An Analytical Model of Joule Heating in Piezoresistive Microcantilevers

The present study investigates Joule heating in piezoresistive microcantilever sensors. Joule heating and thermal deflections are a major source of noise in such sensors. This work uses analytical and numerical techniques to characterise the Joule heating in 4-layer piezoresistive microcantilevers made of silicon and silicon dioxide substrates but with the same U-shaped silicon piezoresistor. A theoretical model for predicting the temperature generated due to Joule heating is developed. The commercial finite element software ANSYS Multiphysics was used to study the effect of electrical potential on temperature and deflection produced in the cantilevers. The effect of piezoresistor width on Joule heating is also studied. Results show that Joule heating strongly depends on the applied potential and width of piezoresistor and that a silicon substrate cantilever has better thermal characteristics than a silicon dioxide cantilever

Comparison between Conduction and Convection Effects on Self-Heating in Doped Microcantilevers

The present study investigates the effects of thermal conduction and convection on self-heating temperatures and bimetallic deflections produced in doped microcantilever sensors. These cantilevers are commonly used as sensors and actuators in microsystems. The cantilever is a monolith, multi-layer structure with a thin U-shaped element inside. The cantilever substrate is made of silicon and silicon dioxide, respectively, and the element is p-doped silicon. A numerical analysis package (ANSYS) is used to study the effect of cantilever substrate material, element width, applied voltage and the operating environments on cantilever characteristics. The numerical results for temperature are compared against their analytical models. Results indicate the numerical results are accurate within 6% of analytical, and Si/Si cantilevers are more suitable for biosensors and AFM, whereas, Si/SiO2 are for hotplates and actuators applications

Thermomechanical Response of a Representative Porin for Biomimetics

The thermomechanical response of Omp2a, a representative porin used for the fabrication of smart biomimetic nanomembranes, has been characterized using microcantilever technology and compared with standard proteins. For this purpose, thermally induced transitions involving the conversion of stable trimers to bigger aggregates, local reorganizations based on the strengthening or weakening of intermolecular interactions, and protein denaturation have been detected by the microcantilever resonance frequency and deflection as a function of the temperature. Measurements have been carried out on arrays of 8-microcantilevers functionalized with proteins (Omp2a, lysozyme and bovine serum albumin). To interpret the measured nanofeatures, the response of proteins to temperature has been also examined using other characterization techniques, including real time wide angle X-ray diffraction. Results not only demonstrate the complex behavior of porins, which exhibit multiple local thermal transitions before undergoing denaturation at temperatures higher than 105 °C, but also suggest a posttreatment to control the orientation of immobilized Omp2a molecules in functionalized biomimetic nanomembranes and, thus, increase their efficacy in ion transport.Peer Reviewe

Electrostatic Excitation for the Force Amplification of Microcantilever Sensors

This paper describes an electrostatic excited microcantilever sensor operating in static mode that is more sensitive than traditional microcantilevers. The proposed sensor comprises a simple microcantilever with electrostatic excitation ability and an optical or piezoresistive detector. Initially the microcantilever is excited by electrostatic force to near pull-in voltage. The nonlinear behavior of the microcantilever in near pull-in voltage i.e., the inverse-square relation between displacement and electrostatic force provides a novel method for force amplification. In this situation, any external load applied to the sensor will be amplified by electrostatic force leading to more displacement. We prove that the proposed microcantilever sensor can be 2 to 100 orders more sensitive compared with traditional microcantilevers sensors of the same dimensions. The results for surface stress and the free-end point force load are discussed

Aptamers for Diagnostics with Applications for Infectious Diseases

Aptamers are in vitro selected oligonucleotides (DNA, RNA, oligos with modified nucleotides) that can have high affinity and specificity for a broad range of potential targets with high affinity and specificity. Here we focus on their applications as biosensors in the diagnostic field, although they can also be used as therapeutic agents. A small number of peptide aptamers have also been identified. In analytical settings, aptamers have the potential to extend the limit of current techniques as they offer many advantages over antibodies and can be used for real-time biomarker detection, cancer clinical testing, and detection of infectious microorganisms and viruses. Once optimized and validated, aptasensor technologies are expected to be highly beneficial to clinicians by providing a larger range and more rapid output of diagnostic readings than current technologies and support personalized medicine and faster implementation of optimal treatments

Cantilever Array Platform for Quantitative Biological Analysis

RÉSUMÉ L'objectif de ce projet est de développer un réseau de microcapteurs pour collecter des données biologiques quantitatives. Ces types de données peuvent être utilisés dans divers domaines, notamment pour l'analyse cellulaire et moléculaire, la détection d’interactions biologiques spécifiques, la surveillance de maladies et la découverte de médicaments. Les capteurs proposés possèdent des réseaux de « cantilevers » qui convertissent les interactions biologiques en variations mécaniques et électriques. Ces capteurs peuvent avoir une sensibilité élevée et ont montré leurs efficacités dans diverses applications. De plus, leur utilisation permet de concevoir un système à haut débit pour la détection en temps réel de diverses paramètres. Afin de développer ces capteurs, un logiciel multiphysique (COMSOL) a été utilisé pour modéliser les « cantilevers » et plusieurs simulations électromécaniques ont été réalisées pour atteindre une conception appropriée. Deux méthodes de lecture, piezorésistive et capacitive, ont été choisies pour être utilisées avec les capteurs. Les deux capteurs ont été fabriqués par le biais de CMC Microsystems; le processus PolyMUMPs a été employé pour la fabrication de réseaux de capteurs capacitifs, et les capteurs piézorésistifs, quant à eux, ont été développés par le processus de MetalMUMPs. Enfin, les capteurs fabriqués ont été caractérisés suivant différentes étapes incluant l’interferometrie afin d'assurer leur fonctionnalité. Sur la base des résultats de simulation et de caractérisation obtenus, ces capteurs peuvent être utilisés pour élaborer une plateforme haut débit à bas coût pour diverses applications biologiques.----------ABSTRACT The objective of the present project is to develop an array of microsensors for gathering cellular and molecular quantitative biological data. Such data can be used in various fields including cellular and molecular analysis, detection of specific biological interactions, monitoring diseases, and drug discovery. The proposed sensing platform in this project can convert biological interactions into mechanical variations and subsequently converts the mechanical variations to electrical ones. This platform offers the advantage of high sensitivity, real time measurement, high throughput sensing array suitable for fundamental studies as well as clinical applications. We modeled the operation of cantilevers using COMSOL multiphysics software. These simulation techniques can efficiently be used to choose the suitable design and dimensions of cantilevers. Two readout methods, piezoresistive and capacitive, have been chosen to be used along with sensors. Both sensors were fabricated through CMC Microsystems; PolyMUMPs process was employed for fabrication of capacitive sensor array and piezoresistive sensors were developed by MetalMUMPs process. The functionality of cantilevers and their incorporated sensors were characterized through different techniques including interferometry.Based on these simulation and characterization results, the proposed sensors can be good candidate for developing a low cost, high throughput platform for various biological applications

Alternative piezoresistor designs for maximizing cantilever sensitivity.

Over the last 15 years, researchers have explored the use of piezoresistive microcantilevers/resonators as gas sensors because of their relative ease in fabrication, low production cost, and their ability to detect changes in mass or surface stress with fairly good sensitivity. However, existing microcantilever designs rely on irreversible chemical reactions for detection and researchers have been unable to optimize symmetric geometries for increased sensitivity. Previous work by our group showed the capability of T-shaped piezoresistive cantilevers to detect gas composition using a nonreaction-based method – viscous damping. However, this geometry yielded only small changes in resistance. Recently, computational studies performed by our group indicated that optimizing the geometry of the base piezoresistor increases device sensitivity up to 700 times. Thus, the focus of this work is to improve the sensitivity of nonreaction-based piezoresistive microcantilevers by incorporating asymmetric piezoresistive sensing elements in a new array design. A three-mask fabrication process was performed using a 4 silicon-on-insulator wafer. Gold bond pads and leads were patterned using two optical lithography masks, gold sputtering, and acetone lift-off techniques. The cantilevers were patterned with electron-beam lithography and a dry etch masking layer was then deposited via electronbeam evaporation of iron. Subsequently, the silicon device layer was deep reactive ion etched (DRIE) to create the vertical sidewalls and the sacrificial silicon dioxide layer was removed with a buffered oxide etch, completely releasing the cantilever structures. Finally, the device was cleaned and dried with critical point drying to prevent stiction of the devices to the substrate. For the resonance experiments, the cantilevers were driven electrostatically by applying an AC bias, 10 Vpp, to the gate electrode. A DC bias of 10 V was placed across the piezoresistor in series with a 14 kÙ resistor. The drive frequency (0 – 80 kHz) was swept until the cantilever resonated at its natural frequency, which occurred when the output of the lock-in amplifier reached its maximum. These devices have been actuated to resonance under vacuum and their resonant frequencies and Qfactors measured. The first mode of resonance for the asymmetric cantilevers was found to range between 40 kHz and 63 kHz, depending on the piezoresistor geometry and length of the cantilever beam. The redesigned piezoresistive microcantilevers tested yielded static and dynamic sensitivities ranging from 1-6 Ù/Ìm and 2-17 Ù/Ìm displacement, respectively, which are 40 –730 times more sensitive than the best symmetric design previously reported by our group. Furthermore, the Q-factors ranged between 1700 and 4200, typical values for MEMS microcantilevers