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dc.contributor.author de Hoyos Martínez, Jesús Enrique
dc.contributor.author JORGE CID, JOSE MANUEL
dc.contributor.author Singh, Mahi
dc.contributor.author Guo, Jiaohan
dc.creator de Hoyos Martínez, Jesús Enrique; 234300
dc.creator JORGE CID, JOSE MANUEL; 700250
dc.creator Singh, Mahi;#0000-0002-2792-3054
dc.creator Guo, Jiaohan;#0000-0001-9822-1896
dc.date.accessioned 2018-02-07T17:54:23Z
dc.date.available 2018-02-07T17:54:23Z
dc.date.issued 2017-03
dc.identifier.issn 121-094303
dc.identifier.uri http://hdl.handle.net/20.500.11799/68431
dc.description.abstract We study the light emission from a quantum emitter and double metallic nanoshell hybrid systems. Quantum emitters act as local sources which transmit their light efficiently due to a double nanoshell near field. The double nanoshell consists of a dielectric core and two outer nanoshells. The first nanoshell is made of a metal, and the second spacer nanoshell is made of a dielectric material or human serum albumin. We have calculated the fluorescence emission for a quantum emitter-double nanoshell hybrid when it is injected in an animal or a human body. Surface plasmon polariton resonances in the double nanoshell are calculated using Maxwell's equations in the quasi-static approximation, and the fluorescence emission is evaluated using the density matrix method in the presence of dipole-dipole interactions. We have compared our theory with two fluorescence experiments in hybrid systems in which the quantum emitter is Indocyanine Green or infrared fluorescent molecules. The outer spacer nanoshell of double metallic nanoshells consists of silica and human serum albumin with variable thicknesses. Our theory explains the enhancement of fluorescence spectra in both experiments. We find that the thickness of the spacer nanoshell layer increases the enhancement when the fluorescence decreases. The enhancement of the fluorescence depends on the type of quantum emitter, spacer layer, and double nanoshell. We also found that the peak of the fluorescence spectrum can be shifted by changing the shape and the size of the nanoshell. The fluorescence spectra can be switched from one peak to two peaks by removing the degeneracy of excitonic states in the quantum emitter. Hence, using these properties, one can use these hybrids as sensing and switching devices for applications in medicine. es
dc.language.iso eng es
dc.publisher Journal of Applied Physics es
dc.rights openAccess es
dc.rights.uri http://creativecommons.org/licenses/by-nc-nd/4.0
dc.subject Nonosilica es
dc.subject Análisis Médico es
dc.subject.classification BIOLOGÍA Y QUÍMICA
dc.title Control of fluorescence in quantum emitter and metallic nanoshell hybrids for medical applications es
dc.type Artículo es
dc.provenance Científica es
dc.road Dorada es
dc.organismo Arquitectura y Diseño es
dc.ambito Internacional es
dc.cve.CenCos 20601 es
dc.audience students es
dc.audience researchers es
dc.type.conacyt article
dc.identificator 2


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  • Título
  • Control of fluorescence in quantum emitter and metallic nanoshell hybrids for medical applications
  • Autor
  • de Hoyos Martínez, Jesús Enrique
  • JORGE CID, JOSE MANUEL
  • Singh, Mahi
  • Guo, Jiaohan
  • Fecha de publicación
  • 2017-03
  • Editor
  • Journal of Applied Physics
  • Tipo de documento
  • Artículo
  • Palabras clave
  • Nonosilica
  • Análisis Médico
  • Los documentos depositados en el Repositorio Institucional de la Universidad Autónoma del Estado de México se encuentran a disposición en Acceso Abierto bajo la licencia Creative Commons: Atribución-NoComercial-SinDerivar 4.0 Internacional (CC BY-NC-ND 4.0)

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