Devices that include a low sensitivity bulk acoustic wave (BAW) resonator sensor including a surface to which a low recognition component is immobilized, the low recognition component being configured to selectively bind the analyte, an analyte molecule to which a tag is linked, or a tag, or any one of these molecules to which an amplification element-linked second recognition component is bound; a high sensitivity BAW resonator sensor including a surface to which a high recognition component is immobilized, the high recognition component being configured to selectively bind the analyte, an analyte molecule to which a tag is linked, or a tag, or any one of these molecules to which an amplification element-linked second recognition component is bound; one or more containers housing an amplification molecule, the amplification element-linked second recognition component, and optionally one or both of the tag and the analyte molecule.

Composite films comprising an organic salt (or GUMBOS) such as 1-n-butyl-2,3-dimethylimidazolium hexafluorophosphate and a polymer such as cellulose acetate are prepared. These films are useful in detecting vapors of volatile organic compounds, and in determining their molecular weights. A quartz crystal microbalance-based sensor was designed by depositing a thin film of this composite material on the gold electrode surface of a quartz crystal resonator. The sensor exhibited rapid response toward a variety of volatile organic compounds, and complete regeneration, high sensitivity, low detection limits, and wide dynamic ranges. The ratio of the change in frequency to the change in motional resistance is a concentration-independent quantity that is proportional to the molecular weight of the absorbed chemical species. These properties facilitate the easy identification and molecular weight determination of a broad range of organic vapors.

Methods are provided for characterizing the stability of a distillate fraction using a quartz crystal microbalance apparatus, such as a distillate fraction derived at least in part from a pre-refined crude oil. A sample can be aged for an aging period in a quartz crystal microbalance apparatus, and a frequency value for the sample in the quartz crystal microbalance apparatus can be determined before and after the aging period to determine a frequency difference. This frequency difference can be correlated directly with the ability of a jet fuel fraction to satisfy a stability test standard, such as a jet fuel breakpoint stability. The methods can also include using a temperature profile during characterization that can reduce or minimize operator error during the characterization.

Redox of an analyte is coupled with redox of a precipitation precursor to generate a precipitating molecule that precipitates on the surface of a thin film bulk acoustic resonance (TFBAR) to allow mass detection of the precipitation molecule as a surrogate for the analyte. This disclosure describes, among other things, detection of an analyte using a TFBAR operating at a high frequency without direct binding of the analyte on a surface of the TBAR. Detection of the analyte is indirect with a precipitating molecule serving as a surrogate for the analyte.

A sensing sensor includes a wiring board, a piezoelectric resonator, and a gel-like protective agent. The piezoelectric resonator has one surface side on which an adsorbing film is formed. The adsorbing film is constituted of biomolecules. The protective agent is disposed so as to cover a surface of the adsorbing film. The protective agent is configured to suppress an inactivation of the biomolecules. The channel forming member is disposed so as to cover a region of the one surface side of the wiring board including the piezoelectric resonator. The channel forming member includes an injection port of the sample solution. The flow passage is disposed between the wiring board and the channel forming member. The flow passage is configured to allow the sample solution supplied to the injection port to flow from one end side to another end side on the one surface side of the piezoelectric resonator.

A measuring assembly and method for layer thickness measurement of a layer applied to a substrate by means of a vapor deposition method includes a measuring head which is provided with at least one vibration plate, an extraction line which can be coupled in a gas-conducting or vapor-conducting manner with a first end having a vacuum chamber for the vapor deposition method and which can be coupled in a gas-conducting or vapor-conducting manner with an opposite second end having the measuring head, wherein the extraction line includes at least one heating section or at least one cooling section.

Disclosed are methods for determining and classifying aircraft air contaminants comprising one or more of: turbine engine oil, hydraulic fluid and deicing fluid using contaminant analyzers comprising a contaminant collector comprising a membrane and a heater vaporizing the contaminants; a gravimetric sensor generating a response when contaminant mass is added to or removed from the sensor, the sensor receiving contaminants desorbed from the heated membrane; a frequency measurement device, measuring the response generated by the sensor as the contaminant is added to and removed from the sensor; a computer readable medium bearing a contaminant recognition program and calibration data; a processor executing the program, the program including a module classifying contaminants by type, and a module using the data for comparison with magnitude of response generated by the sensor to calculate contaminant concentration; and, a pump, generating flow of air through the collector before and after the membrane is heated.

An object of the present invention is to provide a resonant sensor having excellent sensitivity and selectivity with respect to a component to be detected that is contained at a low concentration in the system. A resonant sensor of the present invention has a receiving layer that contains a polymer having a repeating unit represented by Formula (1). In Formula, R.sup.1 represents an alkyl group. A plurality of R.sup.1's may be the same as or different from each other. R.sup.2 represents a hydrogen atom, an alkyl group, or an aryl group. ##STR00001##

A system for the non-destructive inspection of a structure includes a probe including a hollow cylindrical waveguide having a first region and a second region. The first region has a first diameter and the second region has a second diameter. The second diameter is greater than the first diameter. The first diameter is sized and configured for insertion into a structure. The system further includes at least one of sensor element capable of generating and detecting longitudinal and/or torsional ultrasonic guided waves in the waveguide. The at least one sensor element is configured to generate a guided wave pulse in the waveguide when a time-varying current is provided to the at least one sensor element. The at least one sensor element is configured to deflect reflected guided wave energy from one or more anomalies in the structure.

A fluidic device incorporating at least one BAW resonator structure (e.g., a biosensing device) and a fluidic passage includes one or more features that provide filtration capability. Certain embodiments include at least one group of pillars extending into the fluidic passage which are arranged between an active region of the at least one BAW resonator structure and at least one fluidic port. Individual pillars are separated from one another by inter-pillar spaces that provide redundant fluid flow paths while preventing passage of obstruction media such as particulate matter, cells, and/or bubbles. Certain embodiments provide porous material arranged in fluid communication with at least one fluidic port and configured to filter contents of fluid supplied thereto. Porous material (e.g., porous membranes) may be provided in a cover structure of a fluidic device or within a filtration cartridge.