Surface Acoustic Wave (SAW) Vibration Sensors

In the paper a feasibility study on the use of surface acoustic wave (SAW) vibration sensors for electronic warning systems is presented. The system is assembled from concatenated SAW vibration sensors based on a SAW delay line manufactured on a surface of a piezoelectric plate. Vibrations of the plate are transformed into electric signals that allow identification of the sensor and localization of a threat. The theoretical study of sensor vibrations leads us to the simple isotropic model with one degree of freedom. This model allowed an explicit description of the sensor plate movement and identification of the vibrating sensor. Analysis of frequency response of the ST-cut quartz sensor plate and a damping speed of its impulse response has been conducted. The analysis above was the basis to determine the ranges of parameters for vibrating plates to be useful in electronic warning systems. Generally, operation of electronic warning systems with SAW vibration sensors is based on the analysis of signal phase changes at the working frequency of delay line after being transmitted via two circuits of concatenated four-terminal networks. Frequencies of phase changes are equal to resonance frequencies of vibrating plates of sensors. The amplitude of these phase changes is proportional to the amplitude of vibrations of a sensor plate. Both pieces of information may be sent and recorded jointly by a simple electrical unit

Quantized Adiabatic Charge Transport in a Carbon Nanotube

The coupling of a metallic Carbon nanotube to a surface acoustic wave (SAW) is proposed as a vehicle to realize quantized adiabatic charge transport in a Luttinger liquid system. We demonstrate that electron backscattering by a periodic SAW potential, which results in miniband formation, can be achieved at energies near the Fermi level. Electron interaction, treated in a Luttinger liquid framework, is shown to enhance minigaps and thereby improve current quantization. Quantized SAW induced current, as a function of electron density, changes sign at half-filling.Comment: 5 pages, 2 figure

SURFACE ACOUSTIC WAVE (SAW)-ENHANCED SURFACE PLASMON RESONANCE (SPR) BIOSENSOR

The aim of this master thesis work was the realization of a biosensor based on surface plasmon resonance (SPR) which was integrated with surface acoustic wave (SAW)-driven microfluidics. Over the last 15 years SAW-induced mixers for microfluidic devices have been developed owing to their fast mixing capabilities. Meanwhile, SPR sensors have also been developed because of their high reliability and quantitative real-time measurements. Following the Drude model of electrical conduction, surface plasmons (SPs) can be considered as propagating electron density waves occurring at the interface between a metal and a dielectric and can alternatively be viewed as electromag- netic waves that are strongly bound to this interface. The resonance condition for SP excitation varies with the refractive index of the dielectric in the proximity (about 200 nm for visible light) of the surface of the metal film supporting the SP. A change in the resonance condition measured with an optical setup can be used to detect changes in the refractive index. SPR sensing is particularly useful for biological applications. By functionalizing the SPR sensor surface it is pos- sible to detect binding events in real-time and quantify the concentration of the analyte to be studied with high reliability. SPR biosensors have applications in numerous important fields including medical diagnostics, environmental mon- itoring, and food safety and security with resolution as low as 10 − 7 refractive index units (RIU) (§1). Lab-on-a-chip (LOC) devices are typically being developed for use in the life sciences and diagnostics and represent a fast moving field in which efforts are being made in order to increase portability and efficiency. Microfluidic systems are characterized by small Reynolds numbers which indicates that fluid flow is in general laminar. Efficient mixing is a challenge at these scales that can, how- ever, be overcome with the use of SAW-induced streaming. SAWs are mechanical oscillations which propagate along the surface of a given crystal. In piezoelectric materials they can be generated using interdigitated transducers (IDT), which are fabricated using thin-film metal deposition. When a SAW comes into con- tact with the edge of a liquid in its path, the acoustic energy diffracts into the fluid due to the mismatch between the sound velocity in the substrate and the liquid, causing a longitudinal pressure wave front that gives rise to the acoustic streaming. This phenomenon can be exploited to efficiently mix solutions with 1times that are significantly shorter than without SAWs (§2). By using micro- and nano- fabrication techniques (§3.1) a biosensor was de- veloped where SAW-driven active mixing and SPR sensing were integrated onto a common substrate. The optical setup (§3.4) was based on wavelength modula- tion and Kretschmann geometry where a polychromatic light is totally reflected through a high refractive index prism (on which the chip is placed). A spectrom- eter was used to analyze the reflected spectra. The SPR surface was functional- ized in order to study a biotin-streptavidin system (§3.3). SPR was first character- ized in droplets and then in polydimethylsiloxan (PDMS) microchannels (§3.2). By adding an IDT onto the chip it was possible to induce acoustic streaming in the channel while the biotin functionalization or the biotin-streptavidin event occurred. SAW was characterized by using a laser doppler vibrometer and a vector network analyzer. Owing to the chip design it was possible to decouple the two effects induced by SAW in the microchannel: streaming and heating. A thermocamera was used to study the second effect. The effect of the SAWs was studied both on the functionalization process and the streptavidin-biotin binding (§4). SAW streaming resulted in better surface functionalization than in the case without SAW. The signal due to the functionalization of gold with biotin was about 4.4 times higher than the signal detected without SAW-assisted functionalization. It is possible, then, to conclude that SAW streaming increases the probability that the biotin will be in contact with the gold surface and attach to it. Preliminary data also suggest better streptavidin biosensing than control device. The biosensor made for this master thesis work was the first SAW-driven mi- crofluidic device with SPR integrated on the same substrate. It showed promis- ing results that might be exploited for improving sensitivity and limit of detec- tion of SPR biosensors