The meniscus formation along with the geometry of the nanocavity

The meniscus formation along with the geometry of the nanocavity allows capillary force to modify the mechanical stability towards PI3K inhibitor collapse [5]. An important issue that arises from these AFM studies on biological samples is whether the condensation of water in these viral nanocavities may be detected by a direct measurement. The previously mentioned changes on the near field optics, during the desiccation stages, may be

a good tool for showing how this process takes place. Indeed, SNOM characterizes sample composition by the changes in the optical near field and, since the viral capsides are almost transparent at optical wavelengths [6], different water contents in these nanocavities will produce different output signals which are distinct enough to characterize and monitor the desiccation sequence by SNOM experiments. The aim of this paper is to understand, using an adequate combination of numerical techniques, how water evaporation or condensation in a nanocontainer (viral capsid) might be detected by near-field optic measurements. To do so, we consider a tapered dielectric waveguide that scans, at constant height, a sample formed by a viral capsid with different

water contents. The manuscript is organized as follows: next section describes the system under study and the set of numerical methods we have used; finally, the two sections LY333531 mouse devoted to results and conclusions will describe PD-1/PD-L1 Inhibitor 3 cell line the changes of the optical signal

due to the presence of a water meniscus and the possible use of these changes to monitor real-time evolution of water meniscus in nanocontainers. Methods Tip-sample system In order to describe the tip-sample system we have considered a tapered optical fiber probe, with a final aperture of 100 nm, coated with a perfect metal. This tip is placed at a constant distance, h=50 nm, from a flat dielectric substrate with a refractive index n=2.0 and 10 nm thicknesses. This geometry is very similar to that previously described by Wang et al[7]. Upon the substrate we have placed a simple geometry nanocontainer that simulates a viral capsid with a single porous, similar to the previously Methane monooxygenase studied ϕ29 viral particles [4]. The considered shape of our nanocontainer is a 30-nm lateral size square with a porous of 5 nm centered at one side. The nanocontainer is almost transparent (n=1.06) and hydrophilic. The capsid might be filled up with double-stranded DNA (dsDNA) (refractive index n=1.55 at the considered wavelength) [8] or with different contents of water (n=1.33) that will depend on the relative humidity. Simulation methods The water meniscus formation inside the container is studied using a 2D lattice gas model that has been extensively used to study water properties, including gas-liquid transition and density anomalies.

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