Basic Study Of Micromachined Dep (dielectrophoretic) Manipulator

Sundaram, Vivek

01 January 2004

The capability of manipulating microparticle in small volumes is fundamental to many biological and medical applications, including separation and detection of cells. The development of microtools for effective sample handling and separation in such volumes is still a challenge. DEP (dielectrophoresis) is one of the most widely used methods in handling the microparticles. In this thesis we show that forces generated by nonuniform electric field (DEP) can be used for trapping and separating the microparticles (latex beads). This work further explores the DEP force based on different electrode geometries and medium conductivity. A micromanipulator for latex bead separation was designed, fabricated and characterized. For the development of DEP manipulator, the fabrication and packaging of microfluidic structure with the microelectrode is crucial for reliable analysis. A combination of SU-8 photoresist and polydimethylsiloxane polymer was used for this purpose. Besides, the DEP manipulator, preliminary study on a Coulter counter was conducted. The Coulter counter works on the principle of resistive pulse sensing. This counter is used for counting the beads as they pass through the microfluidic channel. Its possible integration with the manipulator was also explored.

Coulter counter

Dielectrophoresis

Interdigitated electrodes

PDMS

SU 8

Electrical and Computer Engineering

Engineering

Design And Fabrication Of Chemiresistor Typemicro/nano Hydrogen Gas Sensors Usinginterdigitated Electrodes

Zhang, Peng

01 January 2008

Hydrogen sensors have obtained increased interest with the widened application of hydrogen energy in recent years. Among them, various chemiresistor based hydrogen sensors have been studied due to their relatively simple structure and well-established detection mechanism. The recent progress in micro/nanotechnology has accelerated the development of small-scale chemical sensors. In this work, MEMS (Micro-Electro-Mechanical Systems) sensor platforms with interdigitated electrodes have been designed and fabricated. Integrating indium doped tin dioxide nanoparticles, these hydrogen sensors showed improved sensor characteristics such as sensitivity, response and selectivity at room temperature. Design parameters of interdigitated electrodes have been studied in association with sensor characteristics. It was observed that these parameters (gap between the electrodes, width and length of the fingers, and the number of the fingers) imposed different impacts on the sensor performance. In order to achieve small, robust, low cost and fast hydrogen micro/nano sensors with high sensitivity and selectivity, the modeling and process optimization was performed. The effect of humidity and the influence of the applied voltage were also studied. The sensor could be tuned to have high sensitivity (105), fast response time (10 seconds) and low energy consumption (19 nW). Finally, a portable hydrogen instrument integrated with a micro sensor, display, sound warning system, and measurement circuitry was fabricated based on the calibration data of the sensor.

Hydrogen Sensor

Micro ElectroMechanical System

Nano Technoloty

Interdigitated Electrodes

Engineering

Mechanical Engineering

Synthesis, characterization, microfabrication and biological applications of conducting polymers

Yang, Yanyin

10 October 2005

No description available.

Biophysics, Medical

Bone cell growth

Conducting polymers

Electrical Stimulation

Interdigitated electrodes

Microfabrication, Modeling, and Characterization of BioMEMS Platforms for Interfacing with Multisized Biological Entities for In-vitro Studies

Manrique Castro, Jorge E

01 January 2023

The main objective of the research in this dissertation is to take advantage of unique materials, innovative designs, novel microfabrication techniques, and specialized characterization tools to develop a set of BioMEMS devices and systems further validated with electrical, interface, geometric, and multiphysics models to address unique biological problems emanating from ethical treatment of animals in drug discovery, biological translation, decentralization and personalization of healthcare. This set of devices is designed to interface with multi-sized biological constructs such as 3D cellular networks, viruses, and proteins. The first objective explored a 3D printing-based microfabrication technology to create 2.5D/3D microelectrodes to interface with cellular constructs such as tissues and organoids. Investigations were carried out on how surface roughness and printing parameters play a critical role in the electrical response of the system for in-vitro applications. Three different metallization strategies were investigated and modeled in order to define novel self-insulated 2.5 and 3D microelectrodes. The second objective centered around virus and microparticle detection using a novel combination of microfluidics and Wi-Fi optical detection. Microfluidics were created designing a multilayered system and processing various polymeric materials. The optical system was able to detect and wirelessly transmit information about the presence of viruses including COVID-19 Delta strain and microparticles in the 5 to 10 microns size. The last objective of the dissertation presented the microfabrication of a BioMEMS platform for electrophysiological characterization of Actin protein (smallest entity within the size spectrum). This platform combined interdigitated electrodes, PDMS soft lithography, and impedance and interface modeling to better understand Actin protein dynamics in bundles. This dissertation proposes innovative ideas to the current state of the art for emerging paradigms in the medical technology field involving rapid sensing and manipulating biological entities at various size scales: (proteins, DNA/RNA), (pathogens, virus), and (organoids, spheroids, assembloids).

3D printing

microfluidics

biomems

microfabrication

electrochemical impedance spectroscopy

microelectrode arrays

interdigitated electrodes

modeling

interface

metallization

A Two Dimensional Model of a Direct Propane Fuel Cell with an Interdigitated Flow Field

Khakdaman, Hamidreza

18 April 2012

Increasing environmental concerns as well as diminishing fossil fuel reserves call for a new generation of energy conversion technologies. Fuel cells, which convert the chemical energy of a fuel directly to electrical energy, have been identified as one of the leading alternative energy conversion technologies. Fuel cells are more efficient than conventional heat engines with minimal pollutant emissions and superior scalability. Proton Exchange Membrane Fuel Cells (PEMFCs) which produce electricity from hydrogen have been widely investigated for transportation and stationary applications. The focus of this study is on the Direct Propane Fuel Cell (DPFC), which belongs to the PEMFC family, but consumes propane instead of hydrogen as feedstock. A drawback associated with DPFCs is that the propane reaction rate is much slower than that of hydrogen. Two ideas were suggested to overcome this issue: (i) operating at high temperatures (150-230oC), and (ii) keeping the propane partial pressure at the maximum possible value. An electrolyte material composed of zirconium phosphate (ZrP) and polytetrafluoroethylene (PTFE) was suggested because it is an acceptable proton conductor at high temperatures. In order to keep the propane partial pressure at the maximum value, interdigitated flow-fields were chosen to distribute propane through the anode catalyst layer. In order to evaluate the performance of a DPFC which operates at high temperature and uses interdigitated flow-fields, a computational approach was chosen. Computational Fluid Dynamics (CFD) was used to create two 2-D mathematical models for DPFCs based on differential conservation equations. Two different approaches were investigated to model species transport in the electrolyte phase of the anode and cathode catalyst layers and the membrane layer. In the first approach, the migration phenomenon was assumed to be the only mechanism of proton transport. However, both migration and diffusion phenomena were considered as mechanisms of species transport in the second approach. Therefore, Ohm's law was used in the first approach and concentrated solution theory (Generalized Stefan-Maxwell equations) was used for the second one. Both models are isothermal. The models were solved numerically by implementing the partial differential equations and the boundary conditions in FreeFEM++ software which is based on Finite Element Methods. Programming in the C++ language was performed and the existing library of C++ classes and tools in FreeFEM++ were used. The final model contained 60 pages of original code, written specifically for this thesis. The models were used to predict the performance of a DPFC with different operating conditions and equipment design parameters. The results showed that using a specific combination of interdigitated flow-fields, ZrP-PTFE electrolyte having a proton conductivity of 0.05 S/cm, and operating at 230oC and 1 atm produced a performance (polarization curve) that was (a) far superior to anything in the DPFC published literature, and (b) competitive with the performance of direct methanol fuel cells. In addition, it was equivalent to that of hydrogen fuel cells at low current densities (30 mA/cm2).

PEM fuel cells

Direct propane fuel cells

Mathematical modeling

Electrolyte model

Proton diffusion

FreeFEM

Interdigitated flow field

A Two Dimensional Model of a Direct Propane Fuel Cell with an Interdigitated Flow Field

Khakdaman, Hamidreza

18 April 2012

Increasing environmental concerns as well as diminishing fossil fuel reserves call for a new generation of energy conversion technologies. Fuel cells, which convert the chemical energy of a fuel directly to electrical energy, have been identified as one of the leading alternative energy conversion technologies. Fuel cells are more efficient than conventional heat engines with minimal pollutant emissions and superior scalability. Proton Exchange Membrane Fuel Cells (PEMFCs) which produce electricity from hydrogen have been widely investigated for transportation and stationary applications. The focus of this study is on the Direct Propane Fuel Cell (DPFC), which belongs to the PEMFC family, but consumes propane instead of hydrogen as feedstock. A drawback associated with DPFCs is that the propane reaction rate is much slower than that of hydrogen. Two ideas were suggested to overcome this issue: (i) operating at high temperatures (150-230oC), and (ii) keeping the propane partial pressure at the maximum possible value. An electrolyte material composed of zirconium phosphate (ZrP) and polytetrafluoroethylene (PTFE) was suggested because it is an acceptable proton conductor at high temperatures. In order to keep the propane partial pressure at the maximum value, interdigitated flow-fields were chosen to distribute propane through the anode catalyst layer. In order to evaluate the performance of a DPFC which operates at high temperature and uses interdigitated flow-fields, a computational approach was chosen. Computational Fluid Dynamics (CFD) was used to create two 2-D mathematical models for DPFCs based on differential conservation equations. Two different approaches were investigated to model species transport in the electrolyte phase of the anode and cathode catalyst layers and the membrane layer. In the first approach, the migration phenomenon was assumed to be the only mechanism of proton transport. However, both migration and diffusion phenomena were considered as mechanisms of species transport in the second approach. Therefore, Ohm's law was used in the first approach and concentrated solution theory (Generalized Stefan-Maxwell equations) was used for the second one. Both models are isothermal. The models were solved numerically by implementing the partial differential equations and the boundary conditions in FreeFEM++ software which is based on Finite Element Methods. Programming in the C++ language was performed and the existing library of C++ classes and tools in FreeFEM++ were used. The final model contained 60 pages of original code, written specifically for this thesis. The models were used to predict the performance of a DPFC with different operating conditions and equipment design parameters. The results showed that using a specific combination of interdigitated flow-fields, ZrP-PTFE electrolyte having a proton conductivity of 0.05 S/cm, and operating at 230oC and 1 atm produced a performance (polarization curve) that was (a) far superior to anything in the DPFC published literature, and (b) competitive with the performance of direct methanol fuel cells. In addition, it was equivalent to that of hydrogen fuel cells at low current densities (30 mA/cm2).

PEM fuel cells

Direct propane fuel cells

Mathematical modeling

Electrolyte model

Proton diffusion

FreeFEM

Interdigitated flow field

A Two Dimensional Model of a Direct Propane Fuel Cell with an Interdigitated Flow Field

Khakdaman, Hamidreza

January 2012

Increasing environmental concerns as well as diminishing fossil fuel reserves call for a new generation of energy conversion technologies. Fuel cells, which convert the chemical energy of a fuel directly to electrical energy, have been identified as one of the leading alternative energy conversion technologies. Fuel cells are more efficient than conventional heat engines with minimal pollutant emissions and superior scalability. Proton Exchange Membrane Fuel Cells (PEMFCs) which produce electricity from hydrogen have been widely investigated for transportation and stationary applications. The focus of this study is on the Direct Propane Fuel Cell (DPFC), which belongs to the PEMFC family, but consumes propane instead of hydrogen as feedstock. A drawback associated with DPFCs is that the propane reaction rate is much slower than that of hydrogen. Two ideas were suggested to overcome this issue: (i) operating at high temperatures (150-230oC), and (ii) keeping the propane partial pressure at the maximum possible value. An electrolyte material composed of zirconium phosphate (ZrP) and polytetrafluoroethylene (PTFE) was suggested because it is an acceptable proton conductor at high temperatures. In order to keep the propane partial pressure at the maximum value, interdigitated flow-fields were chosen to distribute propane through the anode catalyst layer. In order to evaluate the performance of a DPFC which operates at high temperature and uses interdigitated flow-fields, a computational approach was chosen. Computational Fluid Dynamics (CFD) was used to create two 2-D mathematical models for DPFCs based on differential conservation equations. Two different approaches were investigated to model species transport in the electrolyte phase of the anode and cathode catalyst layers and the membrane layer. In the first approach, the migration phenomenon was assumed to be the only mechanism of proton transport. However, both migration and diffusion phenomena were considered as mechanisms of species transport in the second approach. Therefore, Ohm's law was used in the first approach and concentrated solution theory (Generalized Stefan-Maxwell equations) was used for the second one. Both models are isothermal. The models were solved numerically by implementing the partial differential equations and the boundary conditions in FreeFEM++ software which is based on Finite Element Methods. Programming in the C++ language was performed and the existing library of C++ classes and tools in FreeFEM++ were used. The final model contained 60 pages of original code, written specifically for this thesis. The models were used to predict the performance of a DPFC with different operating conditions and equipment design parameters. The results showed that using a specific combination of interdigitated flow-fields, ZrP-PTFE electrolyte having a proton conductivity of 0.05 S/cm, and operating at 230oC and 1 atm produced a performance (polarization curve) that was (a) far superior to anything in the DPFC published literature, and (b) competitive with the performance of direct methanol fuel cells. In addition, it was equivalent to that of hydrogen fuel cells at low current densities (30 mA/cm2).

PEM fuel cells

Direct propane fuel cells

Mathematical modeling

Electrolyte model

Proton diffusion

FreeFEM

Interdigitated flow field

Dispositif microfluidique pour la quantification de sous-populations de cellules / Microfluidic device for quantification of subpopulations of cells

Manczak, Rémi

27 January 2016

La détection quantitative de cellule est généralement réalisée par cytométrie en flux en raison de sa haute sensibilité, cependant cette technique est difficile à mettre en oeuvre pour des analyses de routine ou des analyses au chevet du patient. Les méthodes électrochimiques et en particulier la spectroscopie d'impédance électrochimique ont gagné en popularité en raison de la possibilité de réaliser des analyses sans marquage et de miniaturiser les systèmes d'analyse pour une intégration sur puce. De plus, les avancées récentes dans le domaine des technologies de microfabrication ont permis de développer des électrodes micrométriques ayant de nombreux avantages tels que des hautes impédances dues à des courants très faibles ainsi que la possibilité de les intégrer dans des systèmes microfluidiques. L'objectif de ce travail de thèse se concentre sur la réalisation et l'optimisation de dispositifs microfluidiques contenant les systèmes d'électrodes pour le piégeage immunologique et le comptage impédimétrique de monocytes pro-inflammatoires, marqueurs d'une infection. Compte tenu de l'influence du taux de recouvrement de la surface sur la sensibilité, plusieurs géométries d'électrodes ont été testées. Les meilleures sensibilités et reproductibilités ont été obtenues dans le cas de microélectrodes interdigitées ayant de faibles espaces inter-électrodes (50 µm). D'autre part les études ont également permis de montrer dans ce cas, que la gamme de concentration cellulaire pour laquelle la sensibilité était maximale dépendait de la surface de l'électrode. Les électrodes de plus petites surfaces ont permis d'atteindre une limite de détection inférieure à 10 cellules/mL. De plus, compte tenu de la grande sensibilité des dispositifs ainsi réalisés, ces systèmes ont également été testés pour la caractérisation d'interaction récepteurs-ligands à partir de cellules entières. Ces études ont permis de mettre en évidence l'interaction de cellules CHO exprimant le récepteur A2a à des ligands c-di-AMP pour de très faibles concentrations cellulaires. / The quantitative detection of specific cells is usually carried out by flow cytometry due to its high sensitivity and reliability, however, this technique is not suited for routine screening and point-of-care diagnostics. Electrochemical methods, as electrochemical impedance spectroscopy have gained interest mainly due to a label-free detection and their miniaturization capability required for integration on chip. Furthermore, recent advances in microfabrication based technologies have allowed to develop micron-sized electrodes whose main advantages over conventional electrodes are higher impedances due to smaller currents and the possibility of being integrated inside microfluidic channels. The aim of the present work was the realization and the optimization of microfluidic devices with improved sensitivity targeting the immuno-trapping and counting of pro-inflammatory monocytes as infection markers. Taking into account the influence of the surface coverage on the sensitivity, different geometries were tested. The best sensitivities and reproducibility were recorded in the case of interdigitated micro-electrodes with weak inter-electrodes gap (50 µm). Moreover, experiments carried out with different surfaces demonstrated that there was a threshold beyond which a surface is exploitable for a given slice of concentration. Such microfluidic devices allowed to reach a detection limit around 10 cells/mL. Furthermore, due to the high sensitivity recorded, the devices were also tested to detect ligand binding by cell receptors. These studies have allowed to demonstrate the interaction of CHO-A2a with c-di-AMP for low cell concentrations.

Immunocapteur

Diagnostic

Microfluidique

Microélectrodes interdigitées

Sensibilité

Electrochemical impedance spectroscopie

Immunosensor

Diagnostic

Microfluidic

Interdigitated microelectrodes

Cell sorting

Growth Parameter Dependence and Correlation of Native Point Defects and Dielectric Properties in Ba_xSr_1-xTiO₃ Grown by Molecular Beam Epitaxy

Rutkowski, Mitchell M.

09 August 2013

No description available.

Physics

Molecular Beam Epitaxy

Native Point Defect

Thin Film Growth

Barium Strontium Titanate

Interdigitated Capacitors

Optoelectronic Simulation of Perovskite, All Back Contact, Metasurface Photovoltaic Devices

Sibila, Matthew

29 August 2022

No description available.

Physics

Photovoltaics

Perovskite

Metasurfaces

Lattice back contact

quasi-interdigitated back contact

all back contact

optoelectronic simulation

photovoltaic design

computer modeling