An acoustic receiver and method for acoustic logging. The acoustic receiver comprises a housing and a sensor subassembly, which is located within the housing. The sensor subassembly comprises a mount and a cylindrical piezoelectric crystal coupled to the mount. The sensor subassembly also comprises an isolation ring positioned between one of the ends of the cylindrical piezoelectric crystal and the mount. The isolation ring directly engages the crystal and the mount. The method of acoustic logging comprises receiving an acoustic signal using an acoustic receiver, which comprises a cylindrical piezoelectric crystal coupled to a mount without an adhesive material. The method also comprises converting the acoustic signal into an electrical signal by the cylindrical piezoelectric crystal and transmitting the electrical signal to a processor via a conductor coupled to the cylindrical piezoelectric crystal.

Sensors, as well as systems and methods of using the same are provided. Aspects of the sensors include a piezoelectric base, a plurality of surface-associated compositions that are stably associated with the piezoelectric base, and a plurality of crosslinking compositions that are configured to crosslink one or more surface-associated compositions in the presence of an analyte. The sensors, systems and methods described herein find use in a variety of applications, including the detection of an analyte in a sample.

A system includes a structure bonding layer and a sensor. The structure bonding layer is disposed on a structure. The structure bonding layer is a metallic alloy. The sensor includes a non-metallic wafer and a sensor bonding layer disposed on a surface of the non-metallic wafer. The sensor bonding layer is a metallic alloy. The sensor bonding layer is coupled to the structure bonding layer via a metallic joint, and the sensor is configured to sense data of the structure through the metallic joint, the structure bonding layer, and the sensor bonding layer.

A surface acoustic wave sensor in which instrument drift resulting from accumulated surface contamination is minimized. The sensor includes a piezeoelectric substrate defined by an outer surface and a plurality of interdigitated electrodes mounted thereon. The electrodes are defined by one or more exposed portions and an unexposed portion abutting the outer surface of the piezoelectric substrate. An inert coating layer on the outer surface of the piezoelectric substrate and the exposed portions of the electrodes is provided, and can be a perfluoro-silane type compound, a perfluoro-trichloro-silane type compound, a perfluoro-acrylate type compound, polytetrafluoroethylene, or heptadecafluorodecyltrimethoxysilane.

A biosensor assembly includes a plurality of biosensor units which are juxtaposed next to one another. Respective portions of a continuous piezoelectric monocrystal layer are dedicated to the biosensor units, and Bragg solid bulk structures are arranged on the piezoelectric layer between the portions thereof that pertain to neighboring biosensor units. Each Bragg structure has a pattern repetition direction that is parallel to the piezoelectric layer, and is designed for confinement of elastic vibrations and suppressing cross-talk between the biosensor units. The biosensor assembly can be manufactured from a piezoelectric wafer with low cost price.

A crystal oscillation probe structure and an evaporation device are provided. The crystal oscillation probe structure includes a guide cover, a crystal oscillation probe and a mesh screen structure, the guide cover includes a chamber with a guide opening, the crystal oscillation probe is fixed in the chamber, the crystal oscillation probe includes at least one crystal oscillation sheet, the mesh screen structure includes a plurality of openings, and the mesh screen structure is located on a traveling path of a material traveling toward the at least one crystal oscillation sheet and disposed on a side of the at least one crystal oscillation sheet facing the guide opening.

Operational configuration and temperature compensation methods are provided for bulk acoustic wave (BAW) resonator devices suitable for operating with liquids. Temperature compensation methods dispense with a need for temperature sensing, instead utilizing a relationship between (i) change in frequency of a BAW resonator at a phase with adequate sensitivity and (ii) change in frequency of a phase that is correlated to temperature. Operational configuration methods include determination of an initial phase response of a BAW resonator in which temperature coefficient of frequency is zero, followed by comparison of sensitivity to a level of detection threshold for a phenomenon of interest.

Gas sensors are provided. The gas sensors comprise: a substrate; a plurality of electrodes on the substrate; and a polymeric sensing layer on the substrate for adsorbing a gas-phase analyte. The adsorption of the analyte is effective to change a property of the gas sensor that results in a change in an output signal from the gas sensor. The polymeric sensing layer comprises a polymer chosen from substituted or unsubstituted polyarylenes comprising the reaction product of monomers comprising a first monomer comprising an aromatic acetylene group and a second monomer comprising two or more cyclopentadienone groups, or a cured product of the reaction product. The gas sensors and methods of using such sensors find particular applicability in the sensing of gas-phase organic analytes.

A measuring device for measuring parameters of a piezoelectric crystal onto which a thin film of material is deposited (under vacuum). The crystal includes two spaced-apart electrodes. A frequency generator is adapted to generate an oscillator signal at a specified output frequency. A measuring amplifier is adapted to apply the oscillator signal as a drive signal to one of the electrodes of the crystal and to provide a crystal output signal in response to the drive signal. A quadrature demodulator is adapted to down convert the crystal output signal and to provide an in-phase output signal and a quadrature output signal. A computation unit is adapted to determine one or more parameters of the crystal based on the in-phase output signal and the quadrature output signal. Furthermore, there is provided a corresponding measuring method as well as to thin-film deposition systems (including a vacuum chamber) with such a device and methods for controlling such systems.

A method of making a sensor comprises depositing a plurality of surface-associated compositions on a piezoelectric base. The plurality of surface-associated compositions are adapted to stably associate with the piezoelectric base. The method further comprises depositing a plurality of crosslinking compositions on top of the surface-associated compositions. The crosslinking compositions are configured to bind to an analyte and crosslink one or more of the surface-associated compositions when the analyte binds to an analyte binding domain of a crosslinking composition and the surface-associated compositions include one or more polyclonal antibodies.