Ultrafast laser-induced nanostructuring of metals in regular patterns / Nanostructuration des métaux par motifs réguliers induits par laser ultrabref

Li, Chen

22 May 2016

Les structures périodiques de surface induites par laser femtoseconde(fs-LIPSS) attirent l'attention scientifique et technique en raison de la possibilité de produire des nanostructures en dessous de la longueur d'onde optique. Ces éléments sont essentiels pour l'ingénierie de surface et les procédés, notamment en tribologie, mouillabilité, la mécanique, le marquage et la lutte contre la contrefaçon. Selon le régime d'interaction laser, en particulier la fluence du laser, le nombre d'impulsions et le type de matériaux, les impulsions ultracourtes peuvent induire des basses et des hautes fréquences spatiales-LIPSS (LSFL et HSFL), avec l'orientation perpendiculaire (┴E) ou parallèle (║E) à la polarisation du laser. Compte tenu de leur potentiel pour la nano-fabrication, ce travail se concentre sur les mécanismes potentiels de formation des LIPSS, en particulier la formation des HSFL sur les alliages métalliques. Afin d'étudier les indices optiques transitoires de matériaux excités dans la formation fs-LIPSS, nous avons d'abord développé de l’ellipsométrie résolue en temps afin de mesurer les indices optiques dynamiques des matériaux excités. Ainsi, nous avons obtenu un aperçu de la dynamique de la fonction diélectrique intrinsèquement liée à la configuration électronique et au réseau cristallin. Des simulations de premiers principes sont ensuite utilisées pour révéler la façon dont la configuration électronique change au cours de l'excitation, responsable d’indices optiques transitoires. Les effets des indices optiques transitoires sont pris en compte dans les mécanismes de formation de LIPSS. Sur la base d’expériences de formations des fs-LIPSS sur six matériaux différents, incluant du tungstène métallique, du silicium semiconducteur, de la silice fondue diélectrique, un superalliage monocristallin CMSX-4, un alliage amorphe de Zr-BMG et son alliage cristallin correspondant Zr-CA, nous étudions les mécanismes de formation des LIPSS dans le domaine électromagnétique par des simulations de différences finies dans le domaine temporel (FDTD), liées à la distribution d'énergie électromagnétique suivie par la dynamique de l'excitation optique et par l'évolution de la topologie avec le nombre d’impulsions et les matériaux. Nous nous concentrons sur l'origine électromagnétique de la formation des LIPSS et révélons un facteur principal potentiel de leur formation. Elle peut être expliquée par la modulation de l'énergie déposée sur la surface par des effets électromagnétiques. La modulation de l'énergie provient principalement de l'interférence entre le laser incident et les ondes de surface diffusées (pour LSFL ( ┴ E)), complétée par l'interférence entre les ondes de surface diffusées (pour HSFL (┴E)). Spécialement, pour HSFL (║E) sur Zr-CA, nous avons proposé que les scénarios de formation reposent sur des processus individuels d’exaltation anisotrope du champ. La topologie de surface, évoluant avec le nombre d'impulsions laser, induit une modulation d'énergie déposée sur la surface définie et amplifiée par la rétroaction / Femtosecond laser-induced periodic surface structures (fs-LIPSS) attract the scientific and technical attention due to the ability to produce nanostructures below the optical wavelength. These are essential for surface engineering and treatment, notably in tribology, wettability, mechanics, marking and counterfeiting. Depending on the regime of laser interaction, particularly on the laser fluence, pulse number and material type, ultrashort pulses can induce the low- and high-spatial-frequency-LIPPS (LSFL and HSFL), with the orientation perpendicular (┴E) or parallel (║E) to the laser polarization. Considering their potential in the nano-manufacturing, this work focuses on potential mechanisms for LIPSS formation, especially HSFL formation on the metallic alloys. In order to investigate the transient optical indices of excited materials in fs-LIPSS formation, we first developed time-resolved ellipsometry to measure dynamic optical indices of excited materials. Thus we gain insights in the dynamics of the dielectric function where this is intrinsically related to the electronic configuration and lattice structure. First principle simulations are then used to reveal how the electronic configuration changes during the excitation, responsible for the transient optical indices. The effects of transient optical indices are considered in the LIPSS formation mechanisms. Based on the experiments of fs-LIPSS formations on six different materials, involving metal tungsten, semiconductor silicon, dielectric fused silica, single-crystal superalloy CMSX-4, amorphous alloy Zr-BMG and its corresponding crystal alloy Zr-CA, we investigate the LIPSS formation mechanisms in the electromagnetic domain by finite-difference time-domain (FDTD) simulations, related to the electromagnetic energy distribution followed by the dynamics of optical excitation, evolving topologies with pulse number and materials.We focus on the electromagnetic origin of LIPSS formation and reveal a potential primary factor for LIPSS formation. LIPSS formation can be explained by deposited energy modulation on surface via electromagnetic effects. The energy modulation mainly comes from the interference between incident laser and scattered surface wave (for LSFL(┴E)), being complemented by the interference between scattered surface waves (for HSFL(┴E)). Specially, for HSFL (║E) on Zr-CA, we proposed that the formation scenarios rely on individual anisotropic field-enhancement processes. The evolving surface topology with laser pulse number leads to a feedback-driven energy modulation deposited on surface

Procédés laser ultrabref

Propriétés optiques transitoires

FDTD

LSP

Ultrafast laser process

Transient optical properties

FDTD

LSP

Studium dynamiky dynamiky magnetizace v GaMnAs pomocí ultrarychlé laserové spektroskopie / Investigation of magnetization dynamics in GaMnAs by ultrafast laser spectroscopy

Tesařová, Naďa

January 2013

i Abstract: This doctoral thesis is dedicated to the study of magnetization dynamics in ferromagnetic semiconductor (Ga,Mn)As using magneto-optical (MO) spectroscopy methods. The character of the magnetization dynamics after the impact of the laser pulse was investigated under different experimental conditions in an extensive set of optimized (Ga,Mn)As samples with Mn doping ranging from 1.5% to 14%. The thorough analysis of the measured MO signal enabled us to develop a new method that can be used to determine the laser pulse-induced real-space magnetization trajectory without any numerical modelling. Moreover, the investigation of the measured MO signals allowed us to determine the basic micromagnetic properties of (Ga,Mn)As, such as the magnetic anisotropy, the Gilbert damping or the spin stiffness. In addition to this, we found out that the light-induced magnetization precession can be caused by three distinct mechanisms - the sample heating due to the energy transfer from the laser pulses, the angular momentum transfer from the circularly polarized photons, and the influence of the non-equilibrium hole polarization induced by the relativistic spin-orbit interaction. The first of these mechanisms is rather well known but the two remaining ones, which are the optical analogues of the spin-transfer torque...

Relation entre auto-organisation et création/résorption de défauts microstructuraux sous irradiation laser ultrabrèves / Relationship between self-organization and creation/resorption of microstructural defects under ultrashort laser irradiation

Abou Saleh, Anthony

08 January 2019

L’irradiation des matériaux par des impulsions laser ultrabrèves déclenche un agencement anisotrope de la matière à l’échelle nanométrique: des structures de surface périodiques induites par laser (LIPSS). L'énergie laser déposée et distribuée de manière inhomogène dans le matériau induit des contraintes thermiques locales et des changements de phase transitoires entraînant ainsi des modifications microstructurales. Cette thèse porte sur le rôle de l'altération de la surface irradiée ainsi que les modifications microstructurales en profondeur dans la contribution à la formation des LIPSS, en établissant une corrélation entre l'auto-organisation de la matière et la génération de défauts en tenant en compte de l'orientation cristalline. Comme les LIPSS sont générés au seuil de transition de phase, l’étude de la corrélation avec les défauts induits est alors pertinente. Une étude expérimentale couplée à des simulations de dynamique moléculaire effectuées à l’Université de Virginie suggère que l'altération de surface générée par une irradiation d'échantillons monocristallins de Chrome dans le régime de spallation est susceptible de jouer un rôle majeur dans le déclenchement de génération de LIPSS de haute fréquence spatiale. La microscopie à force atomique ainsi que les résultats de simulations attestent que les caractéristiques de rugosité de surface à l'échelle nanométrique dépendent de l'orientation cristalline. La forte rugosité de surface générée par la première impulsion laser active la diffusion de la lumière laser et l’exaltation du champ local lors des irradiations ultérieures, ce qui génère des structures LIPSS de haute fréquence plus prononcés du côté (100) que celle du (110). Une étude expérimentale approfondie, utilisant la microscopie électronique rétrodiffusés et transmission, a révélé que le Cr (110) est plus susceptible d'être endommagé que les autres orientations cristallines de surface. On constate que les défauts induits par le laser peuvent altérer la topographie de surface et la région sous-jacente, ce qui peut avoir un impact sur les caractéristiques des centres de rugosité favorisant la formation de structures de fréquence spatiale élevée. Afin d’accéder à la transition de phase subie dans la région de formation des LIPSS, une approche d'analyse microstructurale à haute résolution couplée à des calculs hydrodynamiques est utilisée, comprenant la croissance épitaxiale et la nanocavitation. La formation de structures de fréquence spatiale élevée est le résultat de nanocavités périodiques piégés sous la surface, ainsi que des nanocavités apparues à la surface des matériaux cubiques faces centrées.De plus, étant donné que le feedback dans la formation des LIPSS est souvent évoquée, le comportement dynamique des surfaces a été sondé par microscopie électronique à photoémission et étayé par des calculs électromagnétiques. Un caractère périodique des photoélectrons émis par les creux des LIPSS a été mis en évidence, ce qui a permis de vérifier la modulation du dépôt d'énergie.Le travail effectué contribue non seulement à progresser vers l'objectif général d’élucider le phénomène complexe multi-échelles de la formation des LIPSS, mais ouvre une nouvelle voie expérimentale pour générer des structures non conventionnelles avec des périodicités extrêmes (~60nm), offrant ainsi de nouvelles opportunités pour le traitement laser ultrarapide des métaux. / Irradiation of materials by ultrashort laser pulses triggers anisotropically structured arrangement of matter on the nanoscale, the so-called laser-induced periodic surface structures (LIPSS), or ‘ripples’. Ultrashort laser energy deposited and distributed inhomogeneously in the material launches local thermal stresses and transient phase changes yielding microstructural modifications. This thesis focuses on the role of irradiated surface alteration as well as in-depth microstructural modifications in promoting LIPSS formation, by establishing a correlation between self-organization of matter and defect generation taking into account crystalline orientation. Since LIPSS are generated at the threshold of phase transition, then the correlation with defects formation is relevant. An experimental study coupled with molecular dynamic MD simulations performed in the University of Virginia suggest that surface alteration generated by a single pulse irradiation of monocrystalline Cr samples in the spallation regime is likely to play a main role in triggering high-spatial frequency LIPSS generation upon irradiation by multiple laser pulses. Atomic force microscopy as well as computational results suggested that the nanoscale surface features are crystalline orientation dependent. The higher surface roughness generated by the first laser pulse activates scattering of the laser light and the local field enhancement upon irradiation by the second laser pulse, leading to the formation of much more pronounced high-spatial frequency structures on the (100) surface as compared to (110) one. An extended in-depth experimental study, using electron backscattered and transmission microscopy, combined with large-scale two-temperature model TTM-MD simulations revealed that Cr (110) is more likely to get damaged. It is found that laser-induced defects can alter the surface topography and the region beneath it which can impact in turn the roughness center features promoting high-spatial frequency structures formation. In order to infer the phase transition undergone in the LIPSS region, a high resolution microstructural analysis approach coupled with hydrodynamic calculations is employed, including epitaxial regrowth and nanocavitation. High-spatial frequency structures formation is found to be the result of periodic nanovoids trapped beneath the surface as well as nanocavities emerged at the surface on fcc materials. Furthermore, since optical feedback in LIPSS is often evoked, the behavior of dynamical surfaces was probed by photoemission electron microscopy and supported by electromagnetic calculations. A periodic character of photoelectrons emitted from nanoholes was unveiled, which in turn verified a modulated energy deposition. The performed work not only contributes to the progress towards the general goal of untangling the complex multiscale phenomenon of the LIPSS formation, but unlocks a new experimental setup to generate unconventional structures with extreme periodicities (~60 nm), which offers new opportunities in ultrafast laser processing of metals.

LIPSS

Irradiation des matériaux

Laser

Altération des surfaces

Rugosité

Nanocavités

Cavitation

LIPSS

Feedback

Local-field enhancement

Defects

Roughness

Nanoholes

Cavitation

Ultrafast laser nanostructuring

Ultrafast laser-absorption spectroscopy in the mid-infrared for spatiotemporally resolved measurements of gas properties

Ryan J Tancin (10711722)

27 April 2021

<div>Laser-absorption spectroscopy (LAS) is widely used for providing non-intrusive and quantitative measurements of gas properties (such as temperature and absorbing species mole fraction) in combustion environments. However, challenges may arise from the line-of-sight nature of LAS diagnostics, which can limit their spatial resolution. Further, time-resolution of such techniques as scanned direct-absorption or wavelength-modulation spectroscopy is limited by the scanning speed of the laser and the optical bandwidth is often limited by a combination of a laser's intrinsic tunability and its scanning speed. The work presented in this dissertation investigated how recent advancements in mid-IR camera technology and lasers can be leveraged to expand the spatial, temporal, and spectral measurement capabilities of LAS diagnostics. Novel laser-absorption imaging and ultrafast laser-absorption spectroscopy diagnostics are presented in this dissertation. In addition, the high-pressure combustion chamber (HPCC) and high-pressure shock tube (HPST) were designed and built to enable the study of, among others, energetic material combustion, spectroscopy, non-equilibrium and chemistry using optical diagnostics.<br></div><div><br></div>

Aerospace Engineering

Laser Absorption Spectroscopy

Shock Tube

laser absorption tomography

high-pressure combustion chamber

ultrafast laser absorption spectroscopy

propellant flames

combustion diagnostics

Etude du comportement dynamique des sources laser ultrarapides à base de fibres actives fortement dispersives / Study of the dynamic behavior of ultrafast laser sources from highly dispersive active fibers

Tang, Mincheng

23 June 2017

Les lasers ultra-rapides fibrés sont aujourd’hui incontournables dans de nombreuses applications industrielles et scientifiques du fait de leur stabilité, de leur compacité et des hautes puissances disponibles. Les performances actuelles, rendues accessibles par le développement de fibres à larges aires modales et le concept d’amplification à dérive de fréquence, sont toutefois complexes à mettre oeuvre et limitées par l’utilisation de composants massifs pour les étapes de compression et d’étirement des impulsions. Ces travaux de thèse, à la fois expérimentaux et numériques, avaient pour objectif d’explorer des régimes dynamiques originaux basés sur l’utilisation de fibres actives spécifiques combinant large aire modale et propriétés dispersives adéquates pour la génération d’impulsions ultra-courtes de haute énergie. Les études numériques ont ainsi permis de montrer que des régimes impulsionnels à haute dispersion normale pouvaient être atteints en exploitant les phénomènes de résonnance et de couplage de modes dans des fibres de Bragg ou à profil en W. L’étude de l’influence des paramètres de la cavité laser sur le mécanisme de verrouillage de modes a permis d’identifier des configurations attractives pour la montée en puissance. La mise en oeuvre expérimentale de ces concepts a notamment permis le développement d’une source laser à soliton dissipatif produisant des impulsions énergétiques (38 nJ, 700 fs après compression) à des longueurs d’ondes autour de 1560 nm, record pour ce type d’oscillateur. La réalisation expérimentale de sources ultra-rapides basées sur des fibres actives spécifiques combinées au phénomène de couplage de mode ont permis d’identifier les potentialités et limitations de ces architectures originales à fortes dispersions totales pour la montée en énergie. / Ultrafast fiber lasers represent today a ubiquitous technology in various industrial and research applications thanks to their inherent advantages such as compactness, stability and high power. The best performances to date, mostly relying on large mode area fibers and chirped pulse amplification, however require complex experimental developments and are limited by the use of bulk components for pulse stretching and compression. The experimental and numerical work presented in this PhD thesis aimed at exploring original dynamical regimes based on specific active fibers combining large mode area and high dispersions for the generation of high-energy ultra-short pulses. The numerical studies then showed that pulsed regimes with high normal dispersions could be reached by exploiting resonance and mode-coupling phenomena in Bragg or W-type fibers. Studying the influence of the cavity parameters on mode-locking mechanisms allowed to target attractive configurations for energy scaling. The experimental implementation of this concept allowed the development of a dissipative soliton source delivering record high-energy chirped pulses (38 nJ, 700 fs after compression) at 1560 nm. The realization of ultrafast sources based on specific active fibers combined to mode-coupling phenomena then brought the possibility to identify the potentiality and limitations of these particular architectures with high dispersions for energy scaling.

Laser à fibre

Laser ultra-rapide

Absorbant saturable à semi-conducteur

Fibre de Bragg

Haute énergie

Fibre laser

Ultrafast laser

Semiconductor saturable absorber

Bragg fibre

High energy

621.366

Développement de la spectroscopie DRASC femtoseconde à sonde à dérive de fréquence pour la thermométrie haute cadence dans les milieux gazeux réactifs / Development of the chirped probe pulse femtosecond coherent anti-Stokes Raman scattering for high-speed temperature measurements in gaseous reactive flowfields

Berthillier, Frédéric

19 December 2017

L’étude expérimentale des processus physico-chimiques de la combustion nécessite de disposer de diagnostics non-intrusifs. Le présent manuscrit reporte le développement du diagnostic laser de mesure de température DRASC (Diffusion Raman anti-Stokes Cohérente) en régime d’impulsions laser femtoseconde pour lequel la configuration à sonde à dérive de fréquence (CPP) a permis d’effectuer des mesures instantanées de température à 1kHz. Un travail à la fois théorique, numérique et expérimental a permis d’extraire la température des spectres DRASC instantanés acquis dans des mélanges air/argon (300-600K) et en flamme prémélangée CH4/Air avec une précision de l’ordre de 1% à 2100 K. La validité de ces résultats est obtenues par des confrontations numérique/expérimental pour différentes grandeurs d’influence. Cette étude permettra dans un proche futur d’appliquer le diagnostic DRASC fs CPP dans des flammes turbulentes représentatives d’écoulements réels observés en combustion aéronautique. / The experimental study of the physico-chemical processes of combustion requires the use of non-intrusive diagnostics. This manuscript reports the development of the CARS (Coherent Anti-Stokes Raman Scattering)) laser diagnostic in the femtosecond pulse regime for which the Chirped Pulse Probe (CPP) configuration enabled instantaneous measurements of temperature at 1kHz. A theoretical, numerical and experimental study allowed highlighting the possibility to measure temperature from the data processing of instantaneous DRASC spectra acquired in air/argon mixtures (300-600K) and in premixed flame CH4/Air with an accuracy of 1% at 2100 K. Validity of these results was obtained from numerical/experimental confrontations for different scalar parameters configurations. This study would enable in the near future the application of the CPP fs CARS diagnostic in turbulent flames representative of real flows observed in aeronautical combustion.

DRASC

Diffusion Raman anti-Stokes cohérente

Haute cadence

CARS

Coherent anti-Stokes Raman scattering

Laser diagnostic

Thermometry

High-repetition rate

Ultrafast laser pulse

Femtosecond

Synchronization In Advanced Optical Communications

Kim, Inwoong

01 January 2006

The objective of this dissertation is to generate high power ultrashort optical pulses from an all-semiconductor mode-locked laser system. The limitations of semiconductor optical amplifier in high energy, ultrashort pulse amplification are reviewed. A method to overcome the fundamental limit of small stored energy inside semiconductor optical amplifier called "eXtreme Chirped Pulse Amplification (X-CPA)" is proposed and studied theoretically and experimentally. The key benefits of the concept of X-CPA are addressed. Based on theoretical and experimental study, an all-semiconductor mode-locked X-CPA system consisting of a mode-locked master oscillator, an optical pulse pre-stretcher, a semiconductor optical amplifier (SOA) pulse picker, an extreme pulse stretcher/compressor, cascaded optical amplifiers, and a bulk grating compressor is successfully demonstrated and generates >kW record peak power. A potential candidate for generating high average power from an X-CPA system, novel grating coupled surface emitting semiconductor laser (GCSEL) devices, are studied experimentally. The first demonstration of mode-locking with GCSELs and associated amplification characteristics of grating coupled surface emitting SOAs will be presented. In an effort to go beyond the record setting results of the X-CPA system, a passive optical cavity amplification technique in conjunction with the X-CPA system is constructed, and studied experimentally and theoretically.

mode-locked laser

semiconductor laser

optical pulse compression

chirped fiber Bragg grating

ultrafast laser

semiconductor optical amplifier

chirped pulse amplification

Electromagnetics and Photonics

Optics

Two-Photon Direct Frequency Comb Spectroscopy of Rubidium

Chen, Sophia Lee

29 May 2012

No description available.

Physics

frequency comb

optical frequency comb

atomic spectroscopy

ultrafast laser

velocity selective resonance

precision spectroscopy

Doppler-free atomic spectroscopy

two-photon

spectroscopy

rubidium

Yb:tungstate waveguide lasers

Bain, Fiona Mair

January 2010

Lasers find a wide range of applications in many areas including photo-biology, photo-chemistry, materials processing, imaging and telecommunications. However, the practical use of such sources is often limited by the bulky nature of existing systems. By fabricating channel waveguides in solid-state laser-gain materials more compact laser systems can be designed and fabricated, providing user-friendly sources. Other advantages inherent in the use of waveguide gain media include the maintenance of high intensities over extended interaction lengths, reducing laser thresholds. This thesis presents the development of Yb:tungstate lasers operating around 1μm in waveguide geometries. An Yb:KY(WO₄)₂ planar waveguide laser grown by liquid phase epitaxy is demonstrated with output powers up to 190 mW and 76 % slope efficiency. This is similar to the performance from bulk lasers but in a very compact design. Excellent thresholds of only 40 mW absorbed pump power are realised. The propagation loss is found to be less than 0.1 dBcm⁻¹ and Q-switched operation is also demonstrated. Channel waveguides are fabricated in Yb:KGd(WO₄)₂ and Yb:KY(WO₄)₂ using ultrafast laser inscription. Several of these waveguides lase in compact monolithic cavities. A maximum output power of 18.6 mW is observed, with a propagation loss of ~2 dBcm⁻¹. By using a variety of writing conditions the optimum writing pulse energy is identified. Micro-spectroscopy experiments are performed to enable a fuller understanding of the induced crystal modification. Observations include frequency shifts of Raman lines which are attributed to densification of WO₂W bonds in the crystal. Yb:tungstate lasers can generate ultrashort pulses and some preliminary work is done to investigate the use of quantum dot devices as saturable absorbers. These are shown to have reduced saturation fluence compared to quantum well devices, making them particularly suitable for future integration with Yb:tungstate waveguides for the creation of ultrafast, compact and high repetition rate lasers.

535

Point-of-Care High-throughput Optofluidic Microscope for Quantitative Imaging Cytometry

Jagannadh, Veerendra Kalyan

January 2017

Biological research and Clinical Diagnostics heavily rely on Optical Microscopy for analyzing properties of cells. The experimental protocol for con-ducting a microscopy based diagnostic test consists of several manual steps, like sample extraction, slide preparation and inspection. Recent advances in optical microscopy have predominantly focused on resolution enhancement. Whereas, the aspect of automating the manual steps and enhancing imaging throughput were relatively less explored. Cost-e ective automation of clinical microscopy would potentially enable the creation of diagnostic devices with a wide range of medical and biological applications. Further, automation plays an important role in enabling diagnostic testing in resource-limited settings. This thesis presents a novel optofluidics based approach for automation of clinical diagnostic microscopy. A system-level integrated optofluidic architecture, which enables the automation of overall diagnostic work- ow has been proposed. Based on the proposed architecture, three different prototypes, which can enable point-of-care (POC) imaging cytometry have been developed. The characterization of these prototypes has been performed. Following which, the applicability of the platform for usage in diagnostic testing has been validated. The prototypes were used to demonstrate applications like Cell Viability Assay, Red Blood Cell Counting, Diagnosis of Malaria and Spherocytosis. An important performance metric of the device is the throughput (number of cells imaged per second). A novel microfluidic channel design, capable of enabling imaging throughputs of about 2000 cells per second has been incorporated into the instrument. Further, material properties of the sample handling component (microfluidic device) determine several functional aspects of the instrument. Ultrafast-laser inscription (ULI) based glass microfluidic devices have been identi ed and tested as viable alternatives to Polydimethylsiloxane (PDMS) based microfluidic chips. Cellular imaging with POC platforms has thus far been limited to acquisition of 2D morphology. To potentially enable 3D cellular imaging with POC platforms, a novel slanted channel microfluidic chip design has been proposed. The proposed design has been experimentally validated by performing 3D imaging of fluorescent microspheres and cells. It is envisaged that the proposed innovation would aid to the current e orts towards implementing good quality health-care in rural scenarios. The thesis is organized in the following manner : The overall thesis can be divided into two parts. The first part (chapters 2, 3) of the thesis deals with the optical aspects of the proposed Optofluidic instrument (development, characterization and validations demonstrating its use in poc diagnostic applications). The second part (chapters 4,5,6) of the thesis details the microfluidic sample handling aspects implemented with the help of custom fabricated microfludic devices, the integration of the prototype, func-tional framework of the device. Chapter 2 introduces the proposed optofluidic architecture for implementing the POC tool. Further, it details the first implementation of the proposed platform, based on the philosophy of adapting ubiquitously available electronic imaging devices to perform cellular diagnostic testing. The characterization of the developed prototypes is also detailed. Chapter 3 details the development of a stand-alone prototype based on the proposed architecture using inexpensive o -the-shelf, low frame-rate image sensors. The characterization of the developed prototype and its performance evaluation for application in malaria diagnostic testing are also presented. The chapter concludes with a comparative evaluation of the developed prototypes, so far. Chapter 4 presents a novel microfludic channel design, which enables the enhancement of imaging throughput, even while employing an inexpensive low frame-rate imaging modules. The design takes advantage of radial arrangement of microfludic channels for enhancing the achievable imaging throughput. The fabrication of the device and characterization of achievable throughputs is presented. The stand-alone optofluidic imaging system was then integrated into a single functional unit, with the proposed microfluidic channel design, a viscoelastic effect based micro uidic mixer and a suction-based microfluidic pumping mechanism. Chapter 5 brings into picture the aspect of the material used to fabricate the sample handling unit, the robustness of which determines certain functional aspects of the device. An investigative study on the applicability of glass microfluidic devices, fabricated using ultra-fast laser inscription in the context of the microfluidics based imaging flow cytometry is presented. As detailed in the introduction, imaging in poc platforms, has thus far been limited to acquisition of 2D images. The design and implementation of a novel slanted channel microfluidic chip, which can potentially enable 3D imaging with simplistic optical imaging systems (such as the one reported in the earlier chapters of this thesis) is detailed. A example application of the proposed microfludic chip architecture for imaging 3D fluorescence imaging of cells in flow is presented. Chapter 6 introduces a diagnostic assessment framework for the use of the developed of m in an actual clinical diagnostic scenario. The chapter presents the use of computational signatures (extracted from cell images) to be employed for cell recognition, as part of the proposed framework. The experimental results obtained while employing the framework to identify cells from three different leukemia cell lines have been presented in this chapter. Chapter 7 summarizes the contributions reported in this thesis. Potential future scope of the work is also detailed.

Optofluidic Microscope

Quantitative Imaging Cytometry

Quantitative Morphometry

Cell Enumeration

Optical System Characterization

Point-of-Care Cytometry

Imaging Flow Cytometry

Optofluidic Imaging Flow Analyzer

Microfluidic Microscopy

Microfluidics

Ultrafast-laser inscription (ULI)

Polydimethylsiloxane (PDMS)

Instrumentation