Orientation of elongated, macro and nano-sized particles in macroscopic flows

Håkansson, Karl

January 2014

Non-spherical particles are present all around us, in biological, industrial and environmental processes. Making predictions of their impact on us and systems in our vicinity can make life better for everyone here on earth. For example, the ash particles from a volcano eruption are non-spherical and their spreading in the atmosphere can hugely impact the air traffic, as was also proven in 2010. Furthermore, the orientation of the wood fibres in a paper sheet influences the final properties of the paper, and the cause of a specific fibre orientation can be traced back to the fluid flows during the manufacturing process of the paper. In this thesis, experimental and numerical work is presented with the goal to understand and utilize the behavior of elongated particles in fluid flows. Two different experimental setups are used. The first one, a turbulent half channel flow, aims at increasing the understanding of how particles with non-zero inertia behave in turbulence. The second setup is an attempt to design a flow field with the purpose to align nanofibrils and create high performance cellulose filaments. Experiments were performed in a turbulent half channel flow at different flow set- tings with dilute suspensions of cellulose acetate fibres having three different aspect ratios (length to width ratio). The two main results were firstly that the fibres agglom- erated in streamwise streaks, believed to be due to the turbulent velocity structures in the flow. Secondly, the orientation of the fibres was observed to be determined by the aspect ratio and the mean shear, not the turbulence. Short fibres were oriented in the spanwise direction while long fibres were oriented in the streamwise direction. In order to utilize the impressive properties (stiffness comparable to Kevlar) of the cellulose nanofibril in a macroscopic material, the alignment of the fibrils must be controlled. Here, a flow focusing device (resulting in an extensional flow), designed to align the fibrils, is used to create a cellulose filament with aligned fibrils. The principle is based on a separation of the alignment and the assembly of the fibrils, i.e. first align the fibrils and then lock the aligned structure. With this process, continuous filaments were created, with properties similar to that of the wood fibre at the same fibril alignment. However, the highest alignment (lowest angle) of the fibrils in a filament created was only 31o from the filament axis, and the next step is to increase the alignment. This thesis includes modeling of the alignment process with the Smoluchowski equation and a rotary diffusion. Finding a model that correctly describes the alignment process should in the end make it possible to create a filament with fully aligned fibrils. / <p>QC 20140908</p>

Orientation

fibre

fibril

turbulent channel flow

particle streaks

flow focusing

cellulose nanofibrils

extensional flow

Smoluchowski

rotary diffusion

DYNAMICS OF DROP FORMATION IN MICROFLUIDIC DEVICES

Husny, Joeska

Unknown Date

No description available.

Biomechanical study of cells in microfluidic flow : application to sorting and platelet production / Etude biomécanique de cellules en écoulement microfluidique : application au tri et à la production de plaquettes

Vesperini, Doriane

10 October 2018

Les mégacaryocytes sont des cellules de la moelle osseuse, à l’origine de la production des plaquettes sanguines. Quand elles arrivent à maturité, elles grossissent et émettent des prolongements de cytoplasme à travers la paroi des vaisseaux irriguant la moelle. Dans la circulation sanguine, ces prolongements, soumis aux forces de l’écoulement, s’allongent et se rompent pour former des plaquettes. Des techniques microfluidiques capables de produire des plaquettes in vitro existent et sont une alternative prometteuse au don. Mais le rendement reste à améliorer. Pour cela, il est nécessaire de mieux comprendre la fragmentation des mégacaryocytes en plaquettes. Ce travail de doctorat s’inscrit dans ce contexte et sera développé en deux axes principaux dans ce manuscrit. Dans une première partie nous développons une méthode pour trier des cellules en fonction de leur déformabilité, afin de savoir si les propriétés mécaniques d’un mégacaryocyte sont liées à leur stade de maturité. La méthode a d’abord été mise au point avec des microcapsules. Leurs propriétés mécaniques sont déterminées par analyse inverse à partir de la mesure de leur forme en écoulement dans des constrictions droites. Puis le dispositif utilisé a été miniaturisé pour s’adapter à la taille des cellules. Pour la caractérisation de leurs propriétés mécaniques, deux outils ont été utilisés: l’analyse inverse et la microscopie à force atomique sans pointe. Une deuxième partie porte sur l’étude de l’élongation et de la rupture de mégacaryocytes soumis écoulement. Nous avons quantifié les variations spatiotemporelles du taux d’élongation et développé un protocole d’ablation laser pour étudier les mécanismes de rupture de cellules en élongation. / When they mature in the bone marrow, the precursors of platelets, called megakaryocytes, grow and extend protrusions able to join blood circulation. There these protrusions elongate and break into platelets. Microfluidic techniques for in vitro platelet production represent a promising alternative to donation. In order to enhance platelet production and match the needs of clinical applications such as transfusion, we need to better understand the fragmentation of megakaryocytes into platelets. Our contribution will be described in this manuscript in two main axes. First, in order to know if mechanical properties of megakaryocytes can indicate their maturity stage, we develop a cell sorting method based on deformability. The method is first validated with microcapsules. Their mechanical properties are determined by inverse analysis from their shape under flow in straight microchannels. Then the device is downscaled. The characterization of cell mechanical properties are performed using inverse analysis and tipless atomic force microscopy. Second, we study megakaryocyte elongation and rupture in a microfluidic device. We quantify the spatial and temporal variations of the elongation rate and develop a laser ablation protocol to trigger and study the rupture of elongating cells.

Propriétés mécaniques

Ablation laser

Microcapsules

Tri

Ablation laser

Flow-focusing

Atomic force microscopy (AFM)

Microfluidics

Megakaryocytes

Blood platelets

Blood cells

Microcapsules

Sorting

Deformability

Biomechanics

Mechanical properties

Design & Analysis of Microfluidic Systems for Droplet Generation via Flow Focusing & Electrogeneration

Shinwary, Syed Siawash

04 1900

<p>Microdroplets have large and varied areas of application ranging from document printing to complex lab-on-chip devices. Lab-on-chip systems often require precise volume control as well as high throughput operations. Microdroplets fulfill these requirements and have become a staple in these devices. The work presented in this thesis involves the design and characterization of two individual devices capable of droplet generation utilizing flow focusing and electrogeneration methods.</p> <p>The first design involved the generation of gel microdroplets utilizing the flow focusing technique. This device proved to be robust and reliable producing large volumes of uniformly mixed droplets. Long term operation of this device was analyzed and determined to be a feasible route for the manufacture of large quantities of droplets. The device was operated for over 30 hours creating gel droplets ranging from 40-200 μm in diameter with acceptable polydispersities for use in drug release studies.</p> <p>The second device involved the design and characterization of a system for the electrogeneration of microdroplets. This novel device involved the injection of droplets via high voltage and high frequency signals into a cross-flow of oil. The droplet generation was characterized and different droplet generation modes were observed. With the careful selection of parameters ideal conditions were obtained to generate monodisperse droplets of sizes ranging from under 5 to over 100 μm in a highly repeatable manner.</p> <p>To conclude, two separate microfluidic droplet generation devices operating in distinct modes were designed and analyzed. These devices are robust, reliable, and flexible with some applications being tested.</p> / Master of Applied Science (MASc)

microfluidics

flow focusing

droplet generation

microdroplet

lab on a chip

drop on demand

Applied Mechanics

Electro-Mechanical Systems

Other Chemical Engineering

Other Mechanical Engineering

Applied Mechanics

Vers des micromousses stimulables

Yip Cheung Sang, Yann

03 July 2009

L'étude de matériaux intelligents, capables de s'adapter à des stimuli externes est actuellement en plein développement. La ligne directrice de cette thèse est la création de mousses avec des propriétés optiques particulières dans le domaine visible et modulables par un champ magnétique. Cela pose deux problèmes: parvenir d'une part à réaliser une mousse ordonnée constituée de cellules de taille micrométrique et d'autre part à coupler efficacement son arrangement avec un champ magnétique. Ce travail, au cœur des thématiques de la matière molle, se divise en trois parties. La première partie décrit le comportement rhéophysique de solutions aqueuses d'alginate de sodium (polyélectrolyte anionique) et de nanoparticules magnétiques, solutions qui gélifient en présence d'ions calcium. La seconde partie concerne les mousses aqueuses et les bulles monodisperses micrométriques: il est d'abord présenté l'étude de la pression osmotique et de la transition structurelle en fonction de la fraction liquide d'une mousse cristalline générée par un dispositif microfluidique (diamètre des bulles: ~ 100 µm). Puis, une méthode originale basée sur le rétrécissement de bulles est introduite pour créer des bulles ou des gouttes monodisperses micrométriques. Enfin, la troisième partie rassemble les différentes connaissances acquises pour accéder aux premières mousses gélifiées magnéto-stimulables.

ferrofluide

rhéophysique

microfluidique

flow-focusing

bulles monodisperses

gouttes monodisperses

mousse cristalline

pression osmotique

drainage

mousse gélifiée magnétique

matériaux intelligents

matière molle

Particle manipulation in minichannels for enhanced digital holographic microscopy observation / Manipulation de mcroparticules dans des minicanaux pour une observation améliorée au microscope holographique digitale.

Perfetti, Claire

24 April 2014

The development of techniques targeting the manipulation of particles of different<p>sizes - mostly in the nano to millimeter scale - when dispersed in a carrier medium, is an increasingly important topic in many fields such as biotechnology,nanotechnology, medicine, biophysics and environmental monitoring and remediation. The underlying rationale for using such techniques stands in the sometimes compelling requirements of avoiding clogging as in micro/nano channel flows, of limiting sedimentation and wall interactions in particle/cell counting, of enhancing particle-surface interaction as in bio-sensing or of facilitating characterization and sorting as in bio-physical applications. Being developed in the frame of a Belgian national project devoted to the characterization and counting of pollutant in water media by digital holographic microscopy, this thesis tackles a peculiar class of particle manipulation techniques, commonly known as Focusing. The main goal of focusing is to avoid at best wall particle interactions and sedimentation, prevalent issues for dispersions owing in micro/mini-channels especially for applications such as optical characterization and counting.<p><p>The main attention was given to two flow focusing techniques - Hydrodynamic and Acoustic Focusing - for their wide range applicability and cost effectiveness. Hydrodynamic Focusing consists in controlling the position and spreading of the sample under investigation by means of a so-called sheath flow. A low-cost, nevertheless effective, prototype has been conceived, designed, manufactured and tested. It allowed for controlling the spreading of the sample stream and achieving a focusing ratio accounting for only 4% of the original stream width.<p><p>Acoustic Focusing takes advantage of the time-averaged pressure fields induced by the creation of standing waves in channels to manipulate and focus the dispersed particles. In the frame of this thesis, several devices have been developed using square cross section glass mini-channels. Aside from the cost-effectiveness, particles where focused in a somehow unexpected but high reproducible 3D matrix-like structure. A novel numerical model has also been implemented in order to study the conditions leading to the 3D structure formation. A good agreement between experimental and numerical results was found./Ce projet de thèse portant sur la manipulation de micro-particules dans des minicanaux s'inscrit dans le développement de cellules de flux pour des applications biologiques, qui est l'une des problématiques du projet HOLOFLOW, soutenu par<p>la région de Bruxelles Capitale. Les cellules de flux doivent permettre l'observation et la reconnaissance des micro-organismes vivants dans une large gamme de dimensions (de quelques microns à 1mm) avec la microscopie holographie digitale.<p>La problématique d'observation et de manipulation des microorganismes en flux est liée au clogging (bouchage) et à la sédimentation qui limitent la durée de vie des cellules d'observation. Ce projet de thèse s'inscrit dans cette problématique et propose deux axes d'étude pour limiter l'interaction entre organismes et canaux, la focalisation hydrodynamique, basée sur le guidage de flux, et la focalisation acoustique, basée sur la manipulation des particules.<p><p>La focalisation hydrodynamique est une technique basée sur l'injection différentiée de l'échantillon à observer et d'un fluide support. La différence des vitesses d'injection des flux permet de contrôler la dispersion des particules afin d'optimiser leur observation. Dans le cadre de cette thèse, un prototype à bas-coût a été développé et construit, permettant de focaliser les particules dans un faisceau jusqu'à 4% de leur faisceau incident.<p><p>La focalisation acoustique utilise la création d'une onde acoustique stationnaire afin de regrouper les particules en suspension au centre du canal. Au cours de cette thèse, plusieurs prototypes ont été réalisés, mettant en évidence la formation de motifs tridimensionnaux. Un model numérique a été spécialement développé afin d'étudier les conditions de génération de ces motifs, et de nombreuses expériences ont été menées afin de s'assurer de leur reproductibilité. Une bonne adéquation entre la position des particules mesurée et calculée numériquement a été démontrée. / Doctorat en Sciences de l'ingénieur / info:eu-repo/semantics/nonPublished

Contrôle des matériaux

Three-dimensional imaging

Acoustic holography

Sound-waves

Imagerie tridimensionnelle

Holographie acoustique

Ondes sonores

microparticules

Focalisation hydrodynamique

Focalisation 3D

minicanaux

Microscopy holographique numérique

Ondes Acoustiques Stationnaires

3D flow focusing

sheath flow warping

Acoustic standing waves

Acoustofluidic