Project description:Our understanding of the history of the solar system has undergone a revolution in recent years, owing to new theoretical insights into the origin of Pluto and the discovery of the Kuiper belt and its rich dynamical structure. The emerging picture of dramatic orbital migration of the planets driven by interaction with the primordial Kuiper belt is thought to have produced the final solar system architecture that we live in today. This paper gives a brief summary of this new view of our solar system's history and reviews the astronomical evidence in the resonant populations of the Kuiper belt.

Project description:Today, nanoparticles are used in various commercial products. One of the most common nanoparticles is titanium dioxide (TiO2). It has a catalytic activity and UV absorption (λ<400 nm), and it generates reactive oxygen species (ROS). The catalytic activity of TiO2 nanoparticle is capable of killing a wide range of microorganisms. In the environment, nanoparticles form structures consisting of primary particles, and their aggregates and agglomerates. These compounds are defined NOAA (nano-objects, and their aggregates and agglomerates greater than 100 nm). The unique properties of TiO2 nanoparticles can be maintained in the environment, thus, the growing use of TiO2 nanoparticles is raising concerns about the environmental risks. The assessment of biological and ecological effects of TiO2-NOAA is necessary. In our previous study, we assessed the effect of TiO2-NOAA on microbes by using Saccharomyces cerevisiae and Escherichia coli. It was shown that TiO2-NOAA decomposed methylene blue under UV irradiation. It suggested that TiO2-NOAA generated ROS under UV irradiation. However, TiO2-NOAA did not show growth inhibition in minimal agar medium under UV irradiation. By adding TiO2-NOAA in medium, colony formation was observed with UV intensity that inactivates microbes. Moreover, TiO2-NOAA adsorbed microbes. These results suggested that the amount of ROS generated by TiO2-NOAA was not enough to inactivate microbes, and TiO2-NOAA might protect microbes from UV. In this study, we assessed the effect of TiO2-NOAA in more detail by using S. cerevisiae. We used DNA microarray analysis for qualitative assessment. Further, we carried out quantitative assessment by using Real Time RT-PCR method for characteristic genes in DNA microarray analysis. To compare yeast cells in various conditions, six kinds of treatment conditions were prepared (Condition 1. adsorbed fraction to TiO2-NOAA under UV, 2. non-adsorbed fraction to TiO2-NOAA under UV, 3. adsorbed fraction to TiO2-NOAA without UV, 4. non-adsorbed fraction to TiO2-NOAA without UV, 5. irradiated UV and 6. negative control). From the result of DNA microarray analysis, the most number of genes was altered in Condition 1, followed by Condition 3 and 5. The genes related to oxidative stress, and the genes related to synthesis of trehalose and glycogen were significantly up-regulated of yeast cells in Condition 1 and 5, and Condition 1 and 3, respectively. These results suggest that yeast cells suffer oxidative stress by TiO2-NOAA under UV, and they also suffer membrane damage by TiO2-NOAA itself, as a result, they reserve energy sources. From the result of Real Time RT-PCR, genes related to oxidative stress (GRE2, SOD2) were up-regulated in Condition 1 and 3, however, these expression levels in each condition were not significant. And genes related to synthesis of trehalose and glycogen (GSY1, TPS2) were up-regulated in Condition 1 and 3. These results suggest that oxidative stress is caused not by TiO2-NOAA but by UV. It is also suggested that yeast cells were damaged at their membranes by TiO2-NOAA, as a result, genes related to synthesis of trehalose and glycogen were up-regulated. Thus, we suggest that the effect of TiO2-NOAA on yeast cells under UV irradiation is greater due to TiO2-NOAA itself than due to ROS generated by TiO2-NOAA.

Project description:This study presents the development of an in-situ background-free Raman fiber probe, employing two customized double-cladding anti-resonant hollow-core fibers (AR-HCFs). The Raman background noise measured in the AR-HCF probe is lower than that of a conventional multi-mode silica fiber by two orders of magnitude. A plug-in device for fiber coupling optics was designed that was compatible with a commercially available confocal Raman microscope, enabling in-situ Raman detection. The numerical aperture (NA) of both AR-HCF claddings exceeds 0.2 substantially enhancing the collection efficiency of Raman signals at the distal end of the fiber probe. The performance of our Raman fiber probe is demonstrated by characterizing samples of acrylonitrile-butadiene-styrene (ABS) plastics, alumina ceramics, and ethylene glycol solution.

Project description:Optical cavities transmit light only at discrete resonant frequencies, which are well-separated in micro-structures. Despite attempts at the construction of planar 'white-light cavities', the benefits accrued upon optically interacting with a cavity - such as resonant field buildup - have remained confined to narrow linewidths. Here, we demonstrate achromatic optical transmission through a planar Fabry-Pérot micro-cavity via angularly multiplexed phase-matching that exploits a bio-inspired grating configuration. By correlating each wavelength with an appropriate angle of incidence, a continuous spectrum resonates and the micro-cavity is rendered transparent. The locus of a single-order 0.7-nm-wide resonance is de-slanted in spectral-angular space to become a 60-nm-wide achromatic resonance spanning multiple cavity free-spectral-ranges. The result is an 'omni-resonant' planar micro-cavity in which light resonates continuously over a broad spectral span. This approach severs the link between the resonance bandwidth and the cavity-photon lifetime, thereby promising resonant enhancement of linear and nonlinear optical effects over broad bandwidths in ultrathin devices.

Project description:The scattering and absorption of light by nano-objects is a key physical property exploited in many applications, including biosensing and photovoltaics. Yet, its quantification at the single object level is challenging and often requires expensive and complicated techniques. We report a method based on a commercial transmission microscope to measure the optical scattering and absorption cross sections of individual nano-objects. The method applies to microspectroscopy and wide-field image analysis, offering fine spectral information and high throughput sample characterization. Accurate cross-section determination requires detailed modeling of the measurement, which we develop, accounting for the geometry of the illumination and detection as well as for the presence of a sample substrate. We demonstrate the method on three model systems (gold spheres, gold rods, and polystyrene spheres), which include metallic and dielectric particles, spherical and elongated, placed in a homogeneous medium or on a dielectric substrate. Furthermore, by comparing the measured cross sections with numerical simulations, we are able to determine structural parameters of the studied system, such as the particle diameter and aspect ratio. Our method therefore holds the potential to complement electron microscopy as a simpler and cost-effective tool for structural characterization of single nano-objects.

Project description:Metallic or dielectric nano-objects change the photon local density of states of closely placed emitters, particularly when plasmon or Mie resonances are present. Depending on the shape and material of these nano-objects, they may induce either a decrease or an increase in decay rates of the excited states of the emitter. In this work, we consider the reduction of the probability of optical transitions in emitters near high-refractive index dielectric (silicon and zinc selenide) nanoparticles. We tune the spectral positions of magnetic and electric modes of nanocylinders to obtain the largest overlap of the valleys in the total decay rate spectra for differently oriented dipoles and, in this way, find the highest inhibition of about 80% for randomly oriented emitters. The spectral positions of these valleys are easy to control since the wavelengths of the modes depend on the height and diameter of nanocylinders. The inhibition value is robust to the distance between the emitter and the nanoparticle in the range of nearly 50 nm, which is crucially important for the applications, such as selective optical transition engineering and photovoltaics.

Project description:Ultrashort single-walled carbon nanotubes, i.e. with length below ~30 nm, display length-dependent physical, chemical and biological properties that are attractive for the development of novel nanodevices and nanomaterials. Whether fundamental or applicative, such developments require that ultrashort nanotube lengths can be routinely and reliably characterized with high statistical data for high-quality sample production. However, no methods currently fulfill these requirements. Here, we demonstrate that photothermal microscopy achieves fast and reliable optical single nanotube analysis down to ~10 nm lengths. Compared to atomic force microscopy, this method provides ultrashort nanotubes length distribution with high statistics, and neither requires specific sample preparation nor tip-dependent image analysis.

Project description:Phase is an inherent and important feature for coherent processes, which, unfortunately, has not been completely understood for surface plasmon polariton (SPP) and matter interactions. Here we propose a practical approach to extract the phase change dispersion during the interaction between free-space light, SPPs and nanogroove/slit based on far-field information only. Numerical simulation and experimental validation were both presented using nanoslit-groove plasmonic interferometers, agreeing well with theoretical near-field analysis. This approach is generally feasible to extract the intrinsic phase dispersion of other plasmonic nanostructures and can reveal more fundamental features of SPP-matter interactions.

Project description:Achieving nanometer-scale resolution remains challenging in expansion microscopy due to photon loss. To address this concern, here we develop a multi-color expansion stimulated emission depletion technique based on small-molecule probes to realize high labeling density and intensity. Our method substantially lowers the barrier to visualizing diverse intracellular proteins and their interactions in three dimensions. It enables us to achieve sub-10-nm resolution in structures such as microfilaments, lysosomes, and mitochondria, providing new insights into cell biology.

Project description:Optical microsphere nanoscope has great potential in the inspection of integrated circuit chips for semiconductor industry and morphological characterization in biology due to its superior resolving power and label-free characteristics. However, its resolution in ambient air is restricted by the magnification and numerical aperture (NA) of microsphere. High magnification objective lens is required to be coupled with microsphere for nano-imaging beyond the diffraction limit. To overcome these challenges, in this work, high refractive index hyper-hemi-microspheres with tunable magnification up to 10× are proposed and realized by accurately tailoring their thickness with focused ion beam (FIB) milling. The effective refractive index is put forward to guide the design of hyper-hemi-microspheres. Experiments demonstrate that the imaging resolution and contrast of a hyper-hemi-microsphere with a higher magnification and larger NA excel those of a microsphere in air. Besides, the hyper-hemi-microsphere could resolve ~50 nm feature with higher image fidelity and contrast compared with liquid immersed high refractive index microspheres. With a hyper-hemi-microsphere composed microscale compound lens configuration, sub-50 nm optical imaging in ambient air is realized by only coupling with a 10× objective lens (NA = 0.3), which enhances a conventional microscope imaging power about an order of magnitude.