Coupled waveguide model for computing phase and transmission through nanopillar-based metasurfaces.

Dielectric metasurfaces are important in modern photonics due to their unique beam shaping capabilities. However, the standard tools for the computation of the phase and transmission through a nanopillar-based metasurface are either simple, approximating the properties of the surface by that of a single cylinder, or use full 3D numerical simulations. Here we introduce a new analytical model for computing metasurface properties which explicitly takes into account the effect of the lattice geometry. As an example we investigate silicon nanopillar-based metasurfaces, examining how the transmission properties depend on the presence of different modes in the unit cell of the metasurface array. We find that the new model outperforms the isolated cylinder model in predicting the phase, and gives excellent agreement with full numerical simulations when the fill fraction is moderate. Our model offers a waveguide perspective for comprehending metasurface properties, linking it to fiber optics and serving as a practical tool for future metasurface design.

[Interdisciplinary Cooperation as a Characteristic of Successful Rehabilitation Facilities--Results from the Project MeeR]. / Interdisziplinäre Zusammenarbeit als ein Merkmal erfolgreicher Rehabilitationseinrichtungen - Ergebnisse aus dem MeeR-Projekt.

OBJECTIVE: To determine if there is a difference between successful and less successful rehabilitation facilities concerning their extent and quality of interdisciplinary cooperation? METHODS: This analysis is part of the project MeeR, that aims to identify characteristics of rehabilitation facilities related to successful rehabilitation. 6 facilities were recruited based on a quantitative analysis; 3 facilities that ranked as above average and 3 as below average in terms of their success in rehabilitating patients. Comprehensive qualitative data were collected on these 6 facilities. RESULTS: In above average rehabilitation facilities, the extent of interdisciplinary cooperation was higher than in below average facilities; the position of the medical profession was less dominant and there was a wider access to team meetings. DISCUSSION: Promotion of interdisciplinary cooperation is an important component for the improvement of the success of rehabilitation facilities.

The effect of silver thickness on the enhancement of polymer based SERS substrates.

We investigated silver-covered polymer based nanogratings as substrates for surface-enhanced Raman spectroscopy (SERS), in particular with respect to the thickness of the plasmonically active silver film. In order to obtain accurate geometrical input data for the simulation process, we inspected cross sections of the gratings prepared by breaking at cryogenic temperature. We noticed a strong dependence of the simulation results on geometrical variations of the structures. Measurements revealed that an increasing silver film thickness on top of the nanogratings leads to a blue shift of the plasmonic resonance, as predicted by numerical simulations, as well as to an increased field enhancement for an excitation at 488 nm. We found a clear deviation of the experimental data compared to the simulated results for very thin silver films due to an island-like growth at a silver thickness below 20 nm. In order to investigate the SERS activity. we carried out measurements with crystal violet as a model analyte at an excitation wavelength of 488 nm. The SERS enhancement increases up to a silver thickness of about 30 nm, whereas it remains nearly constant for thicker silver films.

Magnetization reversal in magnetic nanostripes via Bloch wall formation.

We present results of micromagnetic simulations of the magnetization reversal in permalloy nanostripes with 5-10 nm thickness and 200-500 nm width under a longitudinal field of 0.4-16 kA m(-1). The data show four distinct field regions: the well-known regions of uniform and oscillating domain wall movement as well as a process with multiple vortices, and finally a new process including Bloch walls and the generation of vortex-antivortex pairs in the inner part of the stripe rather than at the edges. We investigate this process in detail and derive a criterion for the formation of Bloch walls.

[Magnetically based enhancement of nanoparticle uptake in tumor cells: combination of magnetically induced cell labeling and magnetic heating]. / Magnetisch basierte Steigerung der Nanopartikelaufnahme in Tumorzellen: Kombination von magnetisch induzierter Zellmarkierung und magnetischer Wärmebehandlung.

PURPOSE: Magnetic nanoparticles (MNP) are known to be versatile tools in diagnostic and interventional radiology. The goal of the present study was to assess whether MNP can be selectively accumulated on human adenocarcinoma cells in vitro using an external magnetic field (magnetically induced cell labeling) and whether these labeled tumor cells can then be destroyed after being exposed to an alternating magnetic field (magnetically induced heating). In this context, a long-term goal is to combine these two developing methods to achieve an additive effect in tumor therapy. MATERIALS AND METHODS: BT-474 cells were incubated until confluence. Magnetic nanoparticles (0.32 mg Fe/ml culture medium) were then added and the flask was exposed to an external magnetic field gradient (magnetically induced cell labeling, 56 or 83 mT magnets) for 24 hours in order to label the tumor cells with nanoparticles. Cells without both MNP and magnetic labeling as well as cells with MNP incubation but without magnetic labeling served as controls. After MNP incubation, the magnetically labeled cells (5 x 10 (7) cells/ml) were exposed to an alternating magnetic field for 5.45 minutes (frequency 400 kHz, amplitude 24.6 kA/m). The combination effect of both magnetic labeling and magnetic heating was assessed by determining the temperature increase. The amount of MNP accumulated within the cells was determined by measuring the iron content via atomic absorption spectrometry. For statistical analysis mean values and standard deviations of temperature increases and iron contents were calculated and the differences were analyzed using the Student's t-test. RESULTS: A significant temperature increase (p < 0.01) during magnetic heating of 41.76 +/- 4.60 K was detected after magnetic labeling of the cells (5 x 10 (7) cells/ml, 83 mT) incubated with MNP. In comparison, the cells incubated with MNP but without magnetic labeling revealed a temperature increase of 32.03 +/- 3.33 K, naked cells of only 2.69 +/- 0.34 K. CONCLUSION: The results demonstrated the magnetically based enhancement of cellular uptake of nanoparticles by tumor cells, resulting in the intensification of the generated temperature increase during magnetic heating. Consequently, magnetic nanoparticles are shown to be valuable tools for the combination of magnetically based therapy modalities.