An apparatus is provided for sensing an analyte in a fluid. The apparatus includes a fluid collecting device configured to collect the fluid containing the analyte; a fluid input in fluid communication with the fluid collecting device configured to input the fluid containing the analyte into the fluid collecting device, an analyte interactant in fluid communication with the fluid collecting device, wherein the analyte interactant, when contacted by the analyte, reacts to cause a first change in thermal energy within the fluid collecting device; a modulator that causes a second change in thermal energy; a thermal sensing device comprising at least one pyroelectric device thermally coupled to the fluid collecting device to generate a first signal in response to at least one of the first change in thermal energy and the second change in thermal energy; a control device operatively coupled to the thermal sensing device and the modulator that generates a second signal, wherein the second signal comprises information useful in characterizing the analyte. A related method also is disclosed.

The present invention relates to a method for predicting the restart of paraffinic oil flow by being able to estimate the precipitated paraffin fraction under conditions of production stoppage through differential scanning calorimetry (DSC) tests and rheological evaluation, to predict the yield stress (TLE) profiles in pipes containing gelled paraffinic petroleum and the time interval until line blockage formation (available waiting timeTED).

A combustible gas sensor including a first sensing element having a catalyst and a heating element and electronic circuitry in operative connection with the heating element of the first sensing element to change a temperature thereof between a temperature above a temperature to catalyze oxidative combustion and a temperature at which the catalyst is substantially inactive to catalyze oxidative combustion of a plurality of gas analytes of interest. The electronic circuitry being configured to determine a species of at least one of the plurality of gas analytes of interest from a first, dynamic output of the combustible gas sensor while the temperature of the first sensing element is changing. The electronic circuitry further being configured to determine a concentration of the species from a second output of the combustible gas sensor.

The invention provides a calibration method for calibrating a chip-based microfluidic calorimeter, wherein the chip-based microfluidic calorimeter comprises one or more thermopiles, wherein the calibration method uses the deprotonating reaction of a phosphate group, the method comprising: providing calibration liquids comprising (i) a buffer with a pH range of at least 7-9 and (ii) a first compound with a phosphate group which is protonated in a pH range of at least 3-6, and mixing these calibration liquids in the chip-based microfluidic calorimeter to provide a calibration liquid mixture whereby heat is generated, measuring the heat by the thermopiles and thereby providing a corresponding thermopile signal, and calibrating the chip-based microfluidic calorimeter by relating the thermopile signal to reference data of the deprotonating reaction.

Apparatus and methodologies relating to improved gas detection in closed systems are provided. More specifically, the present systems provide for the mixing, conditioning and production of a detection gas comprising, for example, predetermined ratios of nitrogen and methane gas, such predetermined ratios operative for enhancing imaging of gas leaks detected using infrared thermography imaging.

An apparatus and a method are disclosed for measuring a characteristic of an analyte particle. An apparatus for measuring a characteristic of an analyte particle includes a heat flux sensor configured to be maintained at a temperature. The heat flux sensor includes first and second electrical connections, and a top interconnect membrane bridging the first and second electrical connections. The apparatus further includes an emitter configured to eject an analyte particle to cause the analyte particle to collide with the top interconnect membrane of the heat flux sensor.

Methods, apparatuses, and computer program products for determining amounts of greenhouse gas emissions are provided. For example, a computer-implemented method may include determining an amount of each of a plurality of constituent components of a fuel being used, determining one or more properties of the fuel, generating one or more emission factors for the fuel, determining an amount of the fuel used, and using the one or more generated emission factors, determining an emitted amount of a corresponding one or more greenhouse gases. Each emission factor corresponds to a different greenhouse gas. Each emission factor is generated using at least one of the constituent components and at least one of the properties.

A gas monitor apparatus includes a sorbent material that adsorbs a target gas based on a concentration of the target gas in a monitored environment and a reference material that does not respond to the target gas. The gas monitor also includes a first thermistor disposed within the sorbent material and a second thermistor disposed within the reference material, the first thermistor to provide a first indication of a first temperature of the sorbent material and the second thermistor to provide a second indication of a second temperature of the reference material. A processing device determines a concentration of the target gas based at least in part on a differential measurement between the first temperature and the second temperature.

Automated isothermal titration micro calorimetry (ITC) system comprising a micro calorimeter with a sample cell and a reference cell, the sample cell is accessible via a sample cell stem and the reference cell is accessible via a reference cell stem. The system further comprises an automatic pipette assembly comprising a syringe with a titration needle arranged to be inserted into the sample cell for supplying titrant, the pipette assembly comprises an activator for driving a plunger in the syringe, a pipette translation unit supporting the pipette assembly and being arranged to place pipette in position for titration, washing and filling operations, a wash station for the titrant needle, and a cell preparation unit arranged to perform operations for replacing the sample liquid in the sample cell when the pipette is placed in another position than the position for titration.

A combustible gas sensor includes a first sensing element, which includes a catalyst and a heating element in operative connection with the catalyst to heat the catalyst above a temperature to combust gas analytes of interest, and electronic circuitry in operative connection with the heating element of the first sensing element to periodically cycle the first sensing element between a temperature above the temperature to combust the analytes of interest and a temperature at which the catalyst is substantially inactive to catalyze oxidative combustion of the analytes of interest. The electronic circuitry is adapted to determine a species of at least one of the gas analytes of interest from a first output of the combustible gas sensor during an ON time within a cycle duration. The electronic circuitry is further adapted to determine a concentration of the species of gas from a second output of the combustible gas sensor.