Identification of water content in nanocavities
Entidad
UAM. Departamento de Física de MaterialesEditor
Springer New YorkFecha de edición
2013-04-15Cita
Nanoscale Research Letters 8 (2013): 171ISSN
1931-7573 (print); 1556-276X (online)DOI
10.1186/1556-276X-8-171Financiado por
This work has been funded through projects FIS2009-13403-C02-01 (MINECO), S2009-MAT-1467 (CAM), and CSD2010-00024 (MINECO)Proyecto
Comunidad de Madrid. S2009/MAT-1467/NANOOBJETOSVersión del editor
http://dx.doi.org/10.1186/1556-276X-8-171Materias
SNOM; Viral capsid; Water; FDTD; Lattice gas; FísicaDerechos
© 2013 Douas et al.Resumen
A tapered dielectric waveguide that scans, at constant height, a sample containing a viral capsid is studied by combining a lattice gas model to simulate water meniscus formation and a finite difference time domain algorithm for light propagation through the media involved. Our results show different contrasts related to different water contents and different meniscus orientations. We propose this method as a way to study water content and evaporation process in nanocavities being either biological, like viral capsides, or nonbiological, like photonic crystals
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Google™ Scholar:Douas, Maysoun
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Marqués Ponce, Manuel Ignacio
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Serena, Pedro A .
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