Development and Testing of a Second Generation Hand-held Optical Imager

Gonzalez, Jean

22 March 2012

Hand-held optical imagers are developed towards clinical breast cancer imaging. Herein, a Gen-2 hand-held optical imager has been developed with unique features: (i) image curved breast tissues with ~86% surface contact, and (ii) perform reflectance and transillumination imaging using the novel forked probe heads. Extensive phantom studies were performed using 1% Liposyn solution (background, ~ 300 ml and 1000 ml volumes) and 0.45 cc India Ink (absorption) targets, under different target:background contrast ratios and target depths. Two-dimensional surface images detected target(s) up to 2.5 cm deep via reflectance imaging, and up to 5 cm deep via transillumination imaging. Preliminary studies on gel-based breast phantoms (~700 ml) detected targets via reflectance and transillumination imaging. Preliminary in-vivo reflectance studies on normal and cancerous breast tissues also detected targets, although with artifacts. In future, the portable Gen-2 imager has potential for clinical breast imaging via reflectance and transillumination approach after extensive in-vivo studies.

Optical

imaging

breast

hand-held

bed-based

spectroscopic

spectroscopy

near-infrared imaging

NIR

imager

Development

testing of optical device

device

human subject

subject

human

preliminary invivo

invivo

in-vivo

phantom

extensive phantom

biomedical

optics

bioimaging

Photostructuration de matériaux nanocomposites à propriétés magnéto-optiques : vers la réalisation de composants pour l'optique intégrée / Photostructuration of nanocomposite materials with magneto-optical properties : towards realization of integrated devices in optical chips

Bidaud, Clémentine

14 November 2018

L’objectif principal de ce travail de thèse est de formuler un matériau nanocomposite doté de propriétés magnéto-optiques (MO) et photostructurable pour, in fine, réaliser des dispositifs optiques non-réciproques pouvant être intégrés au sein de puces optiques. Le matériau nanocomposite MO est obtenu en dispersant des nanoparticules magnétiques (NP) de ferrite de cobalt dans une matrice sol-gel d’alcoxydes de silicium et de titane. Les NP confèrent au matériau ses propriétés MO. La formulation du matériau est photostructurable en UV profond (193, 266 nm) sans ajout de photoamorceur et se comporte comme une photo-résine négative. La formulation est flexible en termes de ratio molaire Si/Ti et de dopage en NP pouvant atteindre 20 %vol. La photochimie du matériau en films minces a été étudiée par ellipsométrie spectroscopique, FTIR et spectroscopie UV-visible. Les techniques de photolithographies UV interférométriques et par masques binaires ont permis de réaliser des réseaux périodiques de lignes bien définis et couvrant une large gamme de périodes, de 500 nm à 100 µm. Les propriétés optiques et MO (rotation Faraday) du matériau ont été étudiées. En couches minces, l’indice de réfraction peut être modulé entre 1,4 et 1,7 selon la composition du matériau. Il a été établi que l’ensemble des NP introduites dans le matériau contribuent à la rotation Faraday. Des dispositifs microstructurés ont été réalisés en espace libre et en configuration guidée en se basant sur les dimensionnements opto-géométriques déterminés par des simulations optiques et MO. Leurs caractérisations démontrent l’intérêt de ce matériau et son caractère prometteur pour réaliser des dispositifs intégrés. / The main objective of this PhD work is to formulate a nanocomposite material with magneto-optical (MO) properties which is also photostructurable, in order to ultimately create non-reciprocal optical devices that can be integrated into optical chips. The nanocomposite MO material is obtained by homogenously dispersing magnetic nanoparticles (NP) of cobalt ferrite in a sol-gel matrix based on silicon and titanium alkoxides. NP confer the material its MO properties. The material is photostructurable with deep UV wavelengths (193, 266 nm) without any addition of photoinitiator and behaves like a negative photoresist. The formulation is versatile in terms of Si/Ti molar ratio and NP doping, up to 20 %vol. The photochemistry of this material as thin films has been studied by spectroscopic ellipsometry, FTIR and UV-visible spectroscopy. UV photolithography techniques using interferometry setups and binary masks have achieved well-defined periodic lines patterns over a wide range of periods, from 500 nm to 100 microns. The optical and MO (Faraday rotation) properties of the material were studied. In thin layers, the refractive index can be modulated between 1.4 and 1.7 depending on the Si/Ti material stoichiometry and its NP doping. It has been established that all the NP introduced in the material contribute to the Faraday rotation. Micro-structured devices in free space and in guided configuration have been realized using the opto-geometrical features determined using optical and MO simulations. Their characterizations demonstrate the high interest of this material and clearly show its promising character to realize integrated devices.

Nanocomposite magnéto-Optique

Photostructuration

Sol-Gel hybride

Dispositif magnéto-Optique

Rotation Faraday

Simulations

Nanoparticules magnétiques

Photolithographie

Magneto-Optical nanocomposite

Photostructuration

Hybrid sol-Gel

Magneto-Optical device

Faraday rotation

Modelling

Magnetic nanoparticles

Photolithography

Fast Sweeping Methods for Steady State Hyperbolic Conservation Problems and Numerical Applications for Shape Optimization and Computational Cell Biology

Chen, Weitao

08 August 2013

No description available.

Mathematics

Applied Mathematics

steady states

hyperbolic conservation laws

fast sweeping

Lax-Friedrichs

WENO

shape optimization

optical device

eigenvalue problems

steepest descent

computational cell biology

yeast mating

level set method