Acoustic wave biosensor arrays for the simultaneous detection of multiple cancer biomarkers

Wathen, Adam Daniel

11 August 2011

The analysis and development of robust sensing platforms based on solidly-mounted ZnO bulk acoustic wave devices was proposed. The exploitation of acoustic energy trapping was investigated and demonstrated as a method to define active sensing areas on a substrate. In addition, a new "hybrid" acoustic mode experiencing acoustic energy trapping was studied theoretically and experimentally. This mode was used as an explanation of historical inconsistencies in observed thickness-shear mode velocities. Initial theoretical and experimental results suggest that this mode is a coupling of thickness-shear and longitudinal particle displacements and, as such, may offer more mechanical and/or structural information about a sample under test. Device development was taken another step further and multi-mode ZnO resonators operating in the thickness-shear, hybrid, and longitudinal modes were introduced. These devices were characterized with respect to sample viscosity and conductivity and preliminary results show that, with further development, the multi-mode resonators provide significantly more information about a sample than their single-mode counterparts. An alternative to resonator-based platforms was also presented in the form of bulk acoustic delay lines. Initial conceptual and simulation results show that these devices provide a different perspective of typical sensing modalities by using properly designed input pulses, device tuning, and examining overall input and output signal spectra.

ZNO

Bulk acoustic wave

Energy trapping

Acoustic sensors

Biosensors

Bulk acoustic delay line

SMR

Biosensors

Biochemical markers

Tumor markers

Acoustic surface wave devices

Acoustics in nanotechnology: manipulation, device application and modeling

Buchine, Brent Alan

19 December 2007

Advancing the field of nanotechnology to incorporate the unique properties observed at the nanoscale into functional devices has become a major scientific thrust of the 21st century. New fabrication tools and assembly techniques are required to design and manufacture devices based on one-dimensional nanostructures. Three techniques for manipulating nanomaterials post-synthesis have been developed. Two of them involve direct contact manipulation through the utilization of a physical probe. The third uses optically generated surface acoustic waves to reproducibly control and assemble one-dimensional nanostructures into desired locations. The nature of the third technique is non-contact and limits contamination and defects from being introduced into a device by manipulation. While the effective manipulation of individual nanostructures into device components is important for building functional nanosystems, commercialization is limited by this one-device-at-a-time process. A new approach to nanostructure synthesis was also developed to site-specifically nucleate and grow nanowires between two electrodes. Integrating synthesis directly with prefabricated device architectures leads to the possible mass production of NEMS, MEMS and CMOS systems based upon one-dimensional nanomaterials. The above processes have been pursued to utilize piezoelectric ZnO nanobelts for applications in high frequency electronic filtering as well as biological and chemical sensing. The high quality, single crystal, faceted nature of these materials make them ideal candidates for studying their properties through the designs of a bulk acoustic resonator. The first ever piezoelectric bulk acoustic resonator based on bottom-up synthesized belts will be demonstrated. Initial results are promising and new designs are implemented to scale the device to sub-micron dimensions. Multiple models will be developed to assist with design and testing. Some of models presented will help verify experimental results while others will demonstrate some of the problems plaguing further investigations.

Nanoscience

Nanotechnology

Acoustics

Manipulation

Nanowires

Nanobelts

Bulk acoustic wave devices

Resonator

Zinc oxide

ZnO

ISTS

Nanotechnology

Acoustic surface waves

Nanostructured materials Synthesis

Mass production

Dispositf acoustique pour l'isolation galvanique : le CMUT, une voie innovante / Galvanic isolation by acoustic device : the CMUT, an innovative solution

Ngo, Sophie

17 October 2013

Les dispositifs d’isolation galvanique intégrés au sein des systèmes de commande d’interrupteurs de puissance doivent répondre à une demande accrue en performance, facilité d’intégration et efficacité énergétique. Les transducteurs ultrasonores capacitifs micro-usinés (cMUT : capacitive Micromachined Ultrasonic Transducer), capables d’émettre et de recevoir des ondes ultrasonores, semblent une alternative tout à fait nouvelle à la fonction d’isolation galvanique. Ces travaux de thèse ont pour objectif de démontrer la faisabilité d’un dispositif basé sur la technologie cMUT. Le principe de fonctionnement consiste à transmettre une information grâce à une communication par onde acoustique de volume entre deux réseaux de cMUT placés de part et d’autre d’un substrat. Nous focalisons, en premier lieu, ces travaux sur le processus de fabrication par micro-usinage de surface des cMUT ainsi que les techniques de réalisation des dispositifs en structure double face sur substrat de silicium. L’étude permet d’identifier le collage de substrat comme une solution de fabrication industrialisable. Suite à la réalisation des dispositifs, la caractérisation électro-mécanique des cMUT est une étapeessentielle à la validation de leur fonctionnalité en tant que dispositifs émetteurs. L’étude débute par uneévaluation des propriétés mécaniques du matériau constituant la membrane et qui impactent directementle comportement global des cMUT. Puis, la caractérisation du comportement statique et dynamique descMUT permet d’extraire les paramètres tels que la fréquence de résonance, la tension de collapse etl’efficacité électro-mécanique qui définissent le mode de pilotage d’un tel système.Finalement, la validation du concept de transmission et de détection d’ondes ultrasonores est réaliséegrâce à des mesures de vibrométrie laser Doppler. Les résultats apportent des éléments de réponse quantau mode de propagation des ondes et permettent d’identifier les topologies de meilleure efficacité entransmission acoustique. Enfin, l’intégration du prototype dans l’application de commanded’interrupteur de puissance démontre la faisabilité du concept de transformateur acoustique basé sur latechnologie cMUT. / Galvanic isolation devices integrated into switch command systems must be able to answer all of the increasing demand for performance, energetic efficiency and integration easiness. The capacitive micro machined ultrasonic transducers (cMUT), able to emit and receive ultrasounds, could be an entirely new alternative to the function of galvanic isolation. This work aims to demonstrate the feasibility of a cMUT-based device. The operating principle consists in transmitting information thanks to a bulk acoustic wave between two cMUT arrays located on both sides of a substrate. We first focus on cMUT surface micromachining fabrication process and techniques of double-side device manufacturing. Our study allows us to identify wafer bonding as a realistic industrial solution. After device fabrication, electro-mechanical of cMUT is an essential step to validate their functionality as ultrasonic emitters. The study starts with the mechanical properties evaluation of the membrane material. These properties directly impact the global behavior of cMUT. Then, the characterization of cMUT static and dynamic behavior allows extracting parameters as resonance frequency, collapsing voltage and electro-mechanical efficiency which define the actuation mode of such a system. Finally, the validation of transmission and reception of ultrasonic waves is evaluated by vibrometer laser Doppler measurements. Results bring elements concerning the waves propagation modes and allow identifying the best acoustical efficiency in regard to the topology. In conclusion, the prototype integration in the application of power switch command demonstrates the feasibility of acoustic transformer concept based on cMUT technology.

Isolation galvanique

CMUT

Ultrasons

Onde acoustique de volume

Micro-usinage de surface

Vibrométrie laser Doppler

Transformateur acoustique

Galvanic isolation

CMUT

Bulk acoustic wave

Surface micro-machining

Vibrometer laser Doppler

Power switch

Acoustic transformer