Actuation Of Droplets Using Transparent Graphene Electrodes For Tunable Lenses And Biomedical Applications

Variable focal length liquid microlenses are the next candidate for a wide variety of applications. Driving mechanism of the liquid lenses can be categorized into mechanical and electrical actuation. Among different actuation mechanisms, EWOD is the most common tool for actuation of the liquid lenses. In this dissertation, we have demonstrated versatile and low-cost miniature liquid lenses with graphene as electrodes. Tunable focal length is achieved by changing both curvature of the droplet using electrowetting on dielectric (EWOD) and applied pressure. Ionic liquid and KCl solution are utilized as lens liquid on the top of a flexible Teflon-coated PDMS/parylene membrane. Transparent and flexible, graphene allows transmission of visible light as well as large deformation of the polymer membrane to achieve requirements for different lens designs and to increase the field of view without damaging of electrodes. Another advantage of graphene compared to non-transparent electrodes is the larger lens aperture. The tunable range for the focal length is between 3 and 7 mm for a droplet with a volume of 3 μL. The visualization of bone marrow dendritic cells is demonstrated by the liquid lens system with a high resolution (more than 456 lp/mm). The Spherical aberration analysis is performed using COMSOL software to investigate the optical properties of the lens under applied voltages and pressure. We propose a prototype of compound eye with specific design of the electrodes using both tunable lenses and tunable supporting membrane. The design has many advantages including large field of view, compact size and fast response time. This work maybe applicable in the development of the next generation of cameras, endoscopes, cell phones on flexible platform. We also proposed here the design and concept of self-powered wireless sensor based on the graphene radio-frequency (RF) components, which are transparent, flexible, and monolithically integrated on biocompatible soft substrate. We show that a quad-ring circuit based on graphene transistors may simultaneously offer sensing and frequency modulation functions. This battery-free and transparent sensors based on newly discovered 2D nanomaterials may benefit versatile wireless sensing and internet-of-things applications, such as smart contact lenses/glasses and microscope slides

Dispositivos microfluídicos digitales: fundamentos de su funcionamiento, requerimientos de fabricación y aplicaciones

El uso de dispositivos microfluídicos digitales (DM) han demostrado ser herramientas muy eficaces para la manipulación de pequeños volúmenes de líquidos de forma precisa o su uso en lentes líquidas que superan en versatilidad a las lentes convencionales. Sin embargo, en la actualidad, la fabricación de estos dispositivos presenta numerosos desafíos, debido en especial al alto impacto medioambiental de los materiales utilizados. Aquí se presenta una breve explicación de los fundamentos de funcionamiento de estos dispositivos, requerimientos en su fabricación y algunas de sus aplicaciones

Investigation of Microfluidic Kelvin Water Dropper and Its Applications in Contact and Contactless Electrowetting

A typical Kelvin water dropper is a device that can convert gravitational potential energy to a high voltage electrostatic. This device consists of two inductors, two collectors, tubes, and electrical connections. A Kelvin water dropper is able to generate extremely high voltage by separating ions using two positive feedback loops. A Kelvin water dropper provides a low cost solution for the applications in which high voltage is needed. In the present research, low cost Microfluidic Kelvin Water Droppers (MKWDs) were developed and built in house for electrowetting applications. Two MKWDs with different tube inner diameters (254 and 508 μm) were constructed to evaluate their appropriate power output for electrowetting. It was demonstrated that higher flow rate led to higher voltage generated, whereas the MKWD with larger tube diameters generated less voltage. Thereafter, contact electrowetting using the homemade MKWD was studied. Electrowetting is a process used to manipulate deformation of liquid droplets on a dielectric surface using an external electric field. In contact electrowetting, the droplet is in contact with a working electrode that applies the voltage. The electric field in the present research was applied using the MKWD. It was demonstrated that contact electrowetting of water droplets can be controlled using the MKWD. Then, a computational model was built to simulate the contact electrowetting using the MKWD. The model was successfully validated by comparing the experimental and simulation results. Finally, contactless electrowetting using the MKWD was investigated. As compared to contact electrowetting, the working electrode was separated from the water droplets. When applying an electric field using the MKWD, it was observed that the water droplet first corrugated due to electrostatic attraction, and then collapsed due to electrowetting. Unlike contact electrowetting, two processes were involved in contactless electrowetting. To simulate two processes, the first model was built based on the theory of electrostatics, and the second model was based on the conventional electrowetting. Both models were validated by a nice agreement between the experimental and simulation data

Optical Fluid-based Photonic And Display Devices

Conventional solid-state photonic devices exhibit an ultra-high optical performance and durability, but minimal adaptability. Recently, optical fluid-based photonic and display devices are emerging. By dynamically manipulating the optical interface formed by liquids, the optical output can be reconfigured or adaptively tuned in real time. Such devices exhibit some unique characteristics that are not achievable in conventional solid-state photonic devices. Therefore, they open a gateway for new applications, such as image and signal processing, optical communication, sensing, and lab-on-a-chip, etc. Different operation principles of optical fluidbased photonic devices have been proposed, for instance fluidic pressure, electrochemistry, thermal effect, environmentally adaptive hydrogel, electro-wetting and dielectrophoresis. In this dissertation, several novel optical fluid-based photonic and display devices are demonstrated. Their working principles are described and electro-optic properties investigated. The first part involves photonic devices based on fluidic pressure. Here, we present a membrane-encapsulated liquid lens actuated by a photo-activated polymer. This approach paves a way to achieve non-mechanical driving and easy integration with other photonic devices. Next, we develop a mechanical-wetting lens for visible and short-wavelength infrared applications. Such a device concept can be extended to longer wavelength if proper liquids are employed. In the second part, we reveal some new photonic and display devices based on dielectrophoretic effects. We conceive a dielectric liquid microlens with well-shaped electrode for fixing the droplet position and lowering the operating voltage. To widen the dynamic range, we demonstrate an approach to enable focus tuning from negative to positive or vice versa in a single dielectric lens without any moving part. The possibility of fabricating microlens arrays iv with different aperture and density using a simple method is also proposed. Furthermore, the fundamental electro-optic characteristics of dielectric liquid droplets are studied from the aspects of operating voltage, frequency and droplet size. In addition to dielectric liquid lenses, we also demonstrate some new optical switches based on dielectrophoretic effect, e.g., optical switch based on voltage-stretchable liquid crystal droplet, variable aperture or position-shifting droplet. These devices work well in the visible and near infrared spectral ranges. We also extend this approach to display and show a polarizer-free and color filter-free display. Simple fabrication, low power consumption, polarization independence, relatively low operating voltage as well as reasonably fast switching time are their key features

MODELING POWER CONSUMPTION AND OPERATION IN A BISTABLE ELECTROWETTING-BASED DISPLAY

Gemstone Team VOLTAGETeam VOLTAGE is an undergraduate research team based in University of Maryland’s Gemstone research program. Their objective is to advance research related to modeling e-paper technologies. Experimentation with electrowetting display fabrication techniques, followed by modeling based on measured parameters is performed. Both numerical and circuit-based simulations are performed. Numerical simulations demonstrate correlations between pixel size, alpha constant, actuation voltage, and power consumption. Circuit-based simulations demonstrate a method for determining power consumption of an electrowetting-based display and give an accurate power consumption for a specified display

Etude de microrésonateurs optiques polymères en anneaux en vue de leur intégration sur une plateforme de microfluidique digitale : application à la détection d'ions métalliques de Cr (VI) dans l'eau

The selective and sensitive detection of heavy metals, such as transition metals, is ofparamount importance for health and safety an environmental monitoring. Current referencemethods, due to their lack of portability, are limiting factors to obtain high-resolution spatialand temporal data. Optical sensors offer an attractive and convenient way to overcome theselimitations of cost and time per analysis by offering real time, on-site measurementcapabilities.In order to demonstrate this potential, this thesis is focused on the detection and quantificationof hexavalent chromium Cr(VI) in water samples by a colorimetric reaction based on areaction with the 1,5-diphenylcarbazide (DPC), that produces a complex possessing anabsorption maximum in the visible range. This works endorse the goal of creating a true labon-chip, integrating both the fluidic function based on ElectroWetting on Dielectric (EWOD)to create the colorimetric reaction, and the sensing function based on the integration of anoptical sensor able to measure absorption variations in micro-volumes (< μL). In order toobtain sufficient sensitivity on such small volumes, optical microring resonators are used inthis work, due to their ability to enhance the effective optical path length by constructiveinterferences.This thesis describes the conception and fabrication of the EWOD microfluidic platform, aswell as the conception, simulation and fabrication of submicronic microring resonators usingstepper lithography. Polymer materials and glass substrates are selected, due to their greatoptical properties in the visible range, their compatibility with the EWOD platform, and theirintegrability at a reasonable cost.La détection sensible et sélective des métaux lourds, en particulier les métaux detransition, est d’une grande importance pour la santé publique ainsi que pour la surveillancede l’environnement. Les méthodes actuelles de référence, de par leur non portabilité, limitentla possibilité de disposer de mesures à haute résolution spatiale et temporelle. Lesmicrocapteurs optiques offrent un moyen attrayant et pratique pour surmonter ces limitationsde coût global et de temps d’analyse, en permettant la mesure en temps réel sur site.Pour démontrer ce potentiel, ces travaux de thèse sont orientés sur la détermination duchrome hexavalent Cr(VI) en solution à l’aide d’une réaction colorimétrique avec le 1,5-diphénylcarbazide (DPC), permettant de créer un complexe présentant un maximumd’absorption dans le domaine du visible. Ces travaux s’inscrivent dans la volonté dedévelopper un véritable laboratoire sur puce, intégrant la fonction fluidique parélectromouillage sur diélectrique pour créer la réaction colorimétrique, ainsi que la fonctionde mesure par intégration d’un capteur optique dédié à la mesure d’absorption dans desmicrovolumes (< μL). Pour la mesure d'absorption sur de si faibles volumes, l'utilisation demicrorésonateurs vise à augmenter de façon importante le chemin optique effectif et ainsi lasensibilité du capteur.Nous décrivons nos travaux sur la conception, la fabrication de la plateformemicrofluidique digitale ainsi que du résonateur optique en anneaux à des dimensionssubmicroniques par photolithographie par projection. Les matériaux polymères sontprivilégiés pour une intégration totale bas coût à terme, ainsi qu’un substrat verre, dont lespropriétés sont particulièrement adaptées aux applications optiques dans le domaine duvisible

Self-contained microfluidic platform for general purpose lab-on-chip using pcb-mems technology.

El presente trabajo está centrado en la investigación de una nueva plataforma microfluídica autónoma para propósito general fabricada en PCBMEMS. En la vista de la proliferación en los últimos años de los sistemas microfluídicos Lab on Chip (LoC) y la multitud de aplicaciones en las que tienen cabida, surge la necesidad de creación de un sistema portable, autónomo y con una fabricación orientada hacia la producción masiva. En este contexto, se presenta el trabajo de esta tesis dentro de los proyectos de investigación de financiación nacional ISILAB (TEC2011-29045-C04-02) y BIOLOP (TEC2014-54449-C3-2- R). La tesis se encuentra organizada para cubrir los aspectos previamente propuestos. Primeramente, se presenta una introducción donde se explican los motivos para el desarrollo de este trabajo y cuáles son los objetivos específicos que se quieren cumplir. Seguidamente, se hace un breve estudio del arte. En este estudio se presenta la tecnología MEMS, los principios básicos de la microfluídica, que son los fundamentos de los sistemas LOCs y por último, se detalla un estudio de los principales elementos activos en la literatura que componen una plataforma microfluídica. Después de la introducción y revisión literaria del marco de esta tesis, se explican los resultados obtenidos. Esta tesis está desarrollada en dos fases principales: el desarrollo de todos los componentes que hacen un lab on chip autónomo de propósito general y el desarrollo de una tecnología basada en estándares para una producción masiva. En la primera fase se detallan los principales componentes que forman parte de una plataforma autónoma multifunción: microválvula, sistema de impulsión, circuito microfluídico y plataforma de sensado. Todos estos componentes son diseñados como un prototipo y están fabricados en SU-8 y PCBMEMS. El PCB permanece como sustrato y los canales y cámaras microfluídicas están fabricados en SU-8. La microválvula diseñada presenta una activación termoeléctrica, es de un solo uso y tiene una rápida activación y un consumo bajo de energía. Además, el diseño está pensado para ser altamente integrable en una plataforma microfluídica. El siguiente componente descrito es una sistema de impulsión basado en cámaras presurizadas, este sistema está integrado con la microválvula y su principal característica es la activación en el momento de uso, asegurando la ausencia de pérdidas. Para probar la validez de los componentes anteriores, se desarrolla un circuito microfluídico de propósito general. El circuito está diseñado para mezclar dos muestras y transportarlas a una cámara de detección. Finalmente, se desarrolla una plataforma para la detección de glucosa, integrable en el circuito microfluídico. Una vez desarrollado el prototipo, el siguiente objetivo de la tesis es el paso de la tecnología de prototipado hacía una de producción masiva. Para ello los materiales utilizados son el PMMA y el PCB. La tecnología PCBMEMS es conocida por su versatilidad para la integración de la electrónica, por lo que lo hace idóneo para la conexión con el exterior. El PMMA es un material también muy extendido en las aplicaciones microfluídicas, debido a su transparencia, bio compatibilidad y su fácil modelado. La unión de los dos componentes representa un desafío en el desarrollo de la tesis, debido a sus diferentes propiedades químicas. El proceso de fabricación se desarrolla integrando la microválvula y el sistema de impulsión, como partes de una plataforma microfluídica. Para terminar, se ha diseñado un pequeño circuito microfluídico para probar la viabilidad del sistema propuesto hacia una tecnología de gran escala. Finalmente, se exponen las conclusiones de la investigación, las posibles líneas futuras de este trabajo y los apéndices que complementan el trabajo de la tesis.The work presented is focused on the investigation of a new autonomous microfluidic platform manufactured using PCBMEMS technology for general purpose. With the proliferation of the microfluidic platforms, Lab on Chip (LoC), and the multitude of applications which have placed in the market, there is a need to create a self-contained microfluidic platform for general purpose with mass production-oriented manufacturing. Within this framework, the work of this thesis is presented. This is part of two national research project ISILAB (TEC2011-29045-C04-02) and BIOLOP (TEC2014-54449-C3-2- R). The thesis is organized to cover the aspects previously explained. Firstly, an introduction is presented with the motivation and objectives of this work. Subsequently, a study of the art is done. This study presents theMEMS technology, the basics principles of microfluidics, which are the pillars of the lab on chips and finally, a study of the main active elements presented in the literature. After the introduction and the literary revision of the framework of this thesis, the results obtained are presented. This thesis is developed in two main phases: the development of all components that make an autonomous general purpose lab on chip and the development of a standards-based technology for mass production. The first phase details the main components of an autonomous multifunction platform: microvalve, impulsion system, microfluidic circuit and sensing platform. All of these components are designed as a prototype and are manufactured in SU- 8 and PCBMEMS. The PCB remains as a substrate, and the microfluidic channels and chambers are manufactured in SU-8. The microvalve developed is a single use thermoelectrical microvalve with fast activation and low power consumption. In addition, the design is thought to be highly integrable in a microfluidic plat-form. The next component is a impulsion system based on pressurized chambers. The system is integrated with the microvalve and its main characteristic is the activation at the moment of use, ensuring the absence of losses. To test the validity of the above components, a general purpose microfluidic circuit is developed. The circuit is designed to mix two samples and transport those to a detection chamber. Finally, a platform for the detection of glucose, integrable in the microfluidic circuit, is developed. Once the prototype is achieved, the next objective of the thesis is the migration from prototyping technology to mass production. To this end, the materials used are PMMA and PCB. PCBMEMS technology is known for its versatility for the integration of electronics, making it suitable for electrical connection. PMMA is also widely used in microfluidic applications due to its transparency, bio compatibility and easy modeling. The union of the two components represents a challenge in the development of the thesis due to its different chemical properties. The manufacturing process is developed by integrating the microvalve and the drive system, as parts of a microfluidic platform. In conclusion, a small microfluidic circuit is designed by testing the feasibility of the proposed system towards large-scale technology. Finally, the conclusions of the research, the possible future lines of this work and the appendices that complement the work of the thesis are presented