18 research outputs found
Single-mode limit and bending losses for shallow Rib Si3N4 waveguides
Published version also available at http://dx.doi.org/10.1109/JPHOT.2014.2387252.The single-mode limit and bending losses for shallow rib waveguides are studied
using the full vectorial film mode matching method. The maximum rib height for
single-mode waveguides is found to be on the order of 10 nm for a rib width of 2 m and
a wavelength of 785 nm, with the exact value depending on the core thickness and the
polarization. Bending losses are calculated as a function of several geometrical parameters,
for both polarizations and for the fundamental and the first order modes. Bending
losses decrease significantly with rib height for single-mode waveguides. For slightly
larger rib heights, giving multimode waveguides, it is found that the bending losses for
the first-order mode are several orders of magnitude larger than for the fundamental
mode. Thus, a small bend can act as an excellent mode filter, making it possible to use
higher ribs giving low bending losses for the fundamental mode, while maintaining the
waveguide practically single-mode. For TM-polarization, leakage loss can be important
and can cause bending losses to increase for larger rib heights (8–80 nm)
UV-Nanoimprint Lithography for Predefined SERS Nanopatterns Which Are Reproducible at Low Cost and High Throughput
A controlled and reliable nanostructured metallic substrate is a prerequisite for developing effective surface-enhanced Raman scattering (SERS) spectroscopy techniques. In this study, we present a novel SERS platform fabricated using ultra-violet nanoimprint lithography (UV-NIL) to produce large-area, ordered nanostructured arrays. By using UV-NIL imprinted patterns in resist, we were able to overcome the main limitations present in most common SERS platforms, such as nonuniformity, nonreproducibility, low throughput, and high cost. We simulated and fabricated C-shaped plasmonic nanostructures that exhibit high signal enhancement at an excitation wavelength of 785 nm. The substrates were fabricated by directly coating the imprinted resist with a thin gold layer. Avoiding the need to etch patterns in silicon significantly reduces the time and cost of fabrication and facilitates reproducibility. The functionality of the substrates for SERS detection was validated by measuring the SERS spectra of Rhodamine 6G.publishedVersio
MEMS-tunable dielectric metasurface lens using thin-film PZT for large displacements at low voltages
Tunable focusing is a desired property in a wide range of optical imaging and sensing technologies but has tended to require bulky components that cannot be integrated on-chip and have slow actuation speeds. Recently, integration of metasurfaces into electrostatic micro-electromechanical system (MEMS) architectures has shown potential to overcome these challenges but has offered limited out-of-plane displacement range while requiring large voltages. We demonstrate for the first time, to the best of our knowledge, a movable metasurface lens actuated by integrated thin-film PZT MEMS, which has the advantage of offering large displacements at low voltages. An out-of-plane displacement of a metasurface in the range of 7.2 µm is demonstrated under a voltage application of 23 V. This is roughly twice the displacement at a quarter of the voltage of state of the art electrostatic out-of-plane actuation of metasurfaces. Using this tunability, we demonstrate a varifocal lens doublet with a focal shift of the order of 250 µm at the wavelength 1.55 μm. The thin-film PZT MEMS-metasurface is a promising platform for miniaturized varifocal components.publishedVersio
Label-free nanoscopy enabled by coherent imaging with photonic waveguides
SPIE Article-Sharing Policies https://www.spiedigitallibrary.org/article-sharing-policiesIn this project it was found that Fourier ptychographic microscopy can be improved far beyond its conventional limits via waveguide-based optical systems. Extensive in silico studies showed that images obtained on highrefractive index material waveguide chips in conjunction with hyperspectral illumination light and finely designed waveguide geometries can be combined via a modified phase-retrieval algorithm to yield a resolution below 150 nm
Photonic-chip assisted correlative light and electron microscopy
Correlative light-electron microscopy (CLEM) unifies the versatility of light
microscopy (LM) with the high resolution of electron microscopy (EM), allowing
one to zoom into the complex organization of cells. Most CLEM techniques use
ultrathin sections, and thus lack the 3D-EM structural information, and
focusing on a very restricted field of view. Here, we introduce photonic chip
assisted CLEM, enabling multi-modal total internal reflection fluorescence
(TIRF) microscopy over large field of view and high precision localization of
the target area of interest within EM. The chip-based direct stochastic optical
reconstruction microscopy (dSTORM), and 3D high precision correlation of
biological processes by focused ion beam-scanning electron microscopy (FIB-SEM)
is further demonstrated. The core layer of the photonic chips are used as a
substrate to hold, to illuminate and the cladding layer is used to enable
high-precision landmarking of the sample through specially designed grid-like
numbering systems. The landmarks are fabricated on the cladding of the photonic
chips as extruding pillars from the waveguide surface, thus remaining visible
for FIB-SEM after resin embedding during sample processing. Using this approach
we demonstrate its applicability for tracking the area of interest, imaging the
3D structural organization of nano-sized morphological features on liver
sinusoidal endothelial cells such as fenestrations, and correlating specific
endo-lysosomal compartments with its cargo protein upon endocytosis. We
envisage that photonic chip equipped with landmarks can be used in the future
to automatize the work-flow for both LM and EM for high-throughput CLEM,
providing the resolution needed for insights into the complex intracellular
communication and the relation between morphology and function in health and
disease.Comment: 23 Pages, 11 Figure
Label-free imaging on waveguide platform with enhanced resolution and contrast
Chip-based Evanescent Light Scattering (cELS) utilizes the multiple modes of a high-index contrast optical waveguide for near-field illumination of unlabeled samples, thereby repositioning the highest spatial frequencies of the sample into the far-field. The multiple modes scattering off the sample with different phase differences is engineered to have random spatial distributions within the integration time of the camera, mitigating the coherent speckle noise. This enables label-free superior-contrast imaging of weakly scattering nanosized specimens such as extra-cellular vesicles (EVs) and liposomes, dynamics of living HeLa cells etc. We demonstrate a multi-moded straight waveguide as a partially coherent light source. For isotropic super-resolution, spatially incoherent light engineered via multiple-arms waveguide chip and intensity-fluctuation based algorithms are used. The proof-of-concept results are demonstrated on 100 nm polystyrene beads and resolution improvement of close to 2× is shown. cELS also realizes (2-10)× more contrast as opposed to conventional imaging techniques
Fluorescence fluctuation-based super-resolution microscopy using multimodal waveguided illumination
Photonic chip-based total internal reflection fluorescence microscopy (c-TIRFM) is an emerging technology enabling a large TIRF excitation area decoupled from the detection objective. Additionally, due to the inherent multimodal nature of wide waveguides, it is a convenient platform for introducing temporal fluctuations in the illumination pattern. The fluorescence fluctuation-based nanoscopy technique multiple signal classification algorithm (MUSICAL) does not assume stochastic independence of the emitter emission and can therefore exploit fluctuations arising from other sources, as such multimodal illumination patterns. In this work, we demonstrate and verify the utilization of fluctuations in the illumination for super-resolution imaging using MUSICAL on actin in salmon keratocytes. The resolution improvement was measured to be 2.2–3.6-fold compared to the corresponding conventional images
Trapping of Nanoparticles with Optical Waveguides
Over the last few years, the notion that links optical trapping with strong intensity of light (high energy photon) not only forced the modification of optical tweezer, but it also open up the door for evanescent wave field trapping. While optical tweezer is merely suitable for trapping micro-sized particles, trapping by evanescent field of a channel waveguide enables both micro and nanosized particles to be trapped and propel as well. Indeed, nowadays, various structures of channel wave guides are designed to secure higher intensity of light for significantly better trapping purposes. The goal of this study is mainly to examine and better understand features related to trapping of particles on three different structures of a waveguides: straight, loop and ring resonators. We also propose new method to characterize the ring resonator waveguide. Though there are limitations to this method, it is possible to measure power in and out of the ring. Besides, the characteristics result shows too much power loss. From the straight waveguide experiment we confirm that gold particles of diameter 200nm and 500nm are trapped and propelled above the waveguide by the evanescent field. The speed obtained from the 200nm diameter analysis reaches up to 420µm/s for 700mW laser power, which considerably faster than the previously reported values. Given the advantages of the applications of loop waveguides, to stop particles by standing waves or counter propagating beams, we are able to clearly observe this phenomenon in our experiment for 1.02µm diameter polyester particles, in contrast to gold nanoparticles due to weak gradient forces. Maintaining similar analysis for ring resonator waveguides, however, the lacking of particle trapping or propulsion is observed for gallium arsenide nanowires, due to their asymmetric structure besides the low power. Weak gradient force and low power in the gold, and low power though strong gradient force in polystyrene ring waveguides are responsible for lack of trapping and propulsion in the nanoparticles. Even though the priority is of this thesis is the experimental essence, the theories of optical waveguides and optical trapping forces are briefly reviewed
Photonic-chip based free space beam shaping and steering for advanced optical microscopy application
Photonic-chip-based light illumination has recently found applications in optical microscopy and nanoscopy methodologies. The photonic chip removes the dependency on imaging objective lenses to generate the required illumination patterns for different microscopy methods. Until now, all the reported chip-based optical microscopy methods exploit the evanescent field present on top of a waveguide surface and are thus inherently limited to two-dimensional microscopy. Here, we perform systematic simulation studies to investigate different chip-based waveguide designs for static and dynamic shaping of light beams in the free-space. The simulation studies have been carefully designed considering the photo-lithography limitations and wavelength spectrum (405 nm to 660 nm) that is of interest in fluorescence based optical microscopy and nanoscopy. We first report the generation of a quasi-Bessel beam (QBB) using an on-chip axicon made at the end facet of a planar waveguide to mimic light sheet illumination. This is extended to the implementation of a counter propagating QBB for lattice light-sheet applications. The double axicon, a derivative of the axicon generates superimposed Bessel beams (SBB). Its waveguide-based implementation is proposed and analyzed. Finally, we investigate an optical phased array (OPA) approach to allow dynamic steering of the output light in the free-space. The aim of this study is to find suitable waveguide design parameters for free-space beam shaping operating in the visible spectrum opening possibilities for three-dimensional chip-based optical microscopy
Single-Mode Limit and Bending Losses for Shallow Rib <inline-formula> <tex-math notation="TeX">\hbox{Si}_{3}\hbox{N}_{4}}</tex-math></inline-formula> Waveguides
The single-mode limit and bending losses for shallow rib waveguides are studied
using the full vectorial film mode matching method. The maximum rib height for
single-mode waveguides is found to be on the order of 10 nm for a rib width of 2 m and
a wavelength of 785 nm, with the exact value depending on the core thickness and the
polarization. Bending losses are calculated as a function of several geometrical parameters,
for both polarizations and for the fundamental and the first order modes. Bending
losses decrease significantly with rib height for single-mode waveguides. For slightly
larger rib heights, giving multimode waveguides, it is found that the bending losses for
the first-order mode are several orders of magnitude larger than for the fundamental
mode. Thus, a small bend can act as an excellent mode filter, making it possible to use
higher ribs giving low bending losses for the fundamental mode, while maintaining the
waveguide practically single-mode. For TM-polarization, leakage loss can be important
and can cause bending losses to increase for larger rib heights (8–80 nm)