A method of preparing electronically conductive polyaniline that forms a self-supporting dispersion in water is described. The binder-free dispersion was coated on a pair of interdigitated metal electrodes to form a gas sensing layer of a chemical sensor. The chemical sensor utilizes electrochemical impedance spectroscopy (EIS) to detect and characterize a chemical compound in a gaseous state in contact with the sensing layer. Impedance of the sensing layer is measured over a range of alternating current frequencies. The impedance data allows identification and concentration of the chemical compound to be determined when compared to reference impedance data. The analysis of the impedance measurements is adaptable to machine learning.

A system for measuring electrical characteristics of bioparticles is described. The system comprises an incubator for performing electrochemical measurements in a defined environment and a substrate holder positioned in said incubator for holding a substrate comprising a plurality of wells. The system is furthermore configured for continuously or regularly measuring electrochemical data. The system also comprises a processing means for comparing the continuously or regularly measured electrochemical data with reference data and for determining a moment for adding an active compound based on said comparison.

Various aspects of the disclosure relate to evaluating the electromagnetic impedance characteristics of a material under test (MUT) over a range of frequencies. In particular aspects, a system includes: an electrically non-conducting container sized to hold the MUT, the electrically non-conducting container having a first opening at a first end thereof and a second opening at a second, opposite end thereof; a transmitting electrode assembly at the first end of the electrically non-conducting container, the transmitting electrode assembly having a transmitting electrode with a transmitting surface; and a receiving electrode assembly at the second end of the electrically non-conducting container, the receiving electrode assembly having a receiving electrode with a receiving surface, wherein the receiving electrode is approximately parallel with the transmitting electrode, and wherein the transmitting surface of the transmitting electrode is larger than the receiving surface of the receiving electrode.

A measuring system automatically determines and/or monitors quality of a dairy product. The measuring system includes a housing for a container containing the dairy product, a viscosity measuring device, and a control unit. The viscosity measuring device includes a magnetic first body, an electromagnetic drive, and a detection system that detects displacement of the magnetic first body. The electromagnetic drive includes a plurality of individually controllable coils in a stack. The control unit is configured to individually energize the coils in a predetermined pattern in such a way that the magnetic first body is displaced. The magnetic first body is able to be readily pulled up, even in viscous liquids, but can also be pulled down in a controlled manner so that the viscosity can be measured more accurately.

The subject of the invention is a bioreceptor molecule with the formula: R.sub.1-alkyl-C(0)NH—R.sub.2, wherein alkyl is linear or branched alkyl with 2 to 20 C atoms; R.sub.1 is selected from a group comprising thiol group (—SH); disulfide bridge; —S(O)-alkyl, wherein alkyl is linear or branched and contains 1-3 C atoms; thioether, wherein thioether contains 1-3 C atoms; thioacid; thionyl group; R.sub.2 is a peptide with a sequence selected from a group comprising SEQ ID NO 1-8. Another subject of the invention is the use of bioreceptor molecules according to the invention in electrochemical impedance spectroscopy for detecting the SARS-CoV-2 virus. The subject of the invention is also a sensor containing an electrode, whose surface is covered with a layer of metal, characterized in that this layer is modified by bioreceptor molecules according to the invention. Furthermore, the subject of the invention is the method of detecting the SARS-Cov-2 virus by means of electrochemical impedance spectroscopy, including the following steps: a. rinsing and drying of the sensor electrode covered with metal; b. modification of the sensor electrode surface with bioreceptor molecules; c. calibration of the measurement system; d. detection of SARS-Cov-2 virus in a sample by means of a measurement system by observation of impedance changes, characterized in that surface modification of the sensor electrode is carried out using bioreceptor molecules according to the invention, wherein the presence of the virus in the test sample is indicated by a change in impedance of at least 10% in absolute value against the baseline value.

Microfluidic method and device that can be used for sensing and measurement of properties of liquids, gases, solutions, and particles is proposed, wherein the measurable liquid or gas (with or without particles) flow in at least one channel through a measurement chamber (cell) formed between at least two isolated electrodes is used for electrical impedance measurement. The proposed solution is characterized in that the cross-section of at least one pair of similar spatial electrodes decreases smoothly towards the tiny measurement chamber (cell) in order to increase the sensitivity and accuracy of the measurement. Typically, a device with multiple similar channels is advantageous to use for comparative measurement and differential measurement schemes.

A method for determining an electrical property of interest of material(s) in a target region confined by a boundary surface comprises receiving measured values of a measurable electrical quantity; providing simulated values of the measurable electrical quantity for an initial approximation of the electrical property conditions; determining an objective function comprising observation difference between the measured and the simulated values as well a prior model, and determining an adjusted approximation; and providing, on the basis of the adjusted approximation, an estimation of the electrical property of interest. Simulated statistics of a position deviation in the observations is provided, caused by a difference of an effective position of the measurement probe from a predetermined reference position; and by providing the observation model to define the observations of the measurable electrical quantity to correspond to measurements made with the measurement probe in the reference position.

Methods for determining the internal corrosion rate of steel pipelines. During the methods the calibration constant is determined under laboratory conditions then by using the calibration constant field conditions are modeled under laboratory conditions and the corrosion rate is determined, then in the same manner as under laboratory conditions the corrosion rate is determined under field conditions. Further, the invention is a measuring arrangement for determining the calibration constant and the corrosion rate for the internal corrosion rate of steel pipelines (1) the arrangement is applicable to carry out the methods under laboratory and field conditions. The arrangement consists of a polarizing and measuring unit (5) having a two-channel power output (2), a potential-measuring input (3), and a ground connection (4), a control and data storage unit (6), and three probes (8) with counter-electrodes (7). At least one probe (8) is also provided with a reference electrode (9).

Impedance is used to determine the performance of paraffin inhibitors in oil containing paraffin. The method and system can use a specially designed impedance cell having a cell constant of less than 1 cm.sup.−1. Further, the method can include obtaining at least impedance measurements above the wax appearance temperature (WAT) for an oil sample treated with a paraffin inhibitor and an oil sample not treated, and impedance measurements below the WAT for the treated oil sample and the untreated oil sample. Thereafter, the impedance measurements are correlated to determine paraffin inhibitor performance.

Apparatus and methods for determining the impedance spectrum of materials at elevated thermobaric conditions. The apparatus comprises a pair of electrodes in a sample chamber. The sample may be conditioned within the sample chamber by the application of heat and/or pressure. A controller applies alternating voltages across the terminals at a range of different frequencies and processes the frequency response of the sample to determine the impedance spectrum of the sample. By empirically determining the frequency spectrum of the dielectric properties (relative dielectric constant and conductivity) from the measured impedance spectrum at various temperatures and pressures, the effectiveness of electromagnetic heating in extreme environments (e.g., within an oil reservoir) can be determined.