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1.INTRODUCTIONSurface plasmon polaritons (SPPs) are surface electromagnetic waves travelling along a metal/dielectric interface originated from coupling between oscillating electrons and incident photons. SPPs and localized surface Plasmon resonances (LSPR) can offer high field enhancement and confinement beyond the diffraction limit and have found many applications in biosensing, surface-enhanced Raman spectroscopy (SERS) and also microscopy. In this paper a tapered hybrid gold-core/borosilicate-cladding microfiber is studied. Their advantages over the metal tips are the ease of light coupling and the re-excitation of the plasmon modes due to the total internal reflection at the dielectric/air interface through the length of the fiber. Although the field enhancement of pure metal tips has been extensively studied theoretically1-3, it has been clearly identified lately the need for further research4 towards the engineering of physically realizable and robust plasmonic structures with enhanced performance. The absence of impurities and the multiple excitation of the nanowire due to the repeated silicate glass/air total internal reflections5 can provide high field enhancement at the apex of such tapers by overcoming the metal induced losses. For the tapering the method of heating and stretching is used for the accurate control of the final taper geometry. 2.FABRICATION OF DIELECTRIC CLADDING/METAL CORE MICROFIBERSThe hybrid gold core/borosilicate cladding are fabricated in the Optoelectronics Research Center (ORC, University of Southampton) and have core diameters varying from 3-20μm. For the fabrication of the hybrid metal-core/glass-cladding microfibers a suitable metal should be used having melting point below the softening point of the glass cladding. The metals that were used were silver, copper, gold and aluminum having melting points ranging from 660 °C for aluminum to 1085 °C for copper (Fig. 1). For the glass cladding Schott Duran borosilicate tubing of different outer and inner diameters (81 wt% SiO2, 13 wt% B2O2, 4 wt% Na2O+K2O, 2 wt% Al2O3) was identified as a promising, widely available and low cost solution and therefore it was used6. The microwires’ fabrication process was proved to be not a trivial process and certain modifications in the “stack and draw” fiber drawing systems were needed. The main parameters that had to be controlled during the drawing process of the fibers are the temperature, feed rate, pull rate and volume of metal used together with a number of secondary parameters. The initial trials were based on copper based microwires due to the copper’s low cost. Many fiber snaps occurred during initial copper-core fiber draws mostly due to the copper not melting fully, or too much copper flowing into the preform neck at once. For continuous core microfibers a Schott Duran borosilicate preform of 6 mm outer diameter and 2.5 mm inner diameter is fused at one end to create a seal, and four lengths of 0.5 mm diameter copper wire are inserted into the preform. No gas purge is supplied to the center of the furnace, where the preform is situated, but instead a nitrogen gas flow is delivered through the cooling ring. A number of carefully considered parameters in drum’s speed were needed to be considered in order to achieve the continuous production of microwires at speeds of several tens of meters per minute, and of a solitary spool up to 50 km in length of continuous fiber microwire. However it was identified that for some metals there were metal core discontinuities in the entire spool length and therefore there is currently under way an optimization process for production of continuous microwires in such long lengths. In plasmonic applications though, continuity over long length is not a crucial factor as small pieces of microwires are needed. The core discontinuity that was apparent a number of studied microwires were further investigated. It was confirmed that in core discontinuous fibers, the mode profile at the output of these fibers is well preserved due to the continuous reexcitation effects into the silicate enclosure, through the length of the fiber as a result of repeated total internal reflection at the silicate/air interface5. We obtained the beam profile of a microfiber of 54μm diameter and 11μm core diameter. Figure 2 shows the beam profiles of a continuous and a discontinuous piece of the microfiber (see inset picture). The nanowires are excited by coupling light of 532nm into the borosilicate enclosure. As expected two peaks are observed in the 2D beam profile at the gold/glass interface corresponding to the illustrated modelled TM01 mode profile (inset picture). In order to obtain the beam profile we used a 60x objective lens to image the near-field intensity distribution at the fiber output and a scanning slit optical beam profiler. 3.MODELLINGFor metallic core nano-wires of radius R1 surrounded by a dielectric layer of radius R2, the amplitudes of the electric and magnetic fields for TM01 mode6 are: where β is the propagation constant, ε1 ε2 and ε3 are the relative permittivities of metal core, dielectric cladding and air respectively, αj = (β2–εjk2)1/2 for j=1,2,3, I and K are the modified Bessel functions of the first and second kinds and A1, A2 and A3 are the complex constants. The dispersion equation can be derived by the continuity of the tangential components of the fields at the interfaces ρ = R1 and ρ = R2: Figures 3 shows the real and imaginary part of the effective refractive index (neff) as a function of the wavelength for different radii of the gold core. As the radius of the copper tip decreases, both the real and imaginary parts of neff increase. This means that, toward the apex of the metal tip, the effective wavelength of the plasmon wave decreases and the losses increase. For radii of the metal tip larger than 50nm the losses are relatively low. As the radius decreases the losses become significant and they are minimum for wavelength around 800nm. 2.2Simulations of metal tipsSimulations through Finite Element Method (FEM) using COMSOL Multiphysics were performed in order to study the enhancement at the apex of tapered hybrid microfibers. The simulated gold tapered core has input and output radius of 150nm and 3nm, respectively, and semi-angle of 3.5°. The cladding/core ratio is ~12 along the length of the fiber. Boundary mode analysis was used at the input of the fiber for the excitation of TM01 mode. Figure 4 (a) shows the enhancement spectrum of the tapered microfiber. The enhancement factor Ef was calculated as the maximum intensity at the apex of the tip divided by the intensity at the glass/metal interface at the input of the fiber. The maximum Ef calculated was ~2.5 x 105 for 1100nm excitation wavelength. The normalized electric field for 1100nm excitation wavelength and its enhancement toward smaller radii is shown in Figure 2 (b). When the length of the tip is larger than 1μηι the propagating SPPs are reflected at the tip’s end and form cavity modes appeared as periodic peaks in the enhancement spectrum. 2.EXPERIMENTAL3.1.Tapering processFor the tapering of the microfibers the method of heating and stretching in a flame was used as shown8,9. A schematic representation of the tapering setup is shown in Figure 4. The tapering rig consists of three stages, one that moves the micro-burner and two for stretching the fiber. The temperature profile and geometry of the micro-burner flame is tailored by mixing oxygen and butane gasses at appropriate flow rates. Two electronic mass flow controllers are employed for accurately controlling the oxygen and butane gas flow rates. The whole tapering process is computer controlled in order to achieve the desired final taper geometry. The accurate temperature control is important in order to obtain a smooth hybrid tip. The appropriate tapering temperature is just below the melting point of gold (1064° C). For higher temperatures the gold core melts leading to the formation discontinuous core metal patterns or even the formation of well defined microspheres as can be seen Figure 5 (a). For the tapering process a whole range of different microfibers with continuous cores were used but the typical dimensions of the majority of fibers had metal core and silicate cladding diameters of ~10μm and ~35μm, respectively. For discontinuous cores and temperatures below the melting point of gold it was observed that the glass cladding collapses as shown in Figure 5 (b). For temperature just below 1064° C smooth tips were fabricated (Figure 6). The initial core/cladding diameter ratio is not preserved creating a sharp tip with a thick glass cladding facilitating the required robustness for easy handling. In the following Figure 7 is demonstrated the drastic decrease of the metal core to silicate cladding diameter ratio. At the left picture is illustrated the initial untapered microwire where their ratio is about 1/3. At the right SEM picture it can be seen the tapered fiber tip where now the ration has been drastically decreased to 1/20. In the tapered microwire’s tip image the metal core could not be seen and also the core’s shape looks asymmetric and non circular due to the non perfect cleaving that was attempted to the microwire. 3.CONCLUSIONSFabrication of hybrid metal core tips by tapering metal core/dielectric cladding microfibers is proposed for high field enhancement and confinement. The hybrid microfibers used, offer ease of light coupling, as well as mechanical robustness. Even though a solitary spool up to 50 km in length of continuous diameter fiber can be fabricated, a few core discontinuities apparent in the entire length do not influence the TM01 mode profile due to the multiple re-excitation of the plasmon modes due to the repeatable glass/air total internal reflection. The simple and cost – effective method of heating and stretching in a flame was used for the tapering of the microfibers offering control of the tip’s geometrical characteristics. For the tapering process though continuous cores with smooth surfaces are needed in order to get a good quality tip. Tapered tips with final core to silicate diameter ratio of 1/20 were demonstrated. ACKNOWLEDGMENTSThis work was financially supported by the “Advanced Materials and Devices” Program (MIS: 5002409), funded by the Hellenic General Secretariat for Research and Technology - GSRT. REFERENCESStockman M. I.,,
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