, we have fabricated some samples of ENC and PIC arrays, as displayed in the SEM images in Figure 2b and c, respectively. The insets show enlarged top-view images of the samples. As shown in Figure 2c, only one gold NP is situated in each nanocavity, which verifies the reliability and quality of the fabrication method. In the ENC array in Figure 2b, no gold NP is observed in the nanocavity.
As a demonstration of the SERS performance of the PIC array, we have conducted a comparative experiment using the PIC array and the ENC array as SERS substrates for probing 4-ATP molecules (Sigma-Aldrich Co., with bulk concentration 0.1 µM). The reference Raman signal was detected from an unpatterned area of the gold film. All Raman spectra removed the baseline and were fitted using a Gaussian–Lorentzian line shape. In the SERS experiment, 4-ATP molecules were dosed onto the sample substrates via the chemical bonds between the gold atoms and sulfur atoms on the surface when the substrates were soaked for three hours in the 4-ATP solution and washed several times with ethanol to obtain a monolayer of 4-ATP molecules on the samples.
The back-scattering Raman spectra were collected by a LabRam microRaman system (Jobin-Yvon/ISA HR). A super-continuum light source (Fianium, SC400-PP) was tuned to emit light at an excitation wavelength of 720 nm with an output power 0.6 mW and an integration time of 10 s. A thermoelectrically cooled charge-coupled device (CCD) array detector and a BH-2 microscope with a 100 × short-focal-length objective lens with a 0.5 numerical aperture were employed. The diameter of the Raman signal probing area was approximately 1 µm. The SERS spectra were collected in the Raman shift range of 400 cm−1 to 1800 cm−1.
Figure 4 shows the measured SERS spectra of the 4-ATP molecules on the PIC array, the ENC array, and the reference gold film. Note that the reference spectrum is multiplied by a factor of 10. The SERS signal collected from the PIC array, which is approximately four times stronger than the SERS signal collected from the ENC array, is the strongest signal. The SERS enhancement factor (EF) can be estimated by6
where ISERS and Ibulk are the Raman signal intensities at the characteristic vibration mode at 1078 cm−1 of 4-ATP molecules doped on the nanostructured samples and on the surface of the reference flat gold film, respectively, and Nsurf and Nbulk are the estimated number of 4-ATP molecules doped on the sample and number of bulk 4-ATP molecules in the probing light spot area, respectively. Details on the estimation of Nbulk and Nsurf are given in Section 4 of the Supplementary Information. According to Equation (1), the experimental SERS enhancement factor of the PIC array is estimated to be 2 × 107, which is a relatively conservative estimate. Because the collected Raman signal from the PIC array is primarily derived from the gold NP with strong field hot spots, the real number of 4-ATP molecules Nsurf adsorbed on the NP may be significantly smaller, which may produce a larger estimated experimental SERS enhancement factor (maximum of 109).
The SERS experiment provides persuasive evidence that the PIC array has significantly improved SERS performance due to the CFE effect boosted by Fano resonance in the PIC nanoantennas. Therefore, the PIC array has great potential for use as a highly active SERS substrate.
Conclusions
We have proposed a plasmonic PIC array that consists of nanoantennas, in which a 20 nm gold NP is placed at the bottom of a 120 nm truncated hemispherical gold nanovoid. Using plasmonic mode hybridization in this multiscale system, strong Fano resonance can be generated due to the simultaneous excitation and intercoupling of the NP mode with a high-order cavity mode, which significantly boost the CFE in the PIC antenna. The maximum enhancement factor of the localized field amplitude ranges from 102 to 103, which is significantly higher than the maximum enhancement factor in a reference ENC array. To realize the PIC array with high performance, we have developed a cost-effective, efficient and reliable nanofabrication method that involves RT-NIL and anisotropic RIE. Using this technique, only one gold NP is located in each nanovoid and the NP size can be finely controlled to be approximately 20 nm, which are crucial for realizing a significant CFE effect in the PIC array. As a demonstration of the CFE performance of the PIC array, the PIC samples were fabricated and employed as SERS substrates for detecting 4-ATP molecules. The achieved experimental SERS enhancement factor is 2 × 107, which demonstrates the strong field enhancement in the PIC array and its great potential for applications.
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Acknowledgements
We acknowledge the support by the National Natural Science Foundation of China (Projects No. 11474180, and No. 61227014) and the Ministry of Science and Technology of China (Project No. 2011BAK15B03).
Note: Accepted article preview online 7 March 2015
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Zhu, Z., Bai, B., You, O. et al. Fano resonance boosted cascaded optical field enhancement in a plasmonic nanoparticle-in-cavity nanoantenna array and its SERS application. Light Sci Appl 4, e296 (2015). https://doi.org/10.1038/lsa.2015.69
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DOI: https://doi.org/10.1038/lsa.2015.69
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A Hybrid Machine Learning Model to Study UV-Vis Spectra of Gold Nanospheres
Plasmonics (2021)
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Neodymium doped zinc oxide for ultersensitive SERS substrate
Journal of Materials Science: Materials in Electronics (2019)
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Broadband single molecule SERS detection designed by warped optical spaces
Nature Communications (2018)
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Highly effective and chemically stable surface enhanced Raman scattering substrates with flower-like 3D Ag-Au hetero-nanostructures
Scientific Reports (2018)