Strong light emission from a defective hexagonal boron nitride monolayer coupled to near-touching random plasmonic nanounits.

In this Letter, we demonstrate strong light emission from defective hexagonal boron nitride (hBN) defect centers upon their coupling with disorder near-touching plasmonic units. Based on numerical simulations and characterization results, the plasmonic design at thin layer thicknesses of 20 nm can provide above 2 orders of magnitude enhancement in photoluminescence (PL) spectra. Moreover, this plasmonic platform shortens the luminescence lifetime of the emitters. The proposed design can be easily extended to other plasmonic-emitter combinations where strong light-matter interaction can be achieved using large-scale compatible routes.

Numerical analysis of a thermally tunable spectrally selective absorber enabled by an all-dielectric metamirror.

In this Letter, we numerically propose a temperature-tunable, ultra-narrowband one-way perfect near-infrared radiation absorber with high transmission in the longer wavelength neighboring spectral range. We obtained this functionality by using a guided-mode resonance-based grating-waveguide metamirror that is comprised of silicon, a spacer dielectric, an absorbing semiconductor, and germanium. Within the ultra-narrow bandwidth of the guided-mode resonance excited at 1.16 µm with a full width at half-maximum of 3.3 nm, we confirmed perfect absorption when light is incident from one of the two opposite directions. Excitation from the opposite direction resulted in perfect reflection. The thickness of the entire structure is limited to about one third the operating wavelength. Furthermore, due to the temperature tunability of silicon and germanium the thermo-optical sensitivity was found to be approximately 0.068 nm/K. In addition to this spectral tunability, our proposed device supports transparency windows with 80% transmission in the higher wavelength ranges. Our device is highly promising in the applications of thermo-tunable modulators and obtaining single frequency near-infrared signals from broadband sources.

One-way and near-absolute polarization insensitive near-perfect absorption by using an all-dielectric metasurface.

In this Letter, we numerically propose the one-way perfect absorption of near-infrared radiation in a tunable spectral range with high transmission in the neighboring spectral ranges. This functionality is obtained by using a two-dimensional, guided-mode resonance-based grating-waveguide metasurface that acts as a frequency-selective reflector, a spacer dielectric, and an absorbing oxide layer. Within the bandwidth of the excited guided-mode resonance excited at 1.82 µm (with a full-width at half-maximum of 19 nm), we confirmed perfect absorption when light was incident from one of the two opposite directions, whereas in the other direction, perfect reflection was observed. The forward-to-backward absorption ratio reached as high as 60, while the thickness of the entire structure was on the order of the operating wavelength. In addition to the spectral tunability of the excited resonances and their bandwidths, our proposed device supports transparency windows with 65% transmission in the adjacent frequency bands. Our 2D grating is also verified to enable near-absolute insensitivity to the polarization state of incident light. Geometrical parameter modification also gives our design great tunability, as we also designed a device with a 300 nm absorption/reflection linewidth.

[Investigation of toxin genes of Clostridium difficile strains isolated from hospitalized patients with diarrhoea at Marmara University Hospital]. / Marmara Üniversitesi Hastanesinde Yatan Ishalli Hastalardan Izole Edilen Clostridium difficile Kökenlerinde Toksin Genlerinin Arastirilmasi

Toxigenic Clostridium difficile strains cause a spectrum of antibiotic-associated diseases ranging from self-limited diarrhea to severe life-threatening colitis. Pathogenesis primarily involves the action of two important cytotoxins, namely toxin A and toxin B. However, epidemics of C.difficile-associated disease due to the novel, highly virulent strains of C.difficile (binary toxin positive and toxin A variant) have been recognised in hospitals of some countries. The aim of this study was to investigate the toxin gene profiles of C.difficile strains isolated from hospitalized patients with diarrhea. The stool specimens collected from 633 inpatients at Marmara University Hospital, Istanbul, Turkey, between September 2006-March 2008, were included to the study. The presence of C.difficile toxins in the samples has been screened by a commercial enzyme immunoassay kit (ImmunoCard Toxins A&B EIA; Meridian Diagnostics, Belgium). Stool samples were also cultivated on cycloserin-cefoxitin-fructose agar (CCFA; BioMerieux, France) at anaerobic conditions, and the isolates were identified by conventional methods and Rapid ID 32A (BioMerieux, France) system. Toxin production of C.difficile strains isolated from stool cultures have been detected by commercially available "Triage C.difficile Panel" (Biosite Diagnostics, Italy) and "ImmunoCard Toxins A&B EIA" (Meridian Diagnostics, Belgium) kits. In-house polymerase chain reaction (PCR) was performed to investigate the presence of genes for toxin A (tcdA), toxin B (tcdB) and binary toxin (cdtA and cdtB). Stool specimens from 50 (7.9%) patients (age range: 2-> 65 years; mean age: 35.9 ± 27.6 years; 26 were male) yielded C.difficile in culture. All of 50 isolates were found positive for glutamate dehydrogenase enzyme and 28 (56%) were found positive for toxin A with "Triage C.difficile Panel" kit. Toxin positivity rate was detected as 4.7% (30/633) with EIA test performed in stool samples directly, however this rate was 5.7% (36/633) in culture filtrates of the isolates (n= 50), with the same test. Since EIA test yielded false negative results in six samples, the sensitivity of this test was estimated as 85.7% by means of the detection of toxin in direct stool samples. All of the 36 toxin-producing C.difficile isolates were found positive for toxin A and toxin B genes (tcdA+/tcdB+), however there were neither variant strains (tcdA-/tcdB+) nor binary toxin gene positive isolates among tested bacteria. Our results have also indicated that 77.8% (28/36) of patients who harbored toxigenic C.difficile strains have the history of beta-lactam antibiotic (penicillin, cephalosporin and imipenem) use. It was thought that the data of this study would constitute a database on the toxin gene profiles of C.difficile in hospitalized patients with diarrhea both in our hospital and Turkey. The current data have indicated that for the time being there were no risk for isolates producing new toxin variants or binary toxin, however, continuous monitorization of such C.difficile strains is of crucial importance in order to detect the emergence of those strains and establish necessary control and preventive measures.

Seminested PCR for detection and identification of Candida species directly from blood culture bottles.

We investigated the performance of a seminested PCR (snPCR) assay carried out directly from overnight incubated blood culture bottles of 50 newborn intensive care unit (NICU) patients with suspected candidemia and compared these, for sensitivity, specificity and reliability with results from blood cultures. All positive blood cultures (n = 17) yielded positive results for snPCR, which detected the same Candida species, as did the yeast isolates of which 13 were C. parapsilosis and 4 were C. albicans. With both assays showing 32 negative samples and one sample positive with snPCR but negative with blood culture, sensitivity and specificity of snPCR were 100% and 97%, respectively. The patient with contradictory results exhibited a positive blood culture one week later yielding the same species as identified by snPCR. These are the first data demonstrating that snPCR from overnight blood culture bottles can be a potential tool for rapid detection and identification of Candida species, allowing follow-up of the "gold standard" blood culturing, as well.

Unveiling the optical parameters of vanadium dioxide in the phase transition region: a hybrid modeling approach.

The phase change behavior of vanadium dioxide (VO2) has been widely explored in a variety of optical and photonic applications. Commonly, its optical parameters have been studied in two extreme regimes: hot (metallic) and cold (insulating) states. However, in the transition temperatures, VO2 acts like an inherent metamaterial with mixed metallic-insulating character. In this range, the portions of metallic and insulating inclusions are tuned by temperature, and therefore a gradual change of optical parameters can be achieved. In this paper, a universal hybrid modeling approach is developed to model VO2 in the intermediate region. For this aim, the measured reflectivity data, is analyzed and matched through the transfer matrix method (TMM) simulations where an effective medium theory (EMT) is employed. Based on the findings of this approach, not only the relative portions of inclusions are tailored but also their grain shapes are significantly altered in the transition range. Finally, the modeling approach is testified by experimental findings through dynamic device applications operating at short and mid infrared wavelengths. In addition, the hysteretic behaviors on electrical, optical, and structural parameters of the VO2 film along the heating and cooling cycles are demonstrated by the experiments and scrutinized by the simulations.

Near-absolute polarization insensitivity in grapheme based ultra-narrowband perfect visible light absorber.

Strong light-graphene interaction is essential for the integration of graphene to nanophotonic and optoelectronic devices. The plasmonic response of graphene in terahertz and mid-infrared regions enhances this interaction, and other resonance mechanisms can be adopted in near-infrared and visible ranges to achieve perfect light absorption. However, obtaining near-absolute polarization insensitivity with ultra-narrow absorption bandwidth in the visible and near-infrared regimes remains a challenge. In this regard, we numerically propose a graphene perfect absorber, utilizing the excitation of guided-modes of a dielectric slab waveguide by a novel sub-wavelength dielectric grating structure. When the guided-mode resonance is critically coupled to the graphene, we obtain perfect absorption with an ultra-narrow bandwidth (full-width at half-maximum) of 0.8 nm. The proposed design not only preserves the spectral position of the resonance, but also maintains >98% absorption at all polarization angles. The spectral position of the resonance can be tuned as much as 400 nm in visible and near-infrared regimes by tailoring geometrical parameters. The proposed device has great potential in efficient, tunable, ultra-sensitive, compact and easy-to-fabricate advanced photodetectors and color filters.

Publisher Correction: Near-absolute polarization insensitivity in graphene based ultra-narrowband perfect visible light absorber.

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