Abstract: Provided is a method for measuring the concentration of a substance in a blood sample, the method comprising the steps of: supplying the blood sample to a biosensor comprising a hematocrit electrode for measuring a hematocrit value on the surface of which electrode an electrically conductive polymer is coated by physical adsorption in the absence of a crosslinking agent; and calculating the concentration of the substance from the measured value of a first current resulting from application of a first voltage; and correcting the concentration of the substance with the value of a second current resulting from application of a second voltage or the hematocrit value calculated from the value of the second current.

Abstract: Disclosed is a method of calibrating apparatus for optically characterising samples of particles of small size. Also disclosed is a method of estimating the concentration of particles in a population of small size particles.

Abstract: An airborne biological particle monitoring device collects particles floating in air. The monitor includes a camera sensor, illumination source, and quantum-dot illumination source. The camera sensor captures a first image of the particles when the collected particles are illuminated by the illumination source. The camera sensor captures a second image of the particles when the collected particles are illuminated by the quantum-dot illumination source. The first and second images are analyzed to identify the collected particles.

Abstract: A system and method for sorting sperm is provided. The system includes a housing and a microfluidic system supported by the housing. The system also includes an inlet providing access to the microfluidic system to deliver sperm to the microfluidic system and an outlet providing access to the microfluidic system to harvest sorted sperm from the microfluidic system. The microfluidic system provides a flow path for sperm from the inlet to the outlet and includes at least one channel extending from the inlet to the outlet to allow sperm delivered to the microfluidic system through the inlet to progress along the flow path toward the outlet. The microfluidic system also includes a filter including a first plurality of micropores arranged in the flow path between the inlet and the outlet to cause sperm traveling along the flow path to move against through the filter and gravity to reach the outlet.

Abstract: A sheath flow device for an evaporation light scattering detector comprises an evaporation pipe fastener (110), an evaporation pipe heat insulating component (120), a sheath flow nozzle blocking plate (130), a sheath flow nozzle (140), a sheath flow sleeve (150), a sheath flow outlet piece (170) and a stainless steel spray needle (160). The evaporation pipe fastener, the evaporation pipe heat insulating component, the sheath flow nozzle blocking plate, the sheath flow nozzle, the sheath flow sleeve and the sheath flow outlet piece are concentrically connected orderly from front to back, and all provided with concentric inner holes. Said device is applicable to ELSD sheath flow devices ranging from nanoliter-scale to microliter-scale.

Abstract: High numerical aperture collection optics for particle analyzers may include an ellipsoidal reflector or an ellipsoidal reflector in combination with a spherical reflector, and may efficiently collect light scattered or emitted by particles in a sample stream and then couple that collected light into a lower numerical aperture portion of the instrument's optical detection system, such as into an optical fiber for example. The reflectors may be integrated with a flow cell through which the sample stream passes, or may be separate components arranged around a flow cell or, in instruments not employing a flow cell, arranged around a sample stream in air. Refractive beam steering optics may allow multiple closely spaced excitation beams to be directed into the sample stream at low angles of incidence. The collection optics and refractive beam steering optics may be employed separately or in combination with each other.

Abstract: An optical device (22) includes a case (30), which fits over at least a part of a mobile computing device (24) having first and second faces and including a light source (29), which emits a beam of illumination through an exit aperture, and a camera module (27), which captures images through an entrance aperture. Both the entrance and exit apertures open through the second face of the mobile computing device. A receptacle (31) in the case receives and positions a sample (56) in proximity to the second face of the mobile computing device within a field of view of the camera module. Illumination optics (36, 38) receive and turn the beam emitted by the light source so as to back-illuminate the sample while the camera module captures one or more images of the back-illuminated sample.

Abstract: This disclosure relates to rapid and repeatable tests that can be used to evaluate the interfacial adhesion of coatings to substrates. In particular embodiments, tests are used to assess the resistance of anodic oxides to delamination from aluminum substrates. The tests can be conducted using standard hardness test equipment such as a Vickers indenter, and yield more controlled, repeatable results than a large sample of life-cycle tests such as rock tumble tests. In particular embodiments, the tests involve forming an array of multiple indentations within the substrate such that stressed regions where the coating will likely delaminate are formed and evaluated.

Abstract: A method for determining national crop yields during the growing season using regional agricultural data is provided. In an embodiment, determining national crop yields during the growing season may be accomplished using a server computer system that receives, via a network, agricultural data records that are used to forecast a national crop yield for a particular year. Within the server computer system an agricultural time series module receives one or more agricultural data records that represent a type of covariate data value related to plants at a specific geo-location at a specific time. The agricultural time series module then aggregates the agricultural data records to create one or more geo-specific time series that represent a specific geo-location over a specified time. The agricultural time series module creates one or more aggregated time series that represent geographic areas from a subset of the one or more geo-specific time series.

Abstract: An improved method and system for analyzing multistate fluids using NIR spectroscopy. If the sample to be tested resides in a single state condition, the configuration file used in spectroscopic analysis will only be applied against a single model. However, if the sample to be tested is in a multi-state environment, an algorithm determines which model set of a plurality of model sets should be utilized based on the sample characteristics, and the configuration file used in spectroscopic analysis will be applied against the selected model. Results are generated showing the designated parameters.

Abstract: This application is directed to a fast method of quantitatively and qualitatively validating the amount of silicone adhesive in a composition comprising silicone adhesive and silicone polymer which comprises of testing a sample of the composition with near IR or mid IR spectroscopy. The method can be extended to analyzing the amount of silicone adhesive in an oral care composition.

Abstract: A processor includes a transistor pair of a first transistor and a second transistor. The first transistor of the transistor pair is coupled to a Spaser and configured to output a drive current to the Spaser to pump the Spaser. Responsive to the drive current, the Spaser outputs surface plasmon polaritons (SPPs) which are fed to a plasmonic interconnect wire. The plasmonic interconnect wire propagates the SPPs. Further, the SPPs propagated on the plasmonic interconnect wire are detected by a phototransistor. Responsive to detecting the SPPs, the phototransistor generates an output current that is fed to a gate terminal of the second transistor to charge the second transistor.

Abstract: In a spectrophotometer and a method of operation, very low levels of energy are produced in a laser diode and directed to excite a sample. Energy is provided to a quantum well to bring the laser diode to a pre-lasing state. Another increment of energy causes the laser diode to emit energy at an energy level lower than a visible laser beam. The energy produced by the laser is collided with the sample. A stimulated emission from the sample includes signals from various entities in the sample. The return emission spectra from the sample comprise signatures used to identify compounds. Use of such very low energies collided with a sample elicit spectra not previously associated with respective analytes. A Raman spectroscopy platform is used for performance of the method.

Abstract: The invention relates to a method for determining a scale inhibitor concentration in a sample comprising at least a first scale inhibitor, which is a synthetic organic compound comprising at least one ionised group. The method comprises optionally diluting and/or purifying the sample, and allowing the sample to interact with a reagent comprising a lanthanide(III) ion. The sample is excited at a first excitation wavelength and a sample signal deriving from the lanthanide(III) ion is detected at a signal wavelength by using time-resolved luminescence measurement, and the concentration of the at least first scale inhibitor in the sample is determined by using the detected sample signal.

Abstract: The invention relates to a method for analysing a sample comprising at least a first and a second scale inhibitor, which scale inhibitors are synthetic organic compounds comprising at least one ionised group. The method comprises optionally diluting and/or purifying the sample, and allowing the sample interact with a reagent comprising lanthanide(III) ion. The sample is excited at a first excitation wavelength and a sample signal deriving from the lanthanide(III) ion is detected at a signal wavelength by using time-resolved luminescence measurement. The total concentration of the first and the second scale inhibitor is determined by using the detected sample signal, and the concentration of the first scale inhibitor in the sample is determined. The concentration of the second scale inhibitor is determined mathematically by using the obtained results for the total concentration and for the first scale inhibitor concentration.

Abstract: Provided herein is an apparatus for assessing a fluorescence characteristic of a gemstone. The apparatus comprises an optically opaque platform for supporting a gemstone to be assessed, one or more light source to provide uniform UV and non-UV illumination, an image capturing component, and a telecentric lens positioned to provide fluorescent images of the illuminated gemstone to the image capturing component. Also provided are methods of fluorescence analysis based on images collected using such an apparatus.

Abstract: The disclosure relates to measurement and classification of tissue structures in samples using a combination of light imaging and spectroscopy, in particular although not necessarily exclusively for detection of tumours such as basal cell carcinoma or breast tumours in tissue samples. Embodiments disclosed include a method of automatically identifying tissue structures in a sample, the method comprising the steps of: measuring (1702, 1703) a response of an area of the sample to illumination with light; identifying (1704) regions within the area having a measured response within a predetermined range; determining (1705) locations within the identified regions; performing (1706) spectroscopic analysis of the sample at the determined locations; and identifying (1707) a tissue structure for each region from the spectroscopic analysis performed on one or more locations therein.

Abstract: An optical metrology device is capable of detection of any combination of photoluminescence light, specular reflection of broadband light, and scattered light from a line across the width of a sample. The metrology device includes a first light source that produces a first illumination line on the sample. A scanning system may be used to scan an illumination spot across the sample to form the illumination line. A detector collects the photoluminescence light emitted along the illumination line. Additionally, a broadband illumination source may be used to produce a second illumination line on the sample, where the detector collects the broadband illumination reflected along the second illumination line. A signal collecting optic may collect the photoluminescence light and broadband light and focus it into a line, which is received by an optical conduit. The output end of the optical conduit has a shape that matches the entrance of the detector.

Abstract: A device (10) for illuminating a sample (40) is described, having: at least one pulsed laser light source (12) for repeated emission of a first laser pulse along a first light path (14) and of a second laser pulse along a second light path (16) physically separated from the first light path; a superimposition element (32) for collinear superimposition of the two laser pulses in a shared light path (34); a delay stage (26) arranged in the first or the second light path (14, 16), for delaying one of the two laser pulses relative to the other laser pulse in such a way that the two laser pulses sent along the shared light path (34) onto the sample (40) exhibit a temporal superimposition; a shared chirp unit (36) arranged in the shared light path (34), for frequency-modifying influencing both of the first laser pulse and of the second laser pulse; and at least one separate chirp unit (18) arranged in the first light path (14), for frequency-modifying influencing only of the first laser pulse.

Abstract: The invention provides a method for measuring the concentration of anionic polymers in an industrial water system. Specifically, the concentration of anionic polymer can be measured by combining an indicator dye composition comprising an acridine compound or a salt thereof to a water sample and measuring the absorbance of the mixture. The concentration can be determined by comparing the absorbance of the mixture to absorbance values on a pre-determined calibration curve. The dosage of anionic polymer can be optionally adjusted based on the concentration.

Abstract: Provided herein is an apparatus for assessing a color characteristic of a gemstone. The apparatus comprises an optically opaque platform for supporting a sample gemstone to be assessed, a daylight-approximating light source to provide uniform illumination to the gemstone, an image capturing component, and a telecentric lens positioned to provide an image of the illuminated gemstone to the image capturing component. Also provided are methods of color analysis based on images collected using such an apparatus.

Abstract: An object of the present invention is to provide a content condition determination apparatus and a content condition determination. Method capable of efficiently determining the conditions of contents in drug-discovery storage tubes a short time using a simple configuration. A content condition determination apparatus includes a tube moving mechanism 120 that moves drug-discovery storage tubes MT to an imaging position, a lighting unit 130 that projects transmitted light, and a control section 150 that controls processing and operation of an imaging unit 110, an image processing section 140, the tube moving mechanism 120, and the lighting unit 130. The lighting unit 130 has an infrared light projection section 131. The control section 150 is configured to allow the light projection the lighting unit 130 and the imaging by the imaging unit 110 to be performed in an interlocking manner.

Abstract: An inspection system including an optical system (optics) to direct light from an illumination source to a sample, and to direct light reflected/scattered from the sample to one or more image sensors. At least one image sensor of the system is formed on a semiconductor membrane including an epitaxial layer having opposing surfaces, with circuit elements formed on one surface of the epitaxial layer, and a pure boron layer on the other surface of the epitaxial layer. The image sensor may be fabricated using CCD (charge coupled device) or CMOS (complementary metal oxide semiconductor) technology. The image sensor may be a two-dimensional area sensor, or a one-dimensional array sensor. The image sensor can be included in an electron-bombarded image sensor and/or in an inspection system.

Abstract: Provided is an optical inspection system including a supporting unit, allowing a target object to be loaded thereon, a light source unit configured to emit a laser beam toward the target object, a light condensing unit collecting scattered light that is scattered at the target object when the laser beam is irradiated onto the target object, and a control unit controlling the light source unit and the light condensing unit and analyzing the scattered light to examine whether there are pollutants on the target object. The supporting unit may include a first supporting unit, on which the target object is disposed, and which is formed of a first material, and a second supporting unit, which is disposed under the first supporting unit and is formed of a second material different from the first material.

Abstract: Methods and systems for detecting defects on a wafer are provided. One system includes one or more computer subsystems configured for generating a rendered image based on information for a design printed on the wafer. The rendered image is a simulation of an image generated by the optical inspection subsystem for the design printed on the wafer. The computer subsystem(s) are also configured for comparing the rendered image to an optical image of the wafer generated by the optical inspection subsystem. The design is printed on the wafer using a reticle. In addition, the computer subsystem(s) are configured for detecting defects on the wafer based on results of the comparing.

Abstract: The present invention relates to a device for the detection and measurement of the physical-chemical features of materials in the form of sheets comprising a microwave sensor coupled to a passive reflector on the other side of the material to be measured. The invention further comprises calculation methods and algorithms for processing output data, adapted to make the measurement immune from the typical environmental factors of industrial environments.

Abstract: An X-ray generation apparatus includes: an electron emission device comprising a plurality of electron emission units that emit electrons; a transmission type X-ray emission unit for emitting an X-ray by electrons emitted by the plurality of electron emission units; and a vacuum chamber for shielding the electron emission device and the transmission type X-ray emission unit by using vacuum. An X-ray imaging system includes an X-ray detection apparatus for detecting an X-ray that is irradiated from the X-ray generation apparatus and passes through an object.

Abstract: A hard X-ray grating phase-contrast imaging apparatus with large field-of-view, high contrast and low dose and the method thereof. The apparatus includes a source emitter (31), a source grating (G0), a beam splitting grating (G1), an analyzer grating (G2) and a detector (32) arranged in sequence on a transmission path of the source emitter (31). The beam splitting grating (G1) has a period of 30 to 50 ?m and a depth to width ratio not greater than 20. The apparatus can provide a high image contrast and a low radiation dose and realize a phase-contrast imaging with high energy and a large field-of-view by increasing the grating period, increasing a duty cycle of the beam splitting grating while increasing the distance between an object and the analyzer grating. The apparatus can also utilize the conventional polychromatic X-ray sources and available process for manufacturing gratings, and be suitable for clinical use.

Abstract: Disclosed, is a sample preparation apparatus (6B) which is configured to prepare a material sample (900?) suitable for X-ray diffraction. The apparatus (6B) comprises a dished sample holder bottom (500) configured to fit within an annular sample holder (400). The dished sample holder bottom (500) has a concave dished surface (501) which is adapted to distribute sample material (900) under pressing forces. A method of preparing a material sample (900?) suitable for X-ray diffraction is also disclosed. The method comprises dosing a dished sample holder bottom (500) which is configured to fit within an annular sample holder (400) with sample material (900), wherein the dished sample holder bottom (500) preferably has a concave dished surface (501) which is adapted to distribute sample material (900) under pressing forces. A new leveling device design tool (FIG. 12) is also disclosed.

Abstract: A method and apparatus for imaging the distribution of bulk motional velocities in plasmas such as inertial confinement fusion (ICF) implosions. This method and apparatus use multiple narrow-band x-ray crystal imaging systems, one or more of which have a bandpass tuned to lie within the Doppler-broadened emission line profile of a suitable plasma emission line. Crystals tuned on the one end of the profile will preferentially reflect x-rays from plasma ions moving towards the crystals, while crystals tuned to another end of the profile will preferentially reflect x-rays from plasma ions moving away from the crystals.

Abstract: A system and method are provided for authenticating an item, comprising selecting a coding site on the item, storing a location of the coding site, selecting a coding material including at least one transition metal, obtaining an original spectrum of the coding material using an X-ray fluorescence spectroscopy device, storing the original spectrum, applying the coding material to the coding site, and authenticating the item. The item is authenticated by accessing the location of the coding site and the original spectrum, obtaining an authentication spectrum of the coding material using an X-ray fluorescence spectroscopy device, and comparing the authentication spectrum to the original spectrum. The item is authentic when the coding material is present at the coding site and the authentication spectrum matches the original spectrum. The item is not authentic when the coding material is not present at the coding site or the spectra do not match.

Abstract: Monitoring cell (100) for performing an NMR measurement of a reaction fluid. The monitoring cell (100) has a hollow NMR sample probe (110) for receiving the reaction fluid. Inlet and outlet transport capillaries (112, 123) transport the reaction fluid to and from the sample probe (110). A feed line (306) and return line transport a temperature control fluid to and from the monitoring cell (100). An adapter head (108) couples the transport capillaries (112, 123) to the sample probe (110) and removably connects the sample probe (110) to an adapter section (106). The transport capillaries (112, 123) are positioned within the feed line (306) in parallel to one another. The feed and the return lines (306, 358) are attached to the adapter section (106) such that a reversal of the temperature control fluid stream occurs in the adapter section (106).

Abstract: A disclosed method for characterizing gas adsorption on a rock sample includes: measuring a nuclear magnetic resonance (NMR) response of the rock as a function of surrounding gas pressure along an isotherm; transforming the NMR response to obtain a Langmuir pressure distribution of gas adsorption on the rock sample; and displaying the Langmuir pressure distribution. The Langmuir pressure distribution may be shown in one dimension (e.g., contribution to signal response versus Langmuir pressure), or may be combined with additional pressure-dependencies such as spin-lattice relaxation time (T1), spin-spin relaxation time (T2), and chemical shift (?) to form a multi-dimensional distribution. The method can further include: identifying peaks in the Langmuir pressure distribution; and associating a gas storage mechanism and capacity with each peak.

Abstract: Object information representing a honeycomb structure with a plurality of meshes is obtained, and an inner-wall-surface heat transfer coefficient hs, i.e., a heat transfer coefficient between an inner wall surface of a cell and a fluid, is derived as follows. First, one of the meshes as a target for derivation of the inner-wall-surface heat transfer coefficient hs is set (S200), and a dimensionless coordinate X* is derived on the basis of position information (X-coordinate) of the set mesh and fluid state information (S210). An inner-wall-surface dimensionless heat transfer coefficient Nus corresponding to the derived dimensionless coordinate X* is then derived on the basis of the inner-wall-surface dimensionless correspondence information (S220 to S250). The inner-wall-surface heat transfer coefficient hs in the mesh set as the derivation target is then derived on the basis of the derived inner-wall-surface dimensionless heat transfer coefficient Nus (S260).

Abstract: A sensing system for selective analyte detection in presence of interferences is presented. The sensing system includes an inductor-capacitor-resistor (LCR) resonant sensor includes a substrate, a plurality of first sensing elements mutually spaced apart and disposed on the substrate, a plurality of second sensing elements, each second sensing element disposed overlapping a corresponding first sensing element of the plurality of second sensing elements, and a protecting film applied onto the plurality of first sensing elements and the plurality of second sensing elements, wherein the protecting film is disposed to be in a physical contact with the analyte and is configured to enable an operational contact of the plurality of first sensing elements and the plurality of second sensing elements with the analyte.

Abstract: A method includes: removing at least a part of an oxide formed on a surface of the sample by relatively scanning the surface of the sample in X and Y directions parallel to the surface while bringing a probe into contact with the surface of the sample; detecting a signal by bringing the probe into contact with the surface of the sample from which at least a part of the oxide is removed at a predetermined detection position in the X direction or the Y direction while a bias voltage is applied to the sample; calculating a spreading resistance value based on the signal; and retracting the probe to keep the probe relatively away from the surface in a Z direction perpendicular to the surface while relatively moving the probe to a next detection position to start scanning the sample from the next detection position.

Abstract: An integrated gas sensor having a tungsten/tungsten oxide gas sensing element, is provided with: a substrate of semiconductor material; and a structure of interconnection layers, arranged above the substrate and made of a number of stacked conductive layers and dielectric layers. The gas sensing element is integrated within the structure of interconnection layers and at least one electrode is provided within the structure of interconnection layers, electrically connected to the gas sensing element, designed to provide an electric current to the gas sensing element in order to cause heating thereof.

Abstract: A gas sensor is provided with a detection element, a circuit board, and a housing that houses the detection element and the circuit board. The housing has a first fastening section, a second fastening section, and a gas introducing port. The center of the gas introducing port is positioned on a virtual line connecting the first fastening section and the second fastening section, and is disposed corresponding to a corner section of the circuit board, said corner section being close to the first fastening section side.

Abstract: An electrochemical system includes an electrolyte that includes at least one ionic form of a chemical element A chosen from lithium and sodium. The electrolyte is in contact with a comparison electrode, a working electrode and a counterelectrode. The comparison electrode includes a first part in contact with the electrolyte and including a metal M capable of alloying with the chemical element, or a metal alloy of the metal M and of the chemical element A. The comparison electrode also includes a second part including an electrically conducting material, chemically inert with respect to the chemical element A and its ionic form and in direct contact with the first part of the comparison electrode.

Abstract: A sampling plate (1) for use in measuring a property of a fluid sample comprising a sample zone comprising at least two discrete testing zones (5, 6) for receiving different respective volumes of the fluid sample. Each testing zone presents a zone volume defined by a respective zone area and a different respective zone height being a dimension transverse to the zone area (A).

Abstract: A blood glucose monitor includes a can, a replaceable sensor cartridge that includes a frame, an upper spring disposed between the frame and the can, a case for housing the can and sealing the frame, a lower spring disposed between the can and the case, and a meter housing for sealing an upper portion of the frame. The can is capable of accepting the replaceable sensor cartridge. The frame of the removable cartridge has at least at least two walls defining a chamber for accepting a plurality of biosensors, and a bottom portion defining an opening and at least one sealing flange. The frame can further include a desiccant material capable of reducing humidity within the frame. The frame may be dimensioned such that an interference fit constrains the plurality of biosensors prior to inserting the frame within a blood glucose monitor.

Abstract: An analyte meter, such as a blood glucose meter, uses electrochemical test strips and has a contoured strip port to improve electrochemical test strip reliability. The analyte meter has a strip connector with strip terminals that electrically connected to strip electrodes when a test strip is inserted through the strip port opening next to the strip connector. The contoured strip port is located next to the strip connector and comprises a strip shelf having side guides for aligning the test strip with the strip port, a strip port opening having a bottom opening extending from a first bottom edge to a second bottom edge, top guides located at a first top edge and a second top edge, and a contoured top extending between the top guides creating an arched clearance above the bottom opening to provide clearance for test strip electrical traces.

Abstract: The present invention presents a method of fabrication for a physiological sensor with electronic, electrochemical and chemical components. The fabrication method comprises steps for manufacturing an apparatus comprising at least one electrochemical sensor, a microcontroller, and a transceiver. The physiological sensor is operable to analyze biological fluids such as sweat.

Abstract: An oxygen sensor element includes a solid electrolyte body having oxygen ion conductivity, a measuring electrode having catalytic action disposed on one surface of the solid electrolyte body, a reference electrode having a catalytic action disposed on another surface of the solid electrolyte body, and a heater for heating the measuring electrode. When the measuring electrode is heated by the heater, when measuring an oxygen concentration in a measured gas, a ratio (%) of an area of a low-temperature region where a surface temperature is less than 450 degrees C. relative to an area of a contact portion exposed to the measured gas G is 15% or less.

Abstract: A sensor device includes: a housing body delimiting within the housing body: a flow duct, and a bypass that branches off from the flow duct at a branching point, the bypass having a wall with an opening; and a sensor element configured to detect a gas content, the sensor element being arranged in the opening. The sensor element has: a sensor body having a longitudinal axis, an electrode chamber within the sensor body, a heating element embedded in the sensor body and by which a predefined region around the electrode chamber is heatable to a predefined operating temperature, an inlet duct coupled to the electrode chamber and having an inlet on the surface of the sensor body, and a thermal insulation sleeve on the sensor body, the thermal insulation sleeve extending at least axially in the direction of the longitudinal axis over a region of the electrode chamber.

Abstract: An improved sensing method is provided for rapid analyte detection. The method includes: applying an AC excitation signal to the channel region of the transistor; applying an AC drive signal to the transistor; delivering an analyte of interest to a channel region of a transistor; and monitoring a mixing current of the excitation signal and the drive signal through the transistor, where a change in the mixing current is indicative of the concentration of the analyte of interest.

Abstract: A gas sensor includes: a channel layer in which a F-terminated GNR, a H-terminated GNR, and a F-terminated GNR whose edge portions are terminated with different modifying groups are bonded to each other; a source electrode formed on one end of the channel layer; and a drain electrode formed on the other end of the channel layer, in which a surface of the H-terminated GNR is exposed, and this exposed portion is a gas sensing part.

Abstract: An electrical circuit element, defined as “pixel”, can include at least one silicon nanowire open for contact with a medium for sensing; a metal electrode open for contact with said medium and used for feeding a high-frequency sinusoidal stimulation in impedance measurements and for sensing properties of said medium; implanted source and drain electrodes connected to said silicon nanowire and leaving the gate area and parts of said electrode open for contact with said medium; electrical metal contacts for connecting said pixel to an electrical circuit; and a reference electrode open for contact with said medium for creating a three-electrode-cell system and providing a constant gate potential in the circuit. Some embodiments provide a microelectronic sensor and wearable-patch sensor based on the array of these pixels. Also, some embodiments provide methods for performing DC readout, AC readout and a triple readout combining both DC and AC readouts and temperature sensing.

Abstract: In some embodiments, an electrical circuit element, defined as “optoelectronic pixel”, comprises at least one silicon nanowire decorated with optoelectronically active particles and open for contact with a medium for sensing; a metal electrode open for contact with said medium and used for feeding a high-frequency sinusoidal stimulation in impedance measurements and for sensing properties of said medium; implanted source and drain electrodes connected to said silicon nanowire and leaving the gate area and parts of said electrode open for contact with said medium; electrical metal contacts for connecting said pixel to an electrical circuit; and a reference electrode open for contact with said medium for creating a three-electrode-cell system and providing a constant gate potential in the circuit. In addition, some embodiments provide an optoelectronic sensor and wearable-patch sensor based on the array of the optoelectronic pixels, and the readout methods for these sensors.

Abstract: A method recalibrates in situ a comparison electrode integrated into an electrochemical system. The electrochemical system includes a working electrode, a counter electrode, and an electrolyte. The method includes verifying a potential of the comparison electrode relative to the working electrode or to the counter electrode in situ, detecting whether there is a drift in the potential of the comparison electrode relative to a potential plateau for which the comparison electrode was functionalized or designed, and when the drift is detected, recalibrating the comparison electrode in situ.