Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens

Ching-Bin Lin; Yu-Hsiang Lin; Wei-Yu Chen; Cheng-Yang Liu

doi:10.3390/photonics8080334

Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens

Lin, Ching-Bin;Lin, Yu-Hsiang;Chen, Wei-Yu;Liu, Cheng-Yang 2021-08-14 00:00:00 hv photonics Communication Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens 1 1 2 2 , Ching-Bin Lin , Yu-Hsiang Lin , Wei-Yu Chen and Cheng-Yang Liu * Department of Mechanical and Electro-Mechanical Engineering, Tamkang University, New Taipei City 25137, Taiwan; cblin@mail.tku.edu.tw (C.-B.L.); 607370037@gms.tku.edu.tw (Y.-H.L.) Department of Biomedical Engineering, National Yang Ming Chiao Tung University, Taipei 112, Taiwan; sam30261014.be09@nycu.edu.tw * Correspondence: cyliu66@nycu.edu.tw; Tel.: +886-2-28267020 Abstract: The photonic nanojet is a non-resonance focusing phenomenon with high intensity and narrow spot that can serve as a powerful biosensor for in vivo detection of red blood cells, micro- organisms, and tumor cells in blood. In this study, we ﬁrst demonstrated photonic nanojet modulation by utilizing a spider-silk-based metal–dielectric dome microlens. A cellar spider was employed in extracting the silk ﬁber, which possesses a liquid-collecting ability to form a dielectric dome microlens. The metal casing on the surface of the dielectric dome was coated by using a glancing angle deposition technique. Due to the nature of surface plasmon polaritons, the characteristics of photonic nanojets are strongly modulated by different metal casings. Numerical and experimental results showed that the intensity of the photonic nanojet was increased by a factor of three for the gold-coated dome microlens due to surface plasmon resonance. The spider-silk-based metal-dielectric dome microlens could be used to scan a biological target for large-area imaging with a conventional optical microscope. Keywords: photonic nanojet; spider silk; dome lens Citation: Lin, C.-B.; Lin, Y.-H.; Chen, W.-Y.; Liu, C.-Y. Photonic Nanojet Modulation Achieved by a Spider- Silk-Based Metal–Dielectric Dome 1. Introduction Microlens. Photonics 2021, 8, 334. Currently, the design of mesoscale photonic devices with high spatial resolution and https://doi.org/10.3390/ operation speed opens up prospects for the evolution of novel microscopic and manufac- photonics8080334 turing technologies [1,2]. According to the principle of optics, the spatial resolution of traditional optical elements is deﬁned by diffraction, and the minimum dimension of the Received: 21 July 2021 focal spot is more than half the wavelength of the incident light wave. This description sig- Accepted: 12 August 2021 niﬁes that traditional optical elements in the circuit are positioned at an extensive distance Published: 14 August 2021 from each other compared to the wavelength. Therefore, multitudinous investigations have veriﬁed the materialization of a high-intensity optical ﬁeld restrained in a region when Publisher’s Note: MDPI stays neutral the light wave was focused by a mesoscale dielectric particle [3–14]. This phenomenon is with regard to jurisdictional claims in referred to in several academic papers as the photonic nanojet effect. For generating a pho- published maps and institutional afﬁl- tonic nanojet, the Mie size parameter (q = 2r/) of a dielectric particle should correspond iations. to q~(2 . . . 40), where r is the particle radius and is the operating wavelength [15,16]. In contrast to the case of focusing radiation with a traditional optical lens, a photonic nanojet is formed in the near-scattering area, where the intensity ﬁeld is a complex spatial structure determined by a superposition of outgoing and decaying evanescent waves. The intensity Copyright: © 2021 by the authors. distribution and localization of a photonic nanojet depends on the shapes and physical Licensee MDPI, Basel, Switzerland. properties of the mesoscale dielectric particles and surrounding media. As a rule, the as- This article is an open access article semblies of mesoscale particles are embedded in a polymer ﬁlm, which makes it possible to distributed under the terms and arrange particles in diverse spatial conﬁgurations [17–20]. Such a composite polymer ﬁlm conditions of the Creative Commons will lead to a multiple increase in the intensity ﬁeld of a photonic nanojet. However, one of Attribution (CC BY) license (https:// the problems with photonic nanojets in near-ﬁeld focusing is the short spatial length of creativecommons.org/licenses/by/ the focal region that emerges near the convex surface of classical particle geometry. Hence, 4.0/). Photonics 2021, 8, 334. https://doi.org/10.3390/photonics8080334 https://www.mdpi.com/journal/photonics Photonics 2021, 8, 334 2 of 10 the searches for mesoscale particles of other geometric shapes are stimulated to extend the length of the photonic nanojet as far as possible from the particle surface [21,22]. It is also noted that the characteristics (length, width, and peak intensity) of photonic nanojets can be varied by changing the geometric parameters of mesoscale particles such as spheroids, hemispheres, core-shell spheres, toroids, axicons, pyramids, and cuboids [23–31]. However, the fabrication of composite inhomogeneous particles is a problem of great complexity. A natural method is required for assembling mesoscale particular particles in the next step. In natural materials, spider silk possesses several valuable features, including large tensile strength, great toughness, and high elasticity [32–34]. In general, spider silk is enclosed by meshes with nanosized strings and cavities. The appearance of a lyotropic liquid crystalline phase determines the mechanical properties of spider silk. Among spider silks, dragline silk possesses large tensile strength and is used as the skeleton of a web. Natural silk ﬁber can be utilized for optical guiding, imaging, and sensing applications due to its biocompatibility, bioresorbability, and excellent mechanical properties [35–40]. An optical microlens based on natural silk ﬁber could therefore be very practical, and needs further demonstration. In this study, we ﬁrst theoretically and experimentally demonstrate efﬁcient photonic nanojet modulation of a mesoscale metal–dielectric dome microlens based on natural silk ﬁber. The silk ﬁbers were directly collected from a daddy long-legs spider for fabricating the dome microlens due to their better homogeneity and mechanical properties. The glancing angle deposition technique was used to coat different metal layers on the dome surface. The inspections of the photonic nanojet modulations were performed by numerical simulations and a laser scanning digital microscope. The critical parameters of the focusing spot for the dome microlens with different metal coatings were studied systematically. 2. Experimental Methods 2.1. Metal–Dielectric Dome Microlens The cellar spider (Pholcus phalangioides), commonly known as the “daddy long-legs”, can be found throughout the world, especially in undisturbed low-light locations. People often associate this spider with living in the corners of a rooms near the ﬂoor and ceiling. Figure 1a shows a daddy long-legs spider that usually spins its webs large, loose, and ﬂat. A daddy long-legs spider was employed to output a single strand of silk ﬁber from the major ampullate gland for the experiments. Figure 1b shows the electric reeling system for silk ﬁber collection under controlled conditions of reeling speed, humidity, and temperature. A silk ﬁber with a smooth surface, circular cross-section, and uniform material quality was extracted with the reeling process. This silk ﬁber was a transparent medium, and the refractive index was about 1.55 in visible light region [35]. Due to the high refractive index contrast between silk ﬁber and the surrounding air, optical multimode guidance can be excited in the silk ﬁber [37]. After the reeling collection, a silk ﬁber with a 7 cm length and a 2 m diameter was ﬁxed at both ends of a specialized holder. A parafﬁn wax was placed below the bare silk ﬁber, and the photocurable resin (Everwide FP098) was dropped onto the silk’s surface. The refractive indices of the photocurable resin were 1.519, 1.503, and 1.495 for 405 nm, 532 nm, and 671 nm wavelengths, respectively. Due to the obstruction of the parafﬁn wax, the photocurable resin was concentrated only in one direction and formed a dome shape on the silk ﬁber. In the initial phase, slight resin drops condensed on the transparent puffs. As resin condensation continued, the puffs enlarged into bumps and ﬁnally became periodic dome shapes. The standing time of the photocurable resin determined the dome dimension because the silk ﬁber had the excellent ability of directional liquid collection. This structural wet-rebuilding ability of silk ﬁber has been reported in previous scientiﬁc literature [33]. Finally, the solidiﬁed dielectric dome microlens was obtained by using an ultraviolet oven (OPAS TX-500ST, Ganbow Technology Co., New Taipei City, Taiwan) and curing statically for 12 s. Furthermore, the glancing angle deposition technique was performed to coat different metal nanolayers on the dome surface [41]. Figure 1c shows the sputtering manufacturing process for coating Photonics 2021, 8, x FOR PEER REVIEW 3 of 10 scientific literature [33]. Finally, the solidified dielectric dome microlens was obtained by using an ultraviolet oven (OPAS TX-500ST, Ganbow Technology Co., New Taipei City, Photonics 2021, 8, 334 3 of 10 Taiwan) and curing statically for 12 s. Furthermore, the glancing angle deposition tech- nique was performed to coat different metal nanolayers on the dome surface [41]. Figure 1c shows the sputtering manufacturing process for coating the spider-silk-based met- al-dielectric dome microlens. The metal nanolayer could be uniformly deposited on the the spider-silk-based metal-dielectric dome microlens. The metal nanolayer could be dome surface because the silk fiber was inclined with respect to the metal target during uniformly deposited on the dome surface because the silk ﬁber was inclined with respect to the sputtering process. A scanning electron microscope (SEM) was employed to obtain the metal target during the sputtering process. A scanning electron microscope (SEM) was the actual images of the dome microlens on the silk fiber. Figure 1d exhibits an SEM im- employed to obtain the actual images of the dome microlens on the silk ﬁber. Figure 1d age of the spider-silk-based metal-dielectric dome microlens. It was observed that the exhibits an SEM image of the spider-silk-based metal-dielectric dome microlens. It was diameter of the silk fiber was about 2 μm, and the uniformity of dome shape was excel- observed that the diameter of the silk ﬁber was about 2 m, and the uniformity of dome shape lent. In order to veri was excellent. fIn y the meta order to lverify layer’s th the i metal ckness, the meta layer ’s thickness, l–dielectri thec dome mi metal–dielectric crolens dome was cl micr eaved olens by a commer was cleaved ciab l foc y a u commer sed ion beam s cial focused ystem (He ion beam lios N system anoL(Helios ab 600i,NanoLab FEI, Hill- 600i, scoro, O FEI,R Hillscor , USA). It w o, OR, as c USA). larified that t It was clariﬁed he thickness of that the thickness the metal na of the no-lmetal ayer wa nano-layer s about 5 was nm. The aboutsilk-based 5 nm. The metal–dielectric silk-based metal–dielectric dome micro dome lens could be microlens utilized could as be ua p tilized lasmonic as a plasmonic device. device. Figure 1. (a) A photo of a daddy long-legs spider. (b) The electric reeling system for the spider silk. Figure 1. (a) A photo of a daddy long-legs spider. (b) The electric reeling system for the spider silk. (c) The sputtering manufacturing process for coating the spider-silk-based metal–dielectric dome (c) The sputtering manufacturing process for coating the spider-silk-based metal–dielectric dome microlens. (d) An SEM image of the dome microlens. (e) The laser scanning digital microscope microlens. (d) An SEM image of the dome microlens. (e) The laser scanning digital microscope system for measuring the dome microlens. (f) A schematic diagram of the dome microlens for system for measuring the dome microlens. (f) A schematic diagram of the dome microlens for photonic nanojet modulation. photonic nanojet modulation. 2.2. Measurement Setup In the experiments, a commercial laser scanning digital microscope system (LEXT OLS4100, Olympus, Tokyo, Japan) was employed for measuring the optical ﬁeld intensity Photonics 2021, 8, 334 4 of 10 of different metal–dielectric dome microlenses [42]. Figure 1e shows the experimental conﬁguration of the measurement system. A diode-pumped solid-state laser with wave- lengths of 405 nm, 532 nm, and 671 nm was used for illuminating the dome microlens. The metal-dielectric dome microlens was clamped on a specialized holder and fastened on a three-axis motorized stage for aligning the laser beam. The auto-focus processing, based on Olympus software, was used to obtain accurate cross-section images with a 10 nm height resolution and 120 nm lateral resolution. The experimental images of the ﬁeld intensity distributions generated by the dome microlens were acquired by using an objective lens (MPLAPON100XLEXT, Olympus, Tokyo, Japan) with a working distance of 0.35 mm, a numerical aperture of 0.95, and a photomultiplier. The technical details of the commercial laser scanning digital microscope can be found on the ofﬁcial website for Olympus. Figure 1f shows the schematic diagram of the metal-dielectric dome microlens for photonic nanojet modulation. The convex side of the metal-dielectric dome microlens was illuminated by the laser beam along the x axis. The photonic nanojet is shown on the right side of the dome microlens. The focal length f is the axial distance from the ﬂat side of the dome microlens to the maximum peak amplitude (I ) along the x axis. The decay length is the axial max distance from the I at which the intensity distribution drops to I /e along the x axis. max max The full width at half-maximum (FWHM) is the transverse width between the I and max half-maximum point along the z axis. The ﬁnite-difference time-domain (FDTD) method was utilized to build the simulation model of the metal-dielectric dome microlens [43]. The mesh grid in the metal layer region was 1 nm for high accuracy, but the mesh grid in the dielectric and surrounding media was 20 nm for high calculation speed. Perfectly matched boundary layers were implemented along the boundaries of the simulation area. The gold-, silver-, and copper-coating layers had a refractive index of 0.54 + 2.23i, 0.05 + 3.43i, and 1.12 + 2.59i, respectively, at a wavelength of 532 nm [44]. The surrounding medium was air with a refractive index of 1. 3. Results and Discussions In order to achieve the function of photonic nanojet beam steering, it is important to be able to arbitrarily modulate the focusing property from different metal–dielectric dome microlenses. The numerical and experimental results of the photonic nanojet modulation were veriﬁed as indicated below. Figure 2a–d display the numerical results of normalized power ﬂow patterns for the dielectric, gold-coated, silver-coated, and copper-coated dome microlenses. From the amplitude distributions, one can observe that the photonic nanojet was formed close to the surface of the microlens for the dielectric dome microlens, while it moved away from the microlens surface for the metal-coated dome microlenses. In the case of a general sphere, the photonic nanojet only has a short focal length due to the rapid convergence and divergence near the focusing point [11]. The photonic nanojet can be modiﬁed by changing the design of the engineered spheres, which leads to a sharp spot size [12]. This concept demonstrated that the dome microlens acted like a ball lens, and the focusing spot was deformed along the propagation direction by the different metal nanolayer coatings. It was also observed that the effect of the metal nanolayers on the photonic nanojet beam shaping was clariﬁed by the power ﬂow patterns. The maximum intensity of the photonic nanojet changed as the metal nanolayers of dome microlenses changed. As seen from the power ﬂow patterns, the intensity of the photonic nanojet was effectively ampliﬁed by coating a gold nanolayer on the dome surface, due to the surface plasmon polaritons [45]. Photonics 2021, 8, x FOR PEER REVIEW 5 of 10 Compared with the simulation results, the focusing effect of the photonic nanojet is ex- hibited clearly in the raw images. Apparently, the field intensity distributions of the ex- periments were largely in agreement with the simulation results. As shown in Figure 2a,e, the dielectric dome microlens generated the photonic nanojet, the shape of which behaved in a manner similar to a stiletto knife. The field intensity distributions around the focusing point were nearly parallel, and therefore formed a narrow strip. It can be seen in Figure 2f that the focusing intensity of the gold-coated dome microlens was en- hanced significantly due to the surface plasmon resonance. The photonic nanojet’s focus with the surface plasmon resonance was almost three times the field intensity of the die- lectric dome microlens. Controllable photonic nanojet formation excited by plasmonic effects can be described by the dispersion relation of the surface plasmon polaritons [45,46]. The experimental image in Figure 2g demonstrates that the surface plasmon ab- sorption excited on the silver layer caused the intensity reduction of the photonic nanojet for the silver-coated dome microlens. In Figure 2h, the dispersion effect on the surface of Photonics 2021, 8, 334 5 of 10 the copper-coated dome microlens can be observed due to the surface plasmon scatter- ing. The surface-dependent reflectance arose from the copper layer, and the optical beam was dispersed from the layer surface. Figure 2. Numerical results of normalized power flow patterns for the (a) dielectric, (b) Figure 2. Numerical results of normalized power ﬂow patterns for the (a) dielectric, (b) gold-coated, gold-coated, (c) silver-coated, and (d) copper-coated dome microlenses; and raw experimental (c) silver-coated, and (d) copper-coated dome microlenses; and raw experimental images of the images of the (e) dielectric, (f) gold-coated, (g) silver-coated, and (h) copper-coated dome micro- (e) dielectric, (f) gold-coated, (g) silver-coated, and (h) copper-coated dome microlenses. The incident lenses. The incident wavelength was 532 nm for all the dome microlenses. The inset is a micro- wavelength was 532 nm for all the dome microlenses. The inset is a microphotograph of the spider- photograph of the spider-silk-based dome microlens. silk-based dome microlens. Figure 2e–h display the direct experimental images of the intensity distribution for different metal-dielectric dome microlenses at a 532 nm wavelength for veriﬁcation. Com- pared with the simulation results, the focusing effect of the photonic nanojet is exhibited clearly in the raw images. Apparently, the ﬁeld intensity distributions of the experiments were largely in agreement with the simulation results. As shown in Figure 2a,e, the di- electric dome microlens generated the photonic nanojet, the shape of which behaved in a manner similar to a stiletto knife. The ﬁeld intensity distributions around the focusing point were nearly parallel, and therefore formed a narrow strip. It can be seen in Figure 2f that the focusing intensity of the gold-coated dome microlens was enhanced signiﬁcantly due to the surface plasmon resonance. The photonic nanojet’s focus with the surface plas- mon resonance was almost three times the ﬁeld intensity of the dielectric dome microlens. Controllable photonic nanojet formation excited by plasmonic effects can be described by the dispersion relation of the surface plasmon polaritons [45,46]. The experimental image in Figure 2g demonstrates that the surface plasmon absorption excited on the silver layer caused the intensity reduction of the photonic nanojet for the silver-coated dome microlens. In Figure 2h, the dispersion effect on the surface of the copper-coated dome microlens Photonics 2021, 8, 334 6 of 10 Photonics 2021, 8, x FOR PEER REVIEW 6 of 10 can be observed due to the surface plasmon scattering. The surface-dependent reﬂectance arose from the copper layer, and the optical beam was dispersed from the layer surface. To quantitatively estimate the quality of the photonic nanojet, we determined sev- To quantitatively estimate the quality of the photonic nanojet, we determined several eral critical parameters from the field intensity distribution. Figure 3 shows the critical critical parameters from the ﬁeld intensity distribution. Figure 3 shows the critical parame- parameters as a function of the incident wavelength for the dome microlenses with dif- ters as a function of the incident wavelength for the dome microlenses with different metal ferent metal coatings. The focal lengths at a 532 nm wavelength were measured to be 2.27 coatings. The focal lengths at a 532 nm wavelength were measured to be 2.27 m, 2.66 m, μm, 2.66 μm, 2.75 μm, and 2.88 μm for the dielectric, gold-coated, silver-coated, and 2.75 m, and 2.88 m for the dielectric, gold-coated, silver-coated, and copper-coated dome copper-coated dome microlenses, respectively. The focal length increased as the incident microlenses, respectively. The focal length increased as the incident wavelength increased. wavelength increased. Compared to the dielectric dome microlens, the focal length was Compared to the dielectric dome microlens, the focal length was increased by 27% for the increased by 27% for the copper-coated dome microlens. The focal length could be ad- copper-coated dome microlens. The focal length could be adjusted by varying the metal justed by varying the metal layer. When the dome microlens was coated with a metal layer. When the dome microlens was coated with a metal layer, the focal length was large layer, the focal length was large enough to meet the working distance for microlens-aided enough to meet the working distance for microlens-aided imaging [2]. In Figure 3b, the imaging [2]. In Figure 3b, the decay lengths at a 532 nm wavelength were measured to be decay lengths at a 532 nm wavelength were measured to be 1.93 m, 2.29 m, 2.16 m, 1.93 μm, 2.29 μm, 2.16 μm, and 2.23 μm for the dielectric, gold-coated, silver-coated, and and 2.23 m for the dielectric, gold-coated, silver-coated, and copper-coated dome mi- copper-coated dome microlenses, respectively. It was observed that the decay length had crolenses, respectively. It was observed that the decay length had a maximum value at an a maximum value at an incident wavelength of 532 nm for all the metal-dielectric dome incident wavelength of 532 nm for all the metal-dielectric dome microlenses. In Figure 3c, microlenses. In Figure 3c, the transverse FWHMs at a 532 nm wavelength were measured the transverse FWHMs at a 532 nm wavelength were measured to be 192 nm, 215 nm, to be 192 nm, 215 nm, 232 nm, and 263 nm for the dielectric, gold-coated, silver-coated, 232 nm, and 263 nm for the dielectric, gold-coated, silver-coated, and copper-coated dome and copper-coated dome microlenses, respectively. The transverse FWHM of the pho- microlenses, respectively. The transverse FWHM of the photonic nanojet decreased as tonic nanojet decreased as the incident wavelength decreased. As the incident wave- the lengt incident h decrewavelength ased to 405 n decr m, t eased. he corres As p the onding incident FWHM bec wavelength ame decr signeased ificantlto y 405 less t nm, hanthe corr 0.5λesponding via the expFWHM erimental became verificat signiﬁcantly ions. The sug less gest than ed me 0.5 ta l-di via elec the triexperimental c dome microle veriﬁca- nses tions. showed The grea suggested t potenti met al fa olr fa -dielectric r-field super- dome re micr solu olenses tion litshowed hography a great nd potential imaging a for pplica far-ﬁeld - super tions [42 -resolution ]. lithography and imaging applications [42]. Figure 3. Critical parameters as a function of incident wavelength for the dome microlenses with Figure 3. Critical parameters as a function of incident wavelength for the dome microlenses with different metal coatings: (a) focal length, (b) decay length, and (c) FWHM. different metal coatings: (a) focal length, (b) decay length, and (c) FWHM. Photonics 2021, 8, x FOR PEER REVIEW 7 of 10 Photonics 2021, 8, 334 7 of 10 Figure 4a shows the normalized intensity distributions of photonic nanojets for the Figure 4a shows the normalized intensity distributions of photonic nanojets for the different metal-dielectric dome microlenses along the propagation axis (x axis). The different metal-dielectric dome microlenses along the propagation axis (x axis). The origin origin of the longitudinal profile along the propagation axis was located at the flat surface of the longitudinal proﬁle along the propagation axis was located at the ﬂat surface of the of the dome microlenses. All intensity profiles were normalized to the intensity profile dome microlenses. All intensity proﬁles were normalized to the intensity proﬁle for the for the dielectric dome microlens. The photonic nanojet generated by dome microlenses dielectric dome microlens. The photonic nanojet generated by dome microlenses emerged emerged in the form of a Gaussian distribution with an exponentially decaying trail. The in the form of a Gaussian distribution with an exponentially decaying trail. The length of length of the photonic nanojet increased as the dome microlens was coated with metal the photonic nanojet increased as the dome microlens was coated with metal layer, and layer, and the field intensity was enhanced as well. The maximum intensity increased by the ﬁeld intensity was enhanced as well. The maximum intensity increased by 180% for 180% for the gold coating, although the maximum intensity decreased by 10% for the the gold coating, although the maximum intensity decreased by 10% for the silver coating. silver coating. Depending on the metal layer, we observed that not only the intensity of Depending on the metal layer, we observed that not only the intensity of the photonic the photonic nanojet was enhanced, but the effective length of the photonic nanojet also nanojet was enhanced, but the effective length of the photonic nanojet also was elongated. was elongated. The engineered metal–dielectric dome microlens is expected to provide The engineered metal–dielectric dome microlens is expected to provide high concentration high concentration and low divergence in the focusing point [24]. and low divergence in the focusing point [24]. Figure 4. (a) Normalized intensity distributions of photonic nanojets for different metal-dielectric Figure 4. (a) Normalized intensity distributions of photonic nanojets for different metal-dielectric dome microlenses along the propagation axis (x axis). (b) FWHM as a function of the propagation dome microlenses along the propagation axis (x axis). (b) FWHM as a function of the propagation distance for photonic nanojets for the different metal-dielectric dome microlenses. The inset indi- distance for photonic nanojets for the different metal-dielectric dome microlenses. The inset indicates cates that the yellow arrow is the propagation direction, the red lines are the positions of serial that the yellow arrow is the propagation direction, the red lines are the positions of serial cross- cross-sections for the FWHM, and the blue lines are the straight fitting lines. sections for the FWHM, and the blue lines are the straight ﬁtting lines. Figure 4b shows the FWHM as a function of the propagation distance for the pho- Figure 4b shows the FWHM as a function of the propagation distance for the photonic tonic nanojets with different metal–dielectric dome microlenses. The origin of the prop- nanojets with different metal–dielectric dome microlenses. The origin of the propagation agation distance corresponded to the point of maximal peak amplitude. The slope of the distance corresponded to the point of maximal peak amplitude. The slope of the straight straight fitting line was used to determine the divergence angle of the photonic nanojets ﬁtting line was used to determine the divergence angle of the photonic nanojets [7]. The [7]. The divergence angles at a 532 nm wavelength were measured to be 6.3°, 2.6°, 3.8°, divergence angles at a 532 nm wavelength were measured to be 6.3 , 2.6 , 3.8 , and and 7.2° for the dielectric, gold-coated, silver-coated, and copper-coated dome micro- 7.2 for the dielectric, gold-coated, silver-coated, and copper-coated dome microlenses, lenses, respectively. The proposed metal-coated dome microlens can work with a low Photonics 2021, 8, 334 8 of 10 respectively. The proposed metal-coated dome microlens can work with a low divergence angle and long focal length, which is not possible for dielectric spherical microlenses. It was apparent that the divergence angle of the designed dome microlens was sensitive to the refractive index of the surrounding medium. When the dome microlens was coated with a metal layer, the refractive index of the surrounding medium could be found indirectly by measuring the divergence angle. Both the above-mentioned experimental and simulation results conﬁrmed that the metal-dielectric dome microlens with ﬂexible photonic nanojet modulation was suitable for a plasmonic sensor of the refractive index [47]. 4. Conclusions In this work, photonic nanojet modulation based on a metal-dielectric dome microlens was ﬁrst theoretically and experimentally demonstrated with an extended focal length, narrow beam waist, long effective length, and low divergence angle. The directional liquid collection capability of wet-rebuilt silk ﬁber was utilized for the formation of the dielectric dome microlens. The dielectric dome microlens was coated with different metal layers by using the glancing angle deposition technique. Through FDTD simulation and experimen- tal analysis, we concluded that the improvement of the photonic nanojet was attributed to the nature of surface plasmon polaritons, which caused a high concentration near the metal- dielectric interface. The gold-coated dome microlens had an intensity enhancement of about three times due to surface plasmon resonance. The focal length of the photonic nano- jet was increased by 27% for the copper-coated dome microlens. A minimum divergence angle of 2.6 was achieved by the gold-coated dome microlens. Moreover, the proposed metal-dielectric dome microlens showed compatibility with the adjacent wavelengths and a spot width less than half-wavelength. These kinds of plasmonic microlenses have great potential in far-ﬁeld ﬂexible parallel lithography with a sub-wavelength line width. Author Contributions: Conceptualization, C.-B.L. and C.-Y.L.; methodology, C.-B.L. and C.-Y.L.; software, C.-Y.L. and W.-Y.C.; validation, C.-Y.L. and W.-Y.C.; formal analysis, C.-B.L. and Y.-H.L.; resources, C.-Y.L.; data curation, Y.-H.L. and W.-Y.C.; writing—original draft preparation, C.-Y.L.; writing—review and editing, C.-B.L. and C.-Y.L.; visualization, C.-Y.L. and W.-Y.C.; supervision, C.-B.L. and C.-Y.L.; project administration, C.-Y.L. and W.-Y.C.; funding acquisition, C.-Y.L. All authors have read and agreed to the published version of the manuscript. Funding: This research was funded by the Ministry of Science and Technology of Taiwan (MOST 108- 2221-E-010-012-MY3, MOST 109-2923-E-010-001-MY2) and the Yen Tjing Ling Medical Foundation (CI-110-28). Institutional Review Board Statement: Not applicable. 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Abstract

hv photonics Communication Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens 1 1 2 2 , Ching-Bin Lin , Yu-Hsiang Lin , Wei-Yu Chen and Cheng-Yang Liu * Department of Mechanical and Electro-Mechanical Engineering, Tamkang University, New Taipei City 25137, Taiwan; cblin@mail.tku.edu.tw (C.-B.L.); 607370037@gms.tku.edu.tw (Y.-H.L.) Department of Biomedical Engineering, National Yang Ming Chiao Tung University, Taipei 112, Taiwan; sam30261014.be09@nycu.edu.tw * Correspondence: cyliu66@nycu.edu.tw; Tel.: +886-2-28267020 Abstract: The photonic nanojet is a non-resonance focusing phenomenon with high intensity and narrow spot that can serve as a powerful biosensor for in vivo detection of red blood cells, micro- organisms, and tumor cells in blood. In this study, we ﬁrst demonstrated photonic nanojet modulation by utilizing a spider-silk-based metal–dielectric dome microlens. A cellar spider was employed in extracting the silk ﬁber, which possesses a liquid-collecting ability to form a dielectric dome microlens. The metal casing on the surface of the dielectric dome was coated by using a glancing angle deposition technique. Due to the nature of surface plasmon polaritons, the characteristics of photonic nanojets are strongly modulated by different metal casings. Numerical and experimental results showed that the intensity of the photonic nanojet was increased by a factor of three for the gold-coated dome microlens due to surface plasmon resonance. The spider-silk-based metal-dielectric dome microlens could be used to scan a biological target for large-area imaging with a conventional optical microscope. Keywords: photonic nanojet; spider silk; dome lens Citation: Lin, C.-B.; Lin, Y.-H.; Chen, W.-Y.; Liu, C.-Y. Photonic Nanojet Modulation Achieved by a Spider- Silk-Based Metal–Dielectric Dome 1. Introduction Microlens. Photonics 2021, 8, 334. Currently, the design of mesoscale photonic devices with high spatial resolution and https://doi.org/10.3390/ operation speed opens up prospects for the evolution of novel microscopic and manufac- photonics8080334 turing technologies [1,2]. According to the principle of optics, the spatial resolution of traditional optical elements is deﬁned by diffraction, and the minimum dimension of the Received: 21 July 2021 focal spot is more than half the wavelength of the incident light wave. This description sig- Accepted: 12 August 2021 niﬁes that traditional optical elements in the circuit are positioned at an extensive distance Published: 14 August 2021 from each other compared to the wavelength. Therefore, multitudinous investigations have veriﬁed the materialization of a high-intensity optical ﬁeld restrained in a region when Publisher’s Note: MDPI stays neutral the light wave was focused by a mesoscale dielectric particle [3–14]. This phenomenon is with regard to jurisdictional claims in referred to in several academic papers as the photonic nanojet effect. For generating a pho- published maps and institutional afﬁl- tonic nanojet, the Mie size parameter (q = 2r/) of a dielectric particle should correspond iations. to q~(2 . . . 40), where r is the particle radius and is the operating wavelength [15,16]. In contrast to the case of focusing radiation with a traditional optical lens, a photonic nanojet is formed in the near-scattering area, where the intensity ﬁeld is a complex spatial structure determined by a superposition of outgoing and decaying evanescent waves. The intensity Copyright: © 2021 by the authors. distribution and localization of a photonic nanojet depends on the shapes and physical Licensee MDPI, Basel, Switzerland. properties of the mesoscale dielectric particles and surrounding media. As a rule, the as- This article is an open access article semblies of mesoscale particles are embedded in a polymer ﬁlm, which makes it possible to distributed under the terms and arrange particles in diverse spatial conﬁgurations [17–20]. Such a composite polymer ﬁlm conditions of the Creative Commons will lead to a multiple increase in the intensity ﬁeld of a photonic nanojet. However, one of Attribution (CC BY) license (https:// the problems with photonic nanojets in near-ﬁeld focusing is the short spatial length of creativecommons.org/licenses/by/ the focal region that emerges near the convex surface of classical particle geometry. Hence, 4.0/). Photonics 2021, 8, 334. https://doi.org/10.3390/photonics8080334 https://www.mdpi.com/journal/photonics Photonics 2021, 8, 334 2 of 10 the searches for mesoscale particles of other geometric shapes are stimulated to extend the length of the photonic nanojet as far as possible from the particle surface [21,22]. It is also noted that the characteristics (length, width, and peak intensity) of photonic nanojets can be varied by changing the geometric parameters of mesoscale particles such as spheroids, hemispheres, core-shell spheres, toroids, axicons, pyramids, and cuboids [23–31]. However, the fabrication of composite inhomogeneous particles is a problem of great complexity. A natural method is required for assembling mesoscale particular particles in the next step. In natural materials, spider silk possesses several valuable features, including large tensile strength, great toughness, and high elasticity [32–34]. In general, spider silk is enclosed by meshes with nanosized strings and cavities. The appearance of a lyotropic liquid crystalline phase determines the mechanical properties of spider silk. Among spider silks, dragline silk possesses large tensile strength and is used as the skeleton of a web. Natural silk ﬁber can be utilized for optical guiding, imaging, and sensing applications due to its biocompatibility, bioresorbability, and excellent mechanical properties [35–40]. An optical microlens based on natural silk ﬁber could therefore be very practical, and needs further demonstration. In this study, we ﬁrst theoretically and experimentally demonstrate efﬁcient photonic nanojet modulation of a mesoscale metal–dielectric dome microlens based on natural silk ﬁber. The silk ﬁbers were directly collected from a daddy long-legs spider for fabricating the dome microlens due to their better homogeneity and mechanical properties. The glancing angle deposition technique was used to coat different metal layers on the dome surface. The inspections of the photonic nanojet modulations were performed by numerical simulations and a laser scanning digital microscope. The critical parameters of the focusing spot for the dome microlens with different metal coatings were studied systematically. 2. Experimental Methods 2.1. Metal–Dielectric Dome Microlens The cellar spider (Pholcus phalangioides), commonly known as the “daddy long-legs”, can be found throughout the world, especially in undisturbed low-light locations. People often associate this spider with living in the corners of a rooms near the ﬂoor and ceiling. Figure 1a shows a daddy long-legs spider that usually spins its webs large, loose, and ﬂat. A daddy long-legs spider was employed to output a single strand of silk ﬁber from the major ampullate gland for the experiments. Figure 1b shows the electric reeling system for silk ﬁber collection under controlled conditions of reeling speed, humidity, and temperature. A silk ﬁber with a smooth surface, circular cross-section, and uniform material quality was extracted with the reeling process. This silk ﬁber was a transparent medium, and the refractive index was about 1.55 in visible light region [35]. Due to the high refractive index contrast between silk ﬁber and the surrounding air, optical multimode guidance can be excited in the silk ﬁber [37]. After the reeling collection, a silk ﬁber with a 7 cm length and a 2 m diameter was ﬁxed at both ends of a specialized holder. A parafﬁn wax was placed below the bare silk ﬁber, and the photocurable resin (Everwide FP098) was dropped onto the silk’s surface. The refractive indices of the photocurable resin were 1.519, 1.503, and 1.495 for 405 nm, 532 nm, and 671 nm wavelengths, respectively. Due to the obstruction of the parafﬁn wax, the photocurable resin was concentrated only in one direction and formed a dome shape on the silk ﬁber. In the initial phase, slight resin drops condensed on the transparent puffs. As resin condensation continued, the puffs enlarged into bumps and ﬁnally became periodic dome shapes. The standing time of the photocurable resin determined the dome dimension because the silk ﬁber had the excellent ability of directional liquid collection. This structural wet-rebuilding ability of silk ﬁber has been reported in previous scientiﬁc literature [33]. Finally, the solidiﬁed dielectric dome microlens was obtained by using an ultraviolet oven (OPAS TX-500ST, Ganbow Technology Co., New Taipei City, Taiwan) and curing statically for 12 s. Furthermore, the glancing angle deposition technique was performed to coat different metal nanolayers on the dome surface [41]. Figure 1c shows the sputtering manufacturing process for coating Photonics 2021, 8, x FOR PEER REVIEW 3 of 10 scientific literature [33]. Finally, the solidified dielectric dome microlens was obtained by using an ultraviolet oven (OPAS TX-500ST, Ganbow Technology Co., New Taipei City, Photonics 2021, 8, 334 3 of 10 Taiwan) and curing statically for 12 s. Furthermore, the glancing angle deposition tech- nique was performed to coat different metal nanolayers on the dome surface [41]. Figure 1c shows the sputtering manufacturing process for coating the spider-silk-based met- al-dielectric dome microlens. The metal nanolayer could be uniformly deposited on the the spider-silk-based metal-dielectric dome microlens. The metal nanolayer could be dome surface because the silk fiber was inclined with respect to the metal target during uniformly deposited on the dome surface because the silk ﬁber was inclined with respect to the sputtering process. A scanning electron microscope (SEM) was employed to obtain the metal target during the sputtering process. A scanning electron microscope (SEM) was the actual images of the dome microlens on the silk fiber. Figure 1d exhibits an SEM im- employed to obtain the actual images of the dome microlens on the silk ﬁber. Figure 1d age of the spider-silk-based metal-dielectric dome microlens. It was observed that the exhibits an SEM image of the spider-silk-based metal-dielectric dome microlens. It was diameter of the silk fiber was about 2 μm, and the uniformity of dome shape was excel- observed that the diameter of the silk ﬁber was about 2 m, and the uniformity of dome shape lent. In order to veri was excellent. fIn y the meta order to lverify layer’s th the i metal ckness, the meta layer ’s thickness, l–dielectri thec dome mi metal–dielectric crolens dome was cl micr eaved olens by a commer was cleaved ciab l foc y a u commer sed ion beam s cial focused ystem (He ion beam lios N system anoL(Helios ab 600i,NanoLab FEI, Hill- 600i, scoro, O FEI,R Hillscor , USA). It w o, OR, as c USA). larified that t It was clariﬁed he thickness of that the thickness the metal na of the no-lmetal ayer wa nano-layer s about 5 was nm. The aboutsilk-based 5 nm. The metal–dielectric silk-based metal–dielectric dome micro dome lens could be microlens utilized could as be ua p tilized lasmonic as a plasmonic device. device. Figure 1. (a) A photo of a daddy long-legs spider. (b) The electric reeling system for the spider silk. Figure 1. (a) A photo of a daddy long-legs spider. (b) The electric reeling system for the spider silk. (c) The sputtering manufacturing process for coating the spider-silk-based metal–dielectric dome (c) The sputtering manufacturing process for coating the spider-silk-based metal–dielectric dome microlens. (d) An SEM image of the dome microlens. (e) The laser scanning digital microscope microlens. (d) An SEM image of the dome microlens. (e) The laser scanning digital microscope system for measuring the dome microlens. (f) A schematic diagram of the dome microlens for system for measuring the dome microlens. (f) A schematic diagram of the dome microlens for photonic nanojet modulation. photonic nanojet modulation. 2.2. Measurement Setup In the experiments, a commercial laser scanning digital microscope system (LEXT OLS4100, Olympus, Tokyo, Japan) was employed for measuring the optical ﬁeld intensity Photonics 2021, 8, 334 4 of 10 of different metal–dielectric dome microlenses [42]. Figure 1e shows the experimental conﬁguration of the measurement system. A diode-pumped solid-state laser with wave- lengths of 405 nm, 532 nm, and 671 nm was used for illuminating the dome microlens. The metal-dielectric dome microlens was clamped on a specialized holder and fastened on a three-axis motorized stage for aligning the laser beam. The auto-focus processing, based on Olympus software, was used to obtain accurate cross-section images with a 10 nm height resolution and 120 nm lateral resolution. The experimental images of the ﬁeld intensity distributions generated by the dome microlens were acquired by using an objective lens (MPLAPON100XLEXT, Olympus, Tokyo, Japan) with a working distance of 0.35 mm, a numerical aperture of 0.95, and a photomultiplier. The technical details of the commercial laser scanning digital microscope can be found on the ofﬁcial website for Olympus. Figure 1f shows the schematic diagram of the metal-dielectric dome microlens for photonic nanojet modulation. The convex side of the metal-dielectric dome microlens was illuminated by the laser beam along the x axis. The photonic nanojet is shown on the right side of the dome microlens. The focal length f is the axial distance from the ﬂat side of the dome microlens to the maximum peak amplitude (I ) along the x axis. The decay length is the axial max distance from the I at which the intensity distribution drops to I /e along the x axis. max max The full width at half-maximum (FWHM) is the transverse width between the I and max half-maximum point along the z axis. The ﬁnite-difference time-domain (FDTD) method was utilized to build the simulation model of the metal-dielectric dome microlens [43]. The mesh grid in the metal layer region was 1 nm for high accuracy, but the mesh grid in the dielectric and surrounding media was 20 nm for high calculation speed. Perfectly matched boundary layers were implemented along the boundaries of the simulation area. The gold-, silver-, and copper-coating layers had a refractive index of 0.54 + 2.23i, 0.05 + 3.43i, and 1.12 + 2.59i, respectively, at a wavelength of 532 nm [44]. The surrounding medium was air with a refractive index of 1. 3. Results and Discussions In order to achieve the function of photonic nanojet beam steering, it is important to be able to arbitrarily modulate the focusing property from different metal–dielectric dome microlenses. The numerical and experimental results of the photonic nanojet modulation were veriﬁed as indicated below. Figure 2a–d display the numerical results of normalized power ﬂow patterns for the dielectric, gold-coated, silver-coated, and copper-coated dome microlenses. From the amplitude distributions, one can observe that the photonic nanojet was formed close to the surface of the microlens for the dielectric dome microlens, while it moved away from the microlens surface for the metal-coated dome microlenses. In the case of a general sphere, the photonic nanojet only has a short focal length due to the rapid convergence and divergence near the focusing point [11]. The photonic nanojet can be modiﬁed by changing the design of the engineered spheres, which leads to a sharp spot size [12]. This concept demonstrated that the dome microlens acted like a ball lens, and the focusing spot was deformed along the propagation direction by the different metal nanolayer coatings. It was also observed that the effect of the metal nanolayers on the photonic nanojet beam shaping was clariﬁed by the power ﬂow patterns. The maximum intensity of the photonic nanojet changed as the metal nanolayers of dome microlenses changed. As seen from the power ﬂow patterns, the intensity of the photonic nanojet was effectively ampliﬁed by coating a gold nanolayer on the dome surface, due to the surface plasmon polaritons [45]. Photonics 2021, 8, x FOR PEER REVIEW 5 of 10 Compared with the simulation results, the focusing effect of the photonic nanojet is ex- hibited clearly in the raw images. Apparently, the field intensity distributions of the ex- periments were largely in agreement with the simulation results. As shown in Figure 2a,e, the dielectric dome microlens generated the photonic nanojet, the shape of which behaved in a manner similar to a stiletto knife. The field intensity distributions around the focusing point were nearly parallel, and therefore formed a narrow strip. It can be seen in Figure 2f that the focusing intensity of the gold-coated dome microlens was en- hanced significantly due to the surface plasmon resonance. The photonic nanojet’s focus with the surface plasmon resonance was almost three times the field intensity of the die- lectric dome microlens. Controllable photonic nanojet formation excited by plasmonic effects can be described by the dispersion relation of the surface plasmon polaritons [45,46]. The experimental image in Figure 2g demonstrates that the surface plasmon ab- sorption excited on the silver layer caused the intensity reduction of the photonic nanojet for the silver-coated dome microlens. In Figure 2h, the dispersion effect on the surface of Photonics 2021, 8, 334 5 of 10 the copper-coated dome microlens can be observed due to the surface plasmon scatter- ing. The surface-dependent reflectance arose from the copper layer, and the optical beam was dispersed from the layer surface. Figure 2. Numerical results of normalized power flow patterns for the (a) dielectric, (b) Figure 2. Numerical results of normalized power ﬂow patterns for the (a) dielectric, (b) gold-coated, gold-coated, (c) silver-coated, and (d) copper-coated dome microlenses; and raw experimental (c) silver-coated, and (d) copper-coated dome microlenses; and raw experimental images of the images of the (e) dielectric, (f) gold-coated, (g) silver-coated, and (h) copper-coated dome micro- (e) dielectric, (f) gold-coated, (g) silver-coated, and (h) copper-coated dome microlenses. The incident lenses. The incident wavelength was 532 nm for all the dome microlenses. The inset is a micro- wavelength was 532 nm for all the dome microlenses. The inset is a microphotograph of the spider- photograph of the spider-silk-based dome microlens. silk-based dome microlens. Figure 2e–h display the direct experimental images of the intensity distribution for different metal-dielectric dome microlenses at a 532 nm wavelength for veriﬁcation. Com- pared with the simulation results, the focusing effect of the photonic nanojet is exhibited clearly in the raw images. Apparently, the ﬁeld intensity distributions of the experiments were largely in agreement with the simulation results. As shown in Figure 2a,e, the di- electric dome microlens generated the photonic nanojet, the shape of which behaved in a manner similar to a stiletto knife. The ﬁeld intensity distributions around the focusing point were nearly parallel, and therefore formed a narrow strip. It can be seen in Figure 2f that the focusing intensity of the gold-coated dome microlens was enhanced signiﬁcantly due to the surface plasmon resonance. The photonic nanojet’s focus with the surface plas- mon resonance was almost three times the ﬁeld intensity of the dielectric dome microlens. Controllable photonic nanojet formation excited by plasmonic effects can be described by the dispersion relation of the surface plasmon polaritons [45,46]. The experimental image in Figure 2g demonstrates that the surface plasmon absorption excited on the silver layer caused the intensity reduction of the photonic nanojet for the silver-coated dome microlens. In Figure 2h, the dispersion effect on the surface of the copper-coated dome microlens Photonics 2021, 8, 334 6 of 10 Photonics 2021, 8, x FOR PEER REVIEW 6 of 10 can be observed due to the surface plasmon scattering. The surface-dependent reﬂectance arose from the copper layer, and the optical beam was dispersed from the layer surface. To quantitatively estimate the quality of the photonic nanojet, we determined sev- To quantitatively estimate the quality of the photonic nanojet, we determined several eral critical parameters from the field intensity distribution. Figure 3 shows the critical critical parameters from the ﬁeld intensity distribution. Figure 3 shows the critical parame- parameters as a function of the incident wavelength for the dome microlenses with dif- ters as a function of the incident wavelength for the dome microlenses with different metal ferent metal coatings. The focal lengths at a 532 nm wavelength were measured to be 2.27 coatings. The focal lengths at a 532 nm wavelength were measured to be 2.27 m, 2.66 m, μm, 2.66 μm, 2.75 μm, and 2.88 μm for the dielectric, gold-coated, silver-coated, and 2.75 m, and 2.88 m for the dielectric, gold-coated, silver-coated, and copper-coated dome copper-coated dome microlenses, respectively. The focal length increased as the incident microlenses, respectively. The focal length increased as the incident wavelength increased. wavelength increased. Compared to the dielectric dome microlens, the focal length was Compared to the dielectric dome microlens, the focal length was increased by 27% for the increased by 27% for the copper-coated dome microlens. The focal length could be ad- copper-coated dome microlens. The focal length could be adjusted by varying the metal justed by varying the metal layer. When the dome microlens was coated with a metal layer. When the dome microlens was coated with a metal layer, the focal length was large layer, the focal length was large enough to meet the working distance for microlens-aided enough to meet the working distance for microlens-aided imaging [2]. In Figure 3b, the imaging [2]. In Figure 3b, the decay lengths at a 532 nm wavelength were measured to be decay lengths at a 532 nm wavelength were measured to be 1.93 m, 2.29 m, 2.16 m, 1.93 μm, 2.29 μm, 2.16 μm, and 2.23 μm for the dielectric, gold-coated, silver-coated, and and 2.23 m for the dielectric, gold-coated, silver-coated, and copper-coated dome mi- copper-coated dome microlenses, respectively. It was observed that the decay length had crolenses, respectively. It was observed that the decay length had a maximum value at an a maximum value at an incident wavelength of 532 nm for all the metal-dielectric dome incident wavelength of 532 nm for all the metal-dielectric dome microlenses. In Figure 3c, microlenses. In Figure 3c, the transverse FWHMs at a 532 nm wavelength were measured the transverse FWHMs at a 532 nm wavelength were measured to be 192 nm, 215 nm, to be 192 nm, 215 nm, 232 nm, and 263 nm for the dielectric, gold-coated, silver-coated, 232 nm, and 263 nm for the dielectric, gold-coated, silver-coated, and copper-coated dome and copper-coated dome microlenses, respectively. The transverse FWHM of the pho- microlenses, respectively. The transverse FWHM of the photonic nanojet decreased as tonic nanojet decreased as the incident wavelength decreased. As the incident wave- the lengt incident h decrewavelength ased to 405 n decr m, t eased. he corres As p the onding incident FWHM bec wavelength ame decr signeased ificantlto y 405 less t nm, hanthe corr 0.5λesponding via the expFWHM erimental became verificat signiﬁcantly ions. The sug less gest than ed me 0.5 ta l-di via elec the triexperimental c dome microle veriﬁca- nses tions. showed The grea suggested t potenti met al fa olr fa -dielectric r-field super- dome re micr solu olenses tion litshowed hography a great nd potential imaging a for pplica far-ﬁeld - super tions [42 -resolution ]. lithography and imaging applications [42]. Figure 3. Critical parameters as a function of incident wavelength for the dome microlenses with Figure 3. Critical parameters as a function of incident wavelength for the dome microlenses with different metal coatings: (a) focal length, (b) decay length, and (c) FWHM. different metal coatings: (a) focal length, (b) decay length, and (c) FWHM. Photonics 2021, 8, x FOR PEER REVIEW 7 of 10 Photonics 2021, 8, 334 7 of 10 Figure 4a shows the normalized intensity distributions of photonic nanojets for the Figure 4a shows the normalized intensity distributions of photonic nanojets for the different metal-dielectric dome microlenses along the propagation axis (x axis). The different metal-dielectric dome microlenses along the propagation axis (x axis). The origin origin of the longitudinal profile along the propagation axis was located at the flat surface of the longitudinal proﬁle along the propagation axis was located at the ﬂat surface of the of the dome microlenses. All intensity profiles were normalized to the intensity profile dome microlenses. All intensity proﬁles were normalized to the intensity proﬁle for the for the dielectric dome microlens. The photonic nanojet generated by dome microlenses dielectric dome microlens. The photonic nanojet generated by dome microlenses emerged emerged in the form of a Gaussian distribution with an exponentially decaying trail. The in the form of a Gaussian distribution with an exponentially decaying trail. The length of length of the photonic nanojet increased as the dome microlens was coated with metal the photonic nanojet increased as the dome microlens was coated with metal layer, and layer, and the field intensity was enhanced as well. The maximum intensity increased by the ﬁeld intensity was enhanced as well. The maximum intensity increased by 180% for 180% for the gold coating, although the maximum intensity decreased by 10% for the the gold coating, although the maximum intensity decreased by 10% for the silver coating. silver coating. Depending on the metal layer, we observed that not only the intensity of Depending on the metal layer, we observed that not only the intensity of the photonic the photonic nanojet was enhanced, but the effective length of the photonic nanojet also nanojet was enhanced, but the effective length of the photonic nanojet also was elongated. was elongated. The engineered metal–dielectric dome microlens is expected to provide The engineered metal–dielectric dome microlens is expected to provide high concentration high concentration and low divergence in the focusing point [24]. and low divergence in the focusing point [24]. Figure 4. (a) Normalized intensity distributions of photonic nanojets for different metal-dielectric Figure 4. (a) Normalized intensity distributions of photonic nanojets for different metal-dielectric dome microlenses along the propagation axis (x axis). (b) FWHM as a function of the propagation dome microlenses along the propagation axis (x axis). (b) FWHM as a function of the propagation distance for photonic nanojets for the different metal-dielectric dome microlenses. The inset indi- distance for photonic nanojets for the different metal-dielectric dome microlenses. The inset indicates cates that the yellow arrow is the propagation direction, the red lines are the positions of serial that the yellow arrow is the propagation direction, the red lines are the positions of serial cross- cross-sections for the FWHM, and the blue lines are the straight fitting lines. sections for the FWHM, and the blue lines are the straight ﬁtting lines. Figure 4b shows the FWHM as a function of the propagation distance for the pho- Figure 4b shows the FWHM as a function of the propagation distance for the photonic tonic nanojets with different metal–dielectric dome microlenses. The origin of the prop- nanojets with different metal–dielectric dome microlenses. The origin of the propagation agation distance corresponded to the point of maximal peak amplitude. The slope of the distance corresponded to the point of maximal peak amplitude. The slope of the straight straight fitting line was used to determine the divergence angle of the photonic nanojets ﬁtting line was used to determine the divergence angle of the photonic nanojets [7]. The [7]. The divergence angles at a 532 nm wavelength were measured to be 6.3°, 2.6°, 3.8°, divergence angles at a 532 nm wavelength were measured to be 6.3 , 2.6 , 3.8 , and and 7.2° for the dielectric, gold-coated, silver-coated, and copper-coated dome micro- 7.2 for the dielectric, gold-coated, silver-coated, and copper-coated dome microlenses, lenses, respectively. The proposed metal-coated dome microlens can work with a low Photonics 2021, 8, 334 8 of 10 respectively. The proposed metal-coated dome microlens can work with a low divergence angle and long focal length, which is not possible for dielectric spherical microlenses. It was apparent that the divergence angle of the designed dome microlens was sensitive to the refractive index of the surrounding medium. When the dome microlens was coated with a metal layer, the refractive index of the surrounding medium could be found indirectly by measuring the divergence angle. Both the above-mentioned experimental and simulation results conﬁrmed that the metal-dielectric dome microlens with ﬂexible photonic nanojet modulation was suitable for a plasmonic sensor of the refractive index [47]. 4. Conclusions In this work, photonic nanojet modulation based on a metal-dielectric dome microlens was ﬁrst theoretically and experimentally demonstrated with an extended focal length, narrow beam waist, long effective length, and low divergence angle. The directional liquid collection capability of wet-rebuilt silk ﬁber was utilized for the formation of the dielectric dome microlens. The dielectric dome microlens was coated with different metal layers by using the glancing angle deposition technique. Through FDTD simulation and experimen- tal analysis, we concluded that the improvement of the photonic nanojet was attributed to the nature of surface plasmon polaritons, which caused a high concentration near the metal- dielectric interface. The gold-coated dome microlens had an intensity enhancement of about three times due to surface plasmon resonance. The focal length of the photonic nano- jet was increased by 27% for the copper-coated dome microlens. A minimum divergence angle of 2.6 was achieved by the gold-coated dome microlens. Moreover, the proposed metal-dielectric dome microlens showed compatibility with the adjacent wavelengths and a spot width less than half-wavelength. These kinds of plasmonic microlenses have great potential in far-ﬁeld ﬂexible parallel lithography with a sub-wavelength line width. Author Contributions: Conceptualization, C.-B.L. and C.-Y.L.; methodology, C.-B.L. and C.-Y.L.; software, C.-Y.L. and W.-Y.C.; validation, C.-Y.L. and W.-Y.C.; formal analysis, C.-B.L. and Y.-H.L.; resources, C.-Y.L.; data curation, Y.-H.L. and W.-Y.C.; writing—original draft preparation, C.-Y.L.; writing—review and editing, C.-B.L. and C.-Y.L.; visualization, C.-Y.L. and W.-Y.C.; supervision, C.-B.L. and C.-Y.L.; project administration, C.-Y.L. and W.-Y.C.; funding acquisition, C.-Y.L. All authors have read and agreed to the published version of the manuscript. Funding: This research was funded by the Ministry of Science and Technology of Taiwan (MOST 108- 2221-E-010-012-MY3, MOST 109-2923-E-010-001-MY2) and the Yen Tjing Ling Medical Foundation (CI-110-28). Institutional Review Board Statement: Not applicable. 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Photonics – Multidisciplinary Digital Publishing Institute

Published: Aug 14, 2021

Keywords: photonic nanojet; spider silk; dome lens

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Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens

Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens

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Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens

Photonic Nanojet Modulation Achieved by a Spider-Silk-Based Metal–Dielectric Dome Microlens

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