4,891 research outputs found
Scatterer induced mode splitting in poly(dimethylsiloxane) coated microresonators
We investigate scatterer induced mode splitting in a composite microtoroidal
resonator (Q ~ 10^6) fabricated by coating a silica microtoroid (Q ~ 10^7) with
a thin poly(dimethylsiloxane) layer. We show that the two split modes in both
coated and uncoated silica microtoroids respond in the same way to the changes
in the environmental temperature. This provides a self-referencing scheme which
is robust to temperature perturbations. Together with the versatile
functionalities of polymer materials, mode splitting in polymer and polymer
coated microresonators offers an attractive sensing platform that is robust to
thermal noise.Comment: 9 pages, 3 figures, 15 reference
Estimation of Purcell factor from mode-splitting spectra in an optical microcavity
We investigate scattering process in an ultra-high-Q optical microcavity
coupled to subwavelength scatterers by introducing "splitting quality" Qsp, a
dimensionless parameter defined as the ratio of the scatterer-induced mode
splitting to the total loss of the coupled system. A simple relation is
introduced to directly estimate the Purcell factor from single-shot measurement
of transmission spectrum of scatterer-coupled cavity. Experiments with
polystyrene (PS) and gold (Au) nanoparticles, Erbium ions and Influenza A
virions show that Purcell-factor-enhanced preferential funneling of scattering
into the cavity mode takes place regardless of the scatterer type.
Experimentally determined highest Qsp for single PS and Au nanoparticles are
9.4 and 16.19 corresponding to Purcell factors with lower bounds of 353 and
1049, respectively. The highest observed Qsp was 31.2 for an ensemble of Au
particles. These values are the highest Qsp and Purcell factors reported up to
date.Comment: 5 Pages, 4 Figures, 12 Reference
Controlled Manipulation of Mode Splitting in an Optical Microcavity by Two Rayleigh Scatterers
We report controlled manipulation of mode splitting in an optical
microresonator coupled to two nanoprobes. It is demonstrated that, by
controlling the positions of the nanoprobes, the split modes can be tuned
simultaneously or individually and experience crossing or anti-crossing in
frequency and linewidth. A tunable transition between standing wave mode and
travelling wave mode is also observed. Underlying physics is discussed by
developing a two-scatterer model which can be extended to multiple scatterers.
Observed rich dynamics and tunability of split modes in a single microresonator
will find immediate applications in optical sensing, opto-mechanics, filters
and will provide a platform to study strong light-matter interactions in
two-mode cavities.Comment: 9 pages, 5 figures, 14 references. Major revision. Published version
in Optics Expres
Demonstration of mode splitting in an optical microcavity in aqueous environment
Scatterer induced modal coupling and the consequent mode splitting in a
whispering gallery mode resonator is demonstrated in aqueous environment. The
rate of change in splitting as particles enter the resonator mode volume
strongly depends on the concentration of particle solution: The higher is the
concentration, the higher is the rate of change. Polystyrene nanoparticles of
radius 50nm with concentration as low as 5x10^(-6)wt% have been detected using
the mode splitting spectra. Observation of mode splitting in water paves the
way for constructing advanced resonator based sensors for measuring
nanoparticles and biomolecules in various environments.Comment: 8 pages, 4 figures, 21 Reference
Outer membrane vesicles of Porphyromonas gingivalis: Novel communication tool and strategy
Extracellular vesicles (EVs) have been recognized as a universal method of cellular communications and are reportedly produced in bacteria, archaea, and eukaryotes. Bacterial EVs are often called "Outer Membrane Vesicles" (OMVs) as they were the result of a controlled blebbing of the outer membrane of gram-negative bacteria such as Porphyromonas gingivalis (P. gingivalis). Bacterial EVs are natural messengers, implicated in intra-and inter-species cell-to-cell communication among microorganism populations present in microbiota. Bacteria can incorporate their pathogens into OMVs; the content of OMVs differs, depending on the type of bacteria. The production of distinct types of OMVs can be mediated by different factors and routes. A recent study highlighted OMVs ability to carry crucial molecules implicated in immune modulation, and, nowadays, they are considered as a way to communicate and transfer messages from the bacteria to the host and vice versa. This review article focuses on the current understanding of OMVs produced from major oral bacteria, P. gingivalis: generation, characteristics, and contents as well as the involvement in signal transduction of host cells and systemic diseases. Our recent study regarding the action of P. gingivalis OMVs in the living body is also summarized
Outer membrane vesicles of Porphyromonas gingivalis : Novel communication tool and strategy
Extracellular vesicles (EVs) have been recognized as a universal method of cellular communications and are reportedly produced in bacteria, archaea, and eukaryotes. Bacterial EVs are often called “Outer Membrane Vesicles” (OMVs) as they were the result of a controlled blebbing of the outer membrane of gram-negative bacteria such as Porphyromonas gingivalis (P. gingivalis). Bacterial EVs are natural messengers, implicated in intra- and inter-species cell-to-cell communication among microorganism populations present in microbiota. Bacteria can incorporate their pathogens into OMVs; the content of OMVs differs, depending on the type of bacteria. The production of distinct types of OMVs can be mediated by different factors and routes. A recent study highlighted OMVs ability to carry crucial molecules implicated in immune modulation, and, nowadays, they are considered as a way to communicate and transfer messages from the bacteria to the host and vice versa. This review article focuses on the current understanding of OMVs produced from major oral bacteria, P. gingivalis: generation, characteristics, and contents as well as the involvement in signal transduction of host cells and systemic diseases. Our recent study regarding the action of P. gingivalis OMVs in the living body is also summarized
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