Ciencias Exactas y Ciencias de la Salud

Permanent URI for this collectionhttps://hdl.handle.net/11285/551039

Pertenecen a esta colección Tesis y Trabajos de grado de las Maestrías correspondientes a las Escuelas de Ingeniería y Ciencias así como a Medicina y Ciencias de la Salud.

Browse

Filters

20211

Settings

¡Quiero depositar mi trabajo!
Author: search.filters.author.Rosero Arias, CristianHas files: Yes

Search Results

Now showing 1 - 1 of 1
  • Thumbnail Image
    Tesis de maestría
    Numerical design of a silicon nitride nanobeam cavity for biochemical sensing
    (Instituto Tecnológico y de Estudios Superiores de Monterrey, 2021-12-08) Rosero Arias, Cristian; De León Arizpe, Israel; puemcuervo/tolmquevedo; Castañón Ávila, Gerardo Antonio; López Aguayo, Servando; School of Engineering and Sciences; Campus Monterrey
    The field of integrated photonics has experienced rapid growth in the past few decades. Sensors based on photonic crystal (PhC) nanobeam cavities are of great interest due to their size , sensing capabilities, and possible applications such as biochemical sensing. Silicon Nitride (SiN) platforms are competitive option against its counterpart Silicon due to the cost of material, no loss due to Two-Photon Absorption (TPA) or Free Carrier Absorption (FCA), and wide transparency window in both visible and near-infrared regions of the spectrum. Nevertheless, SiN presents low refractive index contrasts, which makes it challenging to achieve optical field confinement inside the cavity. Previous work have proven that slow light waveguides can compensate the low refractive index (RI) contrast in order to obtain high $\mathcal{Q}$ cavities. This thesis presents a design of a slow light PhC nanobeam cavitiy based on SiN working at near-infrared range. A numerical analysis was performed using a high-Q deterministic design. The proposed nanobeam cavity consists of a slow-light PhC waveguide bounded by two Bragg mirrors. For biochemical sensing purposes, the cavity is designed such that the optical mode supported has most of the field in the medium around it, thereby increasing the light-matter interaction between the cavity mode and the analyte. The sensing performance of the structure was studied by RI sensing analysis. The cavity designs presents a Q factor up to $\sim1.2\times10^{4}$ at a wavelength $\sim$ 900 nm. The bulk sensitivity and FOM were found at 215 nm/RIU and 2843, respectively.
En caso de no especificar algo distinto, estos materiales son compartidos bajo los siguientes términos: Atribución-No comercial-No derivadas CC BY-NC-ND http://www.creativecommons.mx/#licencias
logo

El usuario tiene la obligación de utilizar los servicios y contenidos proporcionados por la Universidad, en particular, los impresos y recursos electrónicos, de conformidad con la legislación vigente y los principios de buena fe y en general usos aceptados, sin contravenir con su realización el orden público, especialmente, en el caso en que, para el adecuado desempeño de su actividad, necesita reproducir, distribuir, comunicar y/o poner a disposición, fragmentos de obras impresas o susceptibles de estar en formato analógico o digital, ya sea en soporte papel o electrónico. Ley 23/2006, de 7 de julio, por la que se modifica el texto revisado de la Ley de Propiedad Intelectual, aprobado

DSpace software copyright © 2002-2025

Licencia