• 专利附录
  • 专利说明
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    • 专利摘要:
    CONFIGURED SENSOR TO DETECT A GASEOUS AGENT, METHOD FOR PREPARING A CONFIGURED SENSOR AND TO DETECT A CONCENTRATION OF A GASEOUS AGENT. It is a sensor to detect gaseous agents that has a transducer that includes a resonant electrical circuit that forms an antenna. In addition, the sensor includes a pickup material that is arranged on at least a portion of the transducer. The capture material is configured to display both a capacitance response and a resistance response in the presence of a gaseous agent. The sensor can be reversible, without a battery and may require no electrical contact with a sensor reader.
    公开号:BR102015032845B1
    申请号:R102015032845-1
    申请日:2015-12-29
    公开日:2020-12-01
    发明作者:Radislav Alexandrovich Potyrailo;Zhexiong Tang;Brandon Alan Bartling;Nandini Nagraj;Vadim Bromberg
    申请人:General Electric Company;
    IPC主号:
    专利说明:

    [0001] [001] The present invention relates to sensors and methods for the detection of gaseous agents and, more particularly, materials and sensors for the detection of chlorine dioxide, hydrogen peroxide, formaldehyde, peracetic acid, methyl bromide, oxide of ethylene, ozone and other gaseous agents that can be used as sterilization, fumigation or decontamination agents. BACKGROUND OF THE INVENTION
    [0002] [002] Decontamination, fumigation and sterilization of different environments is critical in a diverse range of applications including health care, food safety and animal safety, for example. Various gases can be used for sterilization, fumigation and decontamination purposes, which include, but are not limited to, chlorine dioxide, formaldehyde, hydrogen peroxide vapor, peracetic acid, methyl bromide, ozone and ethylene oxide. These gases, as well as others, are known for their effectiveness against both spore-forming bacteria and non-spore-forming bacteria.
    [0003] [003] The detection of gaseous agents that are used for decontamination, fumigation and sterilization is critical for safety in general. It is beneficial to determine the presence of sterilizing agents to ensure that a particular agent works properly and that the surface or material that is sterilized is free of harmful contaminants. For example, measuring the presence of vapors by discerning a change in certain environmental variables within or surrounding a sensor can be useful, in particular, in monitoring changes in biopharmaceutical products, food or drinks; monitoring of industrial areas with chemical or physical risks; security applications, such as home monitoring or national security at airports; different environmental and clinical settings and other public places where the detection of certain harmful and / or toxic vapors can be particularly useful. Although today's sensors offer a wide variety of both battery-free and wireless sensors, there is a commercial need for a reversible battery-free sensor that does not require electrical contact with a sensor reader. In addition, it is desired to have a sensor that can display multiple responses to a change in an environmental parameter in order to eliminate sensor arrangements.
    [0004] [004] The change in resistance provided by semiconductor metal oxides when exposed to a vapor, for example, is both an upward and downward shift. Traditionally, sensor arrays that include multiple sensors for accurate and functional monitoring are used. Various sensor arrays include several identical transducers coated with different pickup materials. However, although the use of identical transducers simplifies the fabrication of the sensor array, that array may have limited capabilities for capturing only a single response (eg resistance, current, capacitance, work function, mass, optical thickness, intensity light, etc.). In certain applications, multiple responses or changes in multiple properties can occur. In these applications, it may be beneficial to include a sensor array in which different transducers in the array employ the same or different responses (for example, resistance, current, capacitance, work function, mass, optical thickness, light intensity, etc.) and are lined with different capture materials, so that more than one property can be measured. Disadvantageously, however, manufacturing a sensor array that has individual sensors exclusively designed to capture a particular response complicates the fabrication of the array and is expensive. Therefore, a single sensor comprising a capture material that can simultaneously display more than one response when in the presence of a material under analysis is desired.
    [0005] [005] Several achievements revealed in this document can solve one or more of the challenges set out above. DESCRIPTION OF THE INVENTION
    [0006] [006] In one embodiment, a sensor is configured to detect a gaseous agent and the sensor has a transducer that includes a resonant electrical circuit that forms an antenna. The sensor also has a pickup material disposed at least in a portion of the transducer and the pickup material is configured to display both a capacitance response and a resistance response when exposed to a gaseous agent.
    [0007] [007] In another embodiment, a sensor is configured to detect a gaseous agent and the sensor has a transducer that includes an antenna. The sensor also has a pickup material arranged on the transducer and the pickup material includes a semiconductor metal oxide. Also, a noble metal catalyst is deposited on the semiconductor metal oxide. The antenna is configured to emit an electric field to probe a response from the pickup material when exposed to a gaseous agent.
    [0008] [008] In another embodiment, a method for making a sensor configured to detect a gaseous agent is described. First, a transducer is formed by placing an antenna on a substrate. Second, a noble metal catalyst is doped with a semiconductor metal oxide to form a metal oxide powder. Third, the metal oxide powder is mixed with an aqueous solution of a polymer matrix to form a stable metal oxide suspension. Fourth, the metal oxide suspension is deposited on the transducer and dried to form a final capture material.
    [0009] [009] In another embodiment, a method for detecting a gaseous agent is cited. In one step, a pickup material is exposed to a gaseous agent, where the pickup material comprises a first component and a second component. The first component and the second component are deposited on a surface of a pickup coil. The first component and / or the second component are oxidized or reduced and a capacitance response and a resistance response of the pickup coil are measured in a frequency range. Finally, an analysis is performed using the capacitance response and the resistance response in order to detect a concentration of the gaseous agent. BRIEF DESCRIPTION OF THE DRAWINGS
    [0010] - a Figura 1 mostra etiquetas de RFID que devem ser usadas para captação de vapor, de acordo com as realizações da presente invenção; - a Figura 2 é uma representação esquemática de um sensor, de acordo com as realizações da presente invenção; - a Figura 3 é uma representação gráfica de um espectro de impedância medido, de acordo com as realizações da presente invenção; - a Figura 4 é um bloco esquemático de uma configuração de sensor, de acordo com as realizações da presente invenção; - a Figura 5 é uma representação gráfica de resultados experimentais obtidas com três sensores diferentes, de acordo com as realizações da presente invenção; - a Figura 6 é uma representação gráfica da estabilidade de linha de base ou reversibilidade de uma resposta de sensor, de acordo com as realizações da presente invenção; - a Figura 7 é uma representação gráfica de uma resposta de sensor para aumentar os níveis de concentração de um material em análise, de acordo com as realizações da presente invenção; - a Figura 8 é uma representação esquemática de um diagrama de circuito equivalente de um sensor com um chip de memória IC e uma bobina de captação, de acordo com as realizações da presente invenção; - a Figura 9 ilustra modelos de materiais de captação que podem ser usados com sensores multivariáveis, de acordo com as realizações da presente invenção; - a Figura 10 é uma representação gráfica de resultados experimentais obtidos com um sensor ressonante após exposição do sensor a três vapores diferentes, de acordo com as realizações da presente invenção; - a Figura 11 é uma representação gráfica de resultados experimentais obtidos com outro sensor ressonante após exposição do sensor a três vapores diferentes, de acordo com as realizações da presente invenção; - a Figura 12 é uma representação gráfica de resultados experimentais obtidos com um sensor ressonante após exposição do sensor a cinco vapores diferentes, de acordo com as realizações da presente invenção; - a Figura 13 é uma representação gráfica de resultados experimentais obtidos com outro sensor ressonante após exposição do sensor a cinco vapores diferentes, de acordo com as realizações da presente invenção; e - a Figura 14 é uma representação gráfica de resultados experimentais obtidos com um sensor ressonante após exposição do sensor a três vapores diferentes, de acordo com as realizações da presente invenção; [010] These and other features, aspects and advantages of this specification will be better understood when the following detailed descriptions are read with reference to the accompanying drawings, in which similar characters represent similar parts throughout the drawings presented in this document: - Figure 1 shows RFID tags that should be used to capture steam, in accordance with the embodiments of the present invention; Figure 2 is a schematic representation of a sensor, according to the embodiments of the present invention; Figure 3 is a graphical representation of a measured impedance spectrum, in accordance with the embodiments of the present invention; Figure 4 is a schematic block of a sensor configuration, in accordance with the embodiments of the present invention; - Figure 5 is a graphical representation of experimental results obtained with three different sensors, according to the embodiments of the present invention; Figure 6 is a graphical representation of the baseline stability or reversibility of a sensor response, in accordance with the embodiments of the present invention; Figure 7 is a graphical representation of a sensor response to increase the concentration levels of a material under analysis, in accordance with the embodiments of the present invention; Figure 8 is a schematic representation of an equivalent circuit diagram of a sensor with an IC memory chip and a pickup coil, according to the embodiments of the present invention; Figure 9 illustrates models of capture materials that can be used with multivariable sensors, in accordance with the embodiments of the present invention; Figure 10 is a graphical representation of experimental results obtained with a resonant sensor after exposing the sensor to three different vapors, according to the embodiments of the present invention; Figure 11 is a graphical representation of experimental results obtained with another resonant sensor after exposing the sensor to three different vapors, according to the embodiments of the present invention; Figure 12 is a graphical representation of experimental results obtained with a resonant sensor after exposure of the sensor to five different vapors, according to the embodiments of the present invention; - Figure 13 is a graphical representation of experimental results obtained with another resonant sensor after exposing the sensor to five different vapors, according to the embodiments of the present invention; and - Figure 14 is a graphical representation of experimental results obtained with a resonant sensor after exposing the sensor to three different vapors, according to the embodiments of the present invention;
    [0011] [011] In various embodiments, a pickup material can be arranged on a device surface configured as a resonant circuit, such as an inductor-condenser-resistor (“LCR”) sensor. Non-limiting examples of LCR sensors include RFID sensors with an integrated circuit memory chip (“IC”) and RFID sensors without an IC memory chip (for example, RFID sensors without a chip or LCR sensors without chip). LCR sensors may or may not have a wire. In order to collect data, an impedance spectrum of a resonant circuit is acquired in a frequency range, such as the resonant frequency range of the LCR circuit. In certain embodiments, an impedance response from the resonant circuit is acquired at a single frequency within the resonant frequency range of the LCR circuit. In certain embodiments, an impedance response from the resonant circuit is acquired at a single frequency within the resonant frequency range of the LCR circuit. The technique includes additionally calculating the multivariate signature of the acquired spectrum and manipulating the data to identify the presence of certain vapors. The presence of vapors is detected by measuring changes in dielectric, dimensional charge transfer and other changes in the properties of the materials used by observing changes in the resonant electronic properties of the circuit. Using multivariate analysis, a response of the capture material to the presence of a gaseous sterilizing agent can be simplified in a single data point allowing the recognition or detection of a gaseous agent. In certain embodiments, calibration models based on univariate analyzes are also used to recognize a specific gas and its concentration.
    [0012] [012] To describe the subject of the claimed invention more clearly and concisely, the following definitions are provided for specific terms that are used in the description below and in the appended claims.
    [0013] [013] The term "fluids" includes gases, vapors, liquids and solids.
    [0014] [014] The term "under analysis" includes any substance or chemical constituent that is subjected to chemical analysis. Examples of substances under analysis include, but are not limited to, chlorine dioxide, formaldehyde, hydrogen peroxide, peracetic acid, bromide methyl, ozone, ethylene oxide or any combination thereof In certain embodiments, the capture materials of the present invention can be configured to detect analytical substances related to "decontamination", "sterilization" and / or "fumigation". The terms "decontamination", "sterilization" and "fumigation" are correlated and all can refer to a process, method, procedure or course of action related to removing a contaminant, unwanted substance or other fluid from an environment. , a decontamination, sterilization and / or fumigation procedure may involve using a substance (for example, chlorine dioxide) to eliminate a contaminant (for example, bacteria) through a reaction, response or chemical process.
    [0015] [015] The term "monitoring process” includes, but is not limited to, measuring physical changes occurring around the sensor. For example, monitoring processes include monitoring changes in a biopharmaceutical, food or beverage manufacturing process related to changes in physical, chemical and / or biological properties of an environment around the sensor. Monitoring processes can also include those industry processes that monitor physical changes, as well as changes in a composition or component position. Non-limiting examples include monitoring property security, home protection monitoring, environmental, clinical or bedside monitoring, airport security monitoring, admission ticket issuance and other public events Monitoring can be performed when the sensor signal has reached a state response considerably stable and / or when the sensor has a dynamic response. Steady state sensor is a sensor response over a specified period of time, in which the response does not change considerably with the measurement time. In this way, steady state sensor response measurements over time produce similar values. The dynamic sensor response is a sensor response after a change in the measured environmental parameter (temperature, pressure, chemical concentration, biological concentration, etc.). In this way, the dynamic sensor response changes significantly with the measurement time to produce a dynamic response signature towards measured parameter or environmental parameters. Non-limiting examples of dynamic response signature include mean response slope, mean response magnitude, greater positive signal response slope, greater negative signal response slope, average change in signal response, maximum positive change in signal response and maximum negative change in signal response.
    [0016] [016] The term "multivariable sensor" is referred to in this document as a single sensor that can produce multiple response signals that are not substantially correlated with each other and in which those individual response signals from the multivariable sensor are further analyzed using tools of multivariate analysis to build response patterns of sensor exposure to different analytical substances at different concentrations In one embodiment, multivariate or multivariate signal transduction is performed on multiple response signals using multivariate analysis tools to build a pattern In certain embodiments, the multiple response signals comprise a change in capacitance and a change in resistance of a pickup material disposed in a multivariable sensor when exposed to a test substance. multiple response signals comprise a change in a capacitance, a change in a resistance, a change in an inductance or any combination of them.
    [0017] [017] The term "multivariate analysis" refers to a mathematical procedure that is used to analyze more than one sensor response variable and provide information on the type of at least one environmental parameter of the measured sensor parameters and / or quantitative information about the level of at least one environmental parameter of the measured sensor parameters. Non-limiting examples of multivariate analysis tools include canonical correlation analysis, regression analysis, non-linear regression analysis, principal component analysis, analysis of distinction function, multidimensional dimensioning, linear distinction analysis, logistic regression or neural network analysis.
    [0018] [018] The term "environmental parameters" is used to refer to measurable environmental variables within or close to a manufacturing or monitoring system. Measurable environmental variables comprise at least one of physical, chemical and biological properties and include, however, without limitation, mediation of temperature, pressure, material concentration, conductivity, dielectric property, various dielectric, metallic, chemical or biological particles in the vicinity or in contact with the sensor, ionization radiation dose and light intensity.
    [0019] [019] The term "spectrum parameters” is used to refer to measurable variables of the sensor response. The sensor response is the impedance spectrum of the LCR or RFID sensor. In addition to the measurement of the impedance spectrum in the form of parameters Z, S parameters and other parameters, the impedance spectrum (has both real and imaginary parts) can be analyzed simultaneously using several parameters for analysis such as the frequency of the maximum of the real part of the impedance (Fp), the magnitude of the real part impedance (Zp), the resonant frequency of the imaginary part of the impedance (F1), the anti-resonant frequency of the imaginary part of the impedance (F2), signal magnitude (Z1) in the resonant frequency of the imaginary part of the impedance (F1), magnitude of signal (Z2) at the anti-resonant frequency of the imaginary part of the impedance (F2), and frequency with zero reactance (Fz, frequency at which the imaginary part of the impedance is zero). Other spectral parameters can be m simultaneously edited using the entire impedance spectra, for example, resonance quality factor, phase angle and impedance magnitude. Collectively, the "spectrum parameters" calculated from impedance spectra can also be called "resources" or "descriptors." The appropriate selection of resources is carried out from potential resources that can be calculated from spectra.The multivariate spectrum parameters are described in US Patent 7,911,345 entitled "Methods and systems for calibration of RFID sensors," which is incorporated into this document as a reference.
    [0020] [020] The term "resonance impedance" or "impedance" refers to the sensor frequency response measured as real and imaginary parts of impedance around the sensor resonance from which the sensor "spectrum parameters" are extracted.
    [0021] [021] As used herein, the term "capture materials and capture films" includes, but is not limited to, materials deposited on a module of the transducer electronic devices, such as LCR circuit components or an RFID tag, for perform the predictable and reproducible function that affects the impedance sensor response through interaction with the environment.To prevent the material from leaching in the sensor film in the liquid environment, the capture materials are fixed to the sensor surface using standard techniques such as covalent bonding, electrostatic bonding and other standard techniques known to those skilled in the art.
    [0022] [022] The terms "transducer and sensor" are used to refer to electronic devices such as RFID and LCR devices designed for capture. The "transducer" is a device before being coated with a capture film or before being calibrated for a capture application. The "sensor" is a device typically after being coated with a capture film and after being calibrated for the capture application.
    [0023] [023] As used in this document, the term "RFID tag" refers to an identification and information technology that uses electronic tags to identify and / or track items to which the RFID tag can be attached. RFID typically includes at least two components, the first component of which is an integrated circuit memory (IC) chip for storing and processing information and modulating and demodulating a radio frequency signal. This memory chip can also be used for other specialized functions, for example, can contain a capacitor. It can also contain at least one input for an analog signal such as resistance input, capacitance input or inductance input. In the case of a non-chip RFID tag, the RFID tag can do not include an IC memory chip. This type of RFID tag can be useful in applications where an RFID tag does not need to be identified, but preferably a signal that and merely indicates the presence of the label provides useful information (for example, product safety applications). The second component of the RFID tag is an antenna for receiving and transmitting the radio frequency signal.
    [0024] [024] The term "RFID sensor" is an RFID tag with an added pickup function, such as when an RFID tag antenna also performs pickup functions by changing its impedance parameters as a function of environmental changes. Accurate determinations of environmental changes with these RFID sensors are carried out by resonance impedance analysis, for example, RFID tags can be converted into RFID sensors by coating the RFID tag with a capture film. of RFID with a pickup film, the electrical response of the film is translated into simultaneous changes in the impedance response, peak resonance position, peak width, peak height and peak symmetry of the sensor antenna impedance response; magnitude the real part of the impedance; resonant frequency of the imaginary part of the impedance; anti-resonant frequency of the imaginary part of the impedance; frequency of zero-reactance; angle phase and magnitude of impedance. The "RFID sensor" may have an integrated circuit (IC) memory chip attached to the antenna or it may not have an IC memory chip. An RFID sensor without an IC memory chip is an LCR sensor. A sensor of LCR is composed of known components, such as at least one inductor (L), at least one capacitor (C) and at least one resistor (R) in order to form an LCR circuit.
    [0025] [025] The term "reversibility" in relation to the sensor operation, as mentioned in this document, corresponds to the moment when the sensor returns to its natural or pre-exposure value as a result of the composition of metal oxide or any other capture composition material that prevents permanent changes in the sensor, so in the presence of a vapor, the sensor will respond accordingly, however, as the vapor concentration dissipates, the sensor response will return to the original value. , it is said that the capture material is reversible when the material exhibits a change of signal upon contact with a desired gas and returns to its original value, pre-exposure, upon removal of the gas. capture is not reversible when the material exhibits a change of signal upon contact with a desired gas and does not return to its original value upon removal of the gas concentration.
    [0026] [026] The term “dosimeter” in relation to sensor operation refers to a sensor that exhibits a cumulative signal change when exposed to high concentrations of vapor. The sensor signal increases as the vapor concentration increases, but the signal does not return to its original value after the vapor has been removed. In one embodiment, a dosimeter sensor can be configured as a disposable sensor.
    [0027] [027] The term “writer / reader” includes, but is not limited to, a combination of devices for writing and reading data in the memory of a memory chip and reading antenna impedance. Another term for "writer / reader" is "interrogator".
    [0028] [028] The term “prepare” in relation to a method for building a sensor or capture device refers to assembling, building, creating, assembling the components to build and / or partially completing a partial construction of a sensor or capture device capture, as mentioned in the present invention.
    [0029] [029] In accordance with the achievements disclosed in this document, an LCR sensor or an RFID sensor for gaseous capture agents is described. As discussed previously, semiconductor metal oxide capture materials can be arranged in a transducer and can be used to detect the presence of particular vapors. When a test substance comes into contact with semiconductor metal oxide, the test substance may undergo oxidation, reduction, adsorption, desorption or volume effects, which causes a change in resistance, a change in capacitance and / or a change in the inductance of the semiconductor metal oxide. According to the achievements disclosed in this document, changes in at least two of the dielectric properties of semiconductor metal oxide can be measured simultaneously from the inductive coupling of a sensor reader to a pickup coil with deposited pickup material that can detect the presence of chlorine dioxide or other gaseous agents. In certain embodiments, the pickup coil can serve as a pickup antenna.
    [0030] [030] Referring now to the Figures, Figure 1 shows two embodiments in which a sensor is specifically adapted to detect gaseous agents. Figure 1A illustrates an embodiment, in which the sensor 10 comprises a radio frequency identification (RFID) platform as a transducer. In addition, sensor 10 comprises a pickup material 12 disposed on an antenna 14, thereby altering the impedance response of sensor 10 when it is in the presence of a vapor. In another embodiment, the transducer may be an inductor-condenser-resistor (LCR) resonator, a thick shear mode resonator, an interdigital electrode structure or a general electrode structure. In one embodiment, the transducer can operate in a frequency range from several kilohertz (kHz) to several petahertz (PHz).
    [0031] [031] Figure 1B illustrates another embodiment that comprises a sensor 16 with an RFID platform as a transducer. In contrast to Figure 1A, a pickup material 18 is disposed only in a complementary pickup region 20 of sensor 16, instead of being arranged in the entire antenna 22. The complementary pickup region 20 is the region of sensor 16 in which antenna 22 and an integrated circuit memory chip (“IC”) 24 come into contact or overlap. The pickup material 18 disposed in the complementary pickup region 20 changes the impedance response of the sensor 16 when it is in the presence of a vapor. In another embodiment, the transducer used may be an inductor-condenser-resistor (LCR) resonator, a thick shear mode resonator, an interdigital electrode structure or a general electrode structure.
    [0032] [032] The complementary pickup region 20 has an advantage over the configuration shown in Figure 1A, in which the entire antenna 14 serves as an electrode structure. The relatively small size of the complementary pickup region 20 when compared to the entire antenna 22 leads to reduced costs of the applied pickup material. Also, it is relatively simple to manufacture a nanoscale size gap between electrodes in the complementary pickup region 20 if compared to the gap between electrode regions in the antenna 14, as shown in Figure 1A. 1A. Non-limiting examples of complementary sensors are interdigitalized sensors, resistant sensors and capacitor sensors. Complementary sensors are described in U.S. Patent 7,911,345 entitled “Methods and Systems for Calibration of RFID Sensors”, which is incorporated herein by reference.
    [0033] [033] For the detection of chlorine dioxide and other oxidants, both capture systems shown in Figures 1A and 1B can be used, where the selection depends on the sensitivity, response time, sensor cost and other performance parameters and / or manufacturing required. In one embodiment, the capture material 12 used is a semiconductor metal oxide formulation which is adapted to specifically detect a desired analyte.
    [0034] [034] As a non-limiting example, the capture material 12 used for chlorine dioxide includes a noble metal catalyst disposed in the semiconductor metal oxide. As a non-limiting example, the capture material 12 used for chlorine dioxide includes a noble metal catalyst disposed in the semiconductor metal oxide. Semiconductor metal oxide can include Indium oxide (In2O3), zinc oxide (ZnO), tungsten oxide (WO3), tin oxide (SnO2), titanium oxide (TiO2), and tin and indium oxide (ITO ). The noble metal catalyst can be any of the following: Platinum (Pt), Palladium (Pd), Gold (Au) and Silver (Ag). In certain embodiments, the uptake material 12 may consist of a core component and a layer, shell, or matrix component (s), as described in detail with reference to Figure 9.
    [0035] [035] In a given embodiment, a method of preparing the pickup material includes first doping the noble metal catalyst with the semiconductor metal oxide surface by impregnating moisture to form a metal oxide powder. In other embodiments, the noble metal catalyst can be doped with semiconductor metal oxide using in situ synthesis. In general, doping refers to introducing controlled amounts of impurities into a base composition in order to change its electrical properties to achieve a desired material performance. Here, the noble metal catalyst is arranged in the semiconductor metal oxide to change the electrical properties of the basic semiconductor metal oxide. In one embodiment, adding the noble metal catalyst to the semiconductor metal oxide causes the semiconductor metal oxide to simultaneously exhibit multiple responses when in the presence of a vapor. After the noble metal catalyst is doped with the semiconductor metal oxide, the resulting metal oxide powder is mixed with an aqueous solution of metal salts. Non-limiting examples of such metal salts are gold chloride, hydrogen hexachloroplatinate, silver nitrate and palladium chloride. Finally, the powders of final material are dried at a controlled temperature between 450 and 600 ° C in order to promote the decomposition of the metal precursor in the metallic form. In one embodiment, the weight percentage of the additive for the base metal oxide within the uptake material is in the range of 0.01% to 1%.
    [0036] [036] Semiconductor metal oxides can be synthesized using different approaches such as sol-gel, hydrothermal reaction and any others known in the art. In certain embodiments, SnCl4 can be used as the source of tin to create tin oxide (SnO2). SnCl4 can be dissolved in a water: ethanol solvent (1: 1 w / w), in which a few drops of hydrogen chloride solution are added until the pH is approximately 0.4. The pH of the resulting solution can be adjusted to 4.0 by adding 30% NH4OH while constantly stirring the mixture. The resulting precipitate is filtered and washed with water until it is free of any CLE, then it is initially dried at 100 ° C for 2 hours followed by calcination at 600 ° C for 4 hours.
    [0037] [037] In other embodiments, a mixture of zinc oxide and tungsten oxide can be manufactured by dissolving 3.00 g of sodium tungstate (Na2WO4-2H2O) and 0.05 g of hexadecyl trimethyl ammonium bromide (“CTAB” ) in 10 ml of deionized water (“DI”). Then, the 10 ml nitric acid solution (1.5 mol / l) can be added slowly to this solution and the resulting solution can be stirred for 2 hours. The precipitate produced can be collected by centrifugation. The precipitate is washed twice with DI water, washed three times with ethanol and dried in an oven at 80 ° C in order to produce tungsten acid. Then, 3.67 g of Zn (NO3) 2 and 0.10 g of CTAB are dissolved in 50 ml of DI water in order to obtain solution “A”. In addition, Na2CO3 (1.31 g) can also be dissolved in 50 ml of DI water in order to obtain solution "B." Solution B can be added dropwise to solution A with vigorous stirring After stirring for 1 hour, the precipitate is collected by centrifugation, then an appropriate amount of the formed tungsten acid can be mixed with zinc hydroxyl carbonate and the The mixture can be grounded for 0.5 hours. The mixture must be finally calcined at 600 ° C for 2 hours in air.
    [0038] [038] In certain embodiments, the semiconductor metal oxide doped with the noble metal catalyst can be dispersed directly in a solvent (eg, water, ethanol, isopropyl alcohol, acetone, toluene, hexane and 1-Methyl-2-Pyrrolidinone (NMP) or a combination thereof). The solvent includes a polymer matrix such as polyvinylidene fluoride (PVDF), polyvinyl alcohol (PVA) and acrylic based polymers using a deposition method. Some deposition methods include, but are not limited to, drop casting, spray coating, spin coating, flood coating, inkjet printing, direct writing, ink deposition and screen printing. The weight percentage of the polymer matrix for the semiconductor metal oxide within the uptake material is in the range of 0.1% to 99.9%, more preferably, 1% to 99% and, most preferably, 10% to 80%. The matrix can be a polymer matrix, an inorganic matrix or a composite matrix.
    [0039] [039] The combination and ratio of the polymer matrix to the semiconductor metal oxide in the composition can determine the uptake performance. In one embodiment, a desired capture performance may be to achieve a sensor response when the sensor is exposed to a concentration of analyte from about 30 ppm to about 300 ppm without exhibiting a response saturation of about 300 ppm. To develop a sensor that can achieve the desired uptake performance, a polymer matrix can be mixed with an active uptake material composed of tin and indium oxide to form a stable solvent dispersion. The polymer matrix semiconductor metal oxide dispersion can be deposited on the RFID transducer surface and dried to form capture films. Table 1 shows uptake performance of three different polymer matrix semiconductor metal oxide formulations for uptake of ClO2. Approximately 30 weight percent of the film was polymer. The Zp values of the sensors before depositing the sensor film were 800 ohms. Among the three polymer matrices tested, PVDF demonstrated excellent compatibility with indium and tin oxide and achieved the best detection sensitivity for ClO2 (dynamic resolution between 30 to 300 ppm).
    [0040] [040] Table 2 shows the sensor performance when different percentages of PVDF are included in the capture film. The combination of 67% PVDF and 33% indium and tin oxide achieved the most favorable ClO2 response of 30 to 300 ppm of ClO2, as it did not exhibit saturation at 300 ppm, while other capture films showed saturation at lower concentrations. at 300 ppm. Sensors with the formulation containing 67% PVDF also demonstrated reproducible sensor responses to the tested concentrations.
    [0041] [041] Metal oxide sensors can contain a metal oxide, a catalyst and a polymer, where the polymer serves as a binder. The polymer binder improves the adhesion of the uptake material to the substrate. In certain embodiments, the pickup material may contain a metal oxide, a catalyst and a polymer, in which the polymer serves as a matrix to control sensor sensitivity.
    [0042] [042] Figure 2 shows an embodiment of a complete system 30 configured to detect the presence of certain substances in gas analysis. In certain embodiments, a sensor 32 with a battery-free or passive RFID platform transducer is exposed to a substance under gaseous analysis. An RFID sensor impedance reader 34 and an IC memory chip reader 36 are housed within an RFID reader 38. A pickup coil 40 emits a magnetic field 42 in order to read the sensor response to the substance under analysis. In the presence of the test substance, the pickup material disposed in sensor 32 may incur a change in capacitance and a change in resistance that the pickup coil 42 magnetic field will detect. This process, in effect, writes and reads information on the IC memory chip reader 34, while the impedance Z (f) of sensor 32 is measured using a coupling inductor between the pickup coil 40 and sensor 32. In another In this embodiment, the sensor transducer can be an inductor-condenser-resistor resonator (LCR), a thick shear mode resonator, an interdigital electrode structure or a general electrode structure.
    [0043] [043] Figure 3 shows an example of a measured impedance spectrum that contains real parts Zre (f) 50 and imaginary parts Zim (f) 52 of the impedance spectrum 54. Furthermore, examples of the various spectrum parameters used for analysis multivariate are shown, frequency position (Fp) 56; magnitude of Zre (f) (Zp) 58; resonant frequency of Zim (f) (F1) 60 and anti-resonant frequency of Zim (f) (F2) 62. To accurately measure gases in the presence of uncontrolled temperature fluctuations, the real parts Zre (f) 50 and imaginary Zim (f ) 52 of the impedance spectra Z (f) 54 are measured from the sensor resonant antenna coated with a pickup material and various spectrum parameters are calculated from the Zre (f) 50 and Zim (f) 52 measurements, as shown in Figure 3. Multivariate analysis reduces the dimensionality of the complex impedance response measured from the real Zre (f) 50 and imaginary Zim (f) 52 parts of the complex impedance spectra 54 or calculated parameters Fp 56, Zp 58, F1 60, F2 62, for a single data point in multidimensional space. The only data point can identify an analyte that was present, while taking into account any fluctuations in ambient temperature. Self-correction against ambient temperature fluctuations with multivariable sensors is described in U.S. Patent Application No. 2012/0161787 entitled Temperature-Independent Chemical and Biological Sensors, which is incorporated herein by reference.
    [0044] [044] In one embodiment, multivariate analysis is performed as the principal component analysis ("PCA"). PCA is a mathematical procedure that is used to reduce multidimensional data sets to smaller dimensions (for example, a single variable) in order to simplify the analysis.The main component analysis is a part of eigenvalue analysis methods of statistical analysis of multivariate data and can be performed using a covariance matrix or correlation matrix. multivariate signature of the sensor response for different vapors is produced.The principal component analysis against data received from a sensor is described in US Patent 8,364,419 entitled Sensor Systems and Methods for Selective Analyte Detection Using Resonance Sensor Circuit, which is incorporated by reference in this document.
    [0045] [045] Figure 4 shows an embodiment of an experimental configuration 70, in which a sensor reader 72 is attached to a pickup coil 74 and a sensor 76 is housed within a gas flow cell 78 which is placed on top of the pickup coil 74. Sensor 76 can be a pickup coil or an antenna with a pickup film deposited. Experimental configuration 70 was used to obtain experimental data, as further described with reference to Figures 5, 6 and 10 to 14. In one embodiment, a flow of the analyte is controlled through the gas flow cell 78 to expose the sensor controlled concentration of the analyte. The gas flow cell 78 can be an airtight plastic box with an inlet and an outlet for the flow of the analyte. The gas flow cell 78 can be an airtight plastic box with an inlet and an outlet for the flow of analyte. When the test substance enters the gas flow cell 78, the sensor 76 can detect the test substance, by means of which the uptake material can exhibit a simultaneous response at an altered capacitance and resistance. The pickup coil 74 detects the change in capacitance and resistance of the pickup material deposited on the pickup coil or antenna 76 through inductive coupling between the pickup coil 74 and the sensor 76. The sensor reader 72 collects this data and performs multivariate analysis or univariate in order to alert the operator to the presence of the test substance.
    [0046] [046] Figure 5 shows a graphical representation of the results from testing an embodiment of the invention and, specifically, Figure 5 illustrates the reproducibility of a sensor response with respect to the experimental configuration mentioned above 70. For the purposes of the experiment, the generation of different concentrations of chlorine dioxide gas was carried out using a computer-controlled steam generation system. ClO2 was generated by a reaction of hydrochloric acid and sodium chlorite, with the principle, in which the working chemical reaction is: 5 NaClO2 + 4 HCl → 5 NaCl + 4 ClO2 + 2H2O.
    [0047] [047] During the experiment, the CO2 concentration in air was approximately 500 ppm through dilution with dry air and the relative humidity was maintained at approximately 40%. The sensors were exposed to ClO2 for a period of approximately thirty seconds. The responses resulting from three experiments are known in Figure 5. Each of the three experiments was conducted using a different sensor with the same capture film deposited manually. Figures 5A, 5B and 5C were produced using three different sensors, each with passive RFID platform transducer and 0.8% Pt of doped indium oxide as the capture material. As can be seen from Figure 5, each experiment produced similar results with only a few variations. An important aspect is that each sensor responded quickly to the exposure of the test substance and then returned to the original pre-exposure level. Therefore, Figure 5 illustrates the reversible feature of each of the three sensors.
    [0048] [048] Figure 6 similarly presents a graphical representation 90 of the results of an experiment using an embodiment of the invention. A sensor with a passive RFID platform transducer and a capture material with 0.8% Pt doped indium oxide was used to produce the results in Figure 6.
    [0049] [049] Additionally, the experimental setup used to produce the results in Figure 6 is illustrated in Figure 4. The flow rate of the test substance was 400 cc / min, so that the sensor was exposed to a concentration of 500 ppm of ClO2 for 30 seconds, followed by exposure to air at 40% humidity. The interval between exposures to ClO2 was 60 minutes.
    [0050] [050] Figure 6 specifically shows baseline stability or reversibility of the sensor response to three repeated measurements. The sensor response in the Figure is reversible, as it returned to its original level, pre-exposure 92, after removal of the test substance in each of the three measurements. In addition, repeated measurements were performed to determine sensor stability and the detection limit. The detection limit is a calculated value that represents the lowest concentration of an analyte that the sensor can detect. The detection limit (DL) was calculated for 8 ppm of ClO2, and was calculated on a signal for noise ratio of 3 using the measured values of ΔZp = 33.4 ohm, Std Zp = 0.18 ohm for DL = 8.1 ppm.
    [0051] [051] Figure 7 illustrates a graphical representation of the results from a test of an embodiment of the invention. Specifically, the Figure shows the response of a sensor that responds to increase ClO2 levels. During the experiment, the concentration of ClO2 in air was between 30 to 300 ppm with a range of 20 ppm which was controlled using dilution with dry air. The relative humidity was approximately 40%. The resolution of ClO2 concentration of this detected sensor was optimized based on the formulation ratio of the mixed metal oxide semiconductor and the polymer matrix. As a non-limiting example, to achieve a resolution of 20 ppm, the capture material formulation included in a base metal oxide, namely indium and tin oxide (ITO) and a polymer matrix, namely, fluoride of polyvinylidene (PVDF) with the formulation containing 3 mg of the semiconductor metal oxide and 67% of the polymer binder in 1-Methyl-2-Pyrrolidinone (NMP) solvent. The response resulting from three experiments with an exposure time of thirty seconds and an equilibrium time of 5 minutes for each level concentration is shown and the corresponding calibration graph was undertaken from these numbers. Figure 7 illustrates that after the last exposure to ClO2 the sensor signal slowly returns to its original baseline.
    [0052] [052] Figure 8 shows an equivalent circuit of a multivariable sensor 110 with an RFID platform transducer. Sensor 110 has a pickup coil 112 with LA 114 inductance, Ca 116 capacitance and Ra 118 resistance; a pickup antenna; a pickup material and an IC 120 chip with DC capacitance 122 and RC resistance 124. The complex permissiveness of the pickup material applied to the pickup region as shown in both Figure 1A and 1B is described as ε'r - j ε "r where the real part ε'r corresponds to the energy storage capacity of the capture material and the imaginary part ε "r is directly proportional to the conductivity □. Therefore, the uptake material exhibits a capacitance response through the real ε'r part of the complex permissiveness and the uptake material displays the resistance response through the imaginary part ε'7 of the complex permissiveness. The real part of the complex permissiveness corresponds to the energy storage capacity of the capture material that is proportional to the capacitance of the capture material. Additionally, because the imaginary part of the complex permissiveness proportional to the conductivity is inversely proportional to the resistance, since the conductivity and the resistance are inversely related. In this way, by measuring the complex permissiveness of the pickup material, the response of the pickup material 'to both a change in resistance and a change in capacitance can be measured.
    [0053] [053] The sensor also has the ability to obtain accurate measurements at ambient temperatures although fluctuations in temperature may occur. Variations in ambient temperature produce independent effects on the different components of the equivalent circuit in Figure 8. However, these independent effects are correlated with the spectral resources of the resonance impedance spectra and are resolved by the sensor's multivariate response.
    [0054] [054] Examples of multivariable pickup material models for embodiments of the present invention are shown in Figure 9. To produce a multivariate response, the materials can have a steam inert core or an active steam core that can include a first component 130. The first component 130 is surrounded with a complete covering layer, shell or matrix that can include a second component 132, (for example, as shown in Figure 9A) or an incomplete covering layer, shell or matrix (for example, as shown in Figures 9B and 9C). In certain embodiments, the layer, shell or matrix may include the second component 132 and a third component 134, as shown in Figure 9C. 9C. In other embodiments, the layer, shell, or matrix may include more than two components. The number of components in the multivariable capture material can be between 1 and 20, where each component performs a different function in the capture film. The first component 130 of the multivariable uptake material may include nanoparticles, microparticles, nanowires and nanotubes. The material of the first component 130 can be a conductive material, a semiconductor material or a non-conductive material. The shape of the first component 130 can be controlled or random. In addition, the dimensions of the first component 130 may be unaffected by exposure to steam or the first dimensions of component 130 may be affected by exposure. If affected by exposure to vapor, the first dimensions of component 130 may contract or swell or exhibit a change in a dielectric property, an electrical property and / or an optical property.
    [0055] [055] The layer, wrapper or matrix may be a conformal layer, a monolayer or a non-conformal layer that includes at least one nanoparticle, microparticle, nanowire or nanotube. In addition, a filler matrix can fill a pore between the first component 130 and the layer, shell or matrix. The second component 132 and / or the third component 134 can be a conductive material, a semiconductor material or a non-conductive material. The shape of the layer, wrapper or matrix attributes can be controlled or random. The dimensions of the layer, shell or matrix may be unaffected by exposure to a vapor or the dimensions of the layer, shell or matrix may be affected by vapors. If affected by exposure to vapor, the layer shell or matrix dimensions may contract or swell or exhibit a change in a dielectric property, an electrical property and / or an optical property.
    [0056] [056] In certain embodiments, the multivariable uptake material may include a hybrid structure, so that more than two materials (eg metal oxides, metal oxide frames, organic bound capped nanoparticles, capped inorganic bonded nanoparticles, nanoparticles capped polymeric binders or mixed metal oxides) are connected by a physical bond or strong interaction. Hybrid multivariable uptake materials may have micro- or nano-structural resources such as physical interactions between conductive noble metals, conductive organic polymeric materials and functionalized nanomaterials.
    [0057] [057] Figure 10 is a graphical representation 140 of experimental results obtained with a resonant sensor after exposure of the sensor to three different vapors. The experimental setup 70 used to produce the results in Figure 10 is illustrated in Figure 4. Figure 10 represents a response from sensor 76 to various vapors (for example, ammonia, methanol and chlorine), where sensor 76 has a material of uptake of mixed WO3-ZnO oxide. The experiment was conducted at 400 ° C and the sensor 76 was operated in a resonant mode to measure resonant spectra. The vapors tested were chlorine in concentrations of 10, 20 and 40 ppm, methanol in concentrations of 15, 30 and 60 ppm, and ammonia in concentrations of 20, 40 and 80 ppm. The sensor response 76 was measured as real and imagined parts of the resonance impedance. Figure 10 shows a scores graph 140 after principal component analysis of various responses from sensor 76. This graph 140 shows that sensor 76 can distinguish between the three different vapors to which sensor 76 has been exposed.
    [0058] [058] Figure 11 is a graphical representation of 150 experimental results obtained with another resonant sensor after exposing the sensor to three different vapors. The experimental setup 70 used to produce the results in Figure 11 is illustrated in Figure 4. Figure 11 represents a response from sensor 76 to various vapors (for example, ammonia, methanol and methyl salicylate (MeS)), where the sensor 76 has a Pt metal oxide uptake material doped with Ι1Ί2Ο3. The experiment was conducted at 300 ° C and the sensor 76 was operated in a resonant mode to measure resonant spectra. The vapors tested were ammonia at concentrations of 20, 40 and 60 ppm, methyl salicylate in concentrations of 15, 30 and 45 ppm and methanol in concentrations of 100, 200 and 300 ppm. The sensor response 76 was measured as real and imagined parts of the resonance impedance. Figure 11 shows a score chart 150 after principal component analysis of various responses from sensor 76. This chart 150 shows that sensor 76 can distinguish between the three different vapors to which sensor 76 has been exposed.
    [0059] [059] Figure 12 is a graphical representation 160 of experimental results obtained with another resonant sensor after exposure of the sensor to five different vapors. The experimental setup 70 used to produce the results in Figure 12 is illustrated in Figure 4. Figure Figure 12 represents a sensor 76 response to various vapors (for example, hydrogen peroxide, ethanolamine, water, chlorine dioxide and ammonia) , in which the sensor 76 has a SnO2-Pd compound capture material. The experiment was conducted at 300 ° C and the sensor 76 was operated in a resonant mode to measure resonant spectra. The vapors tested were hydrogen peroxide, ethanolamine, water, chlorine dioxide, ammonia and water. The concentrations of the tested vapors were 1/8, 1/4 and 1/2 P / Po, where P is the partial vapor pressure and Po is the saturated vapor pressure. The sensor response 76 was measured as real and imagined parts of the resonance impedance. Figure 12 shows a score graph 160 after principal component analysis of various responses from sensor 76. This graph 160 shows that sensor 76 with SnO2-Pd as the capture material can distinguish between the five different vapors to which sensor 76 was exposed.
    [0060] [060] In certain embodiments, a SnO2-Pd compound is synthesized by dissolving sodium stannate trihydrate (eg 2 g) in DI water (eg 15 ml). D-glucose monohydrate (for example, 1 g) is added to the sodium stannate trihydrate and the water mixture and is stirred overnight at 60 ° C in an oil bath. The formation of white precipitate is collected by centrifugal separation and is followed by washing with DI water. The collected nanoparticle is dried by lyophilization overnight. About 300 mg of SnO2 is dispersed in 30 ml of water. For that mixture, sodium tetrachloropaladate (for example, 7 mg) is added, followed by an addition of sodium borohydride (for example, 8 mg). This procedure produces a final non-composite structure with a Pd ratio of 0.8%. This reaction mixture can be stirred overnight and purified from the final nanoparticles using centrifugal washing.
    [0061] [061] Figure 13 is a graphical representation 170 of experimental results obtained with another resonant sensor after exposure of the sensor to five different vapors. The experimental setup 70 used to produce the results in Figure 13 is illustrated in Figure 4. Figure 13 represents a sensor 76 response to various vapors (eg hydrogen peroxide, ethanolamine, water, chlorine dioxide and ammonia), in that sensor 76 has only SnO2 as a composite pickup material. The experiment was conducted at 300 ° C and the sensor 76 was operated in a resonant mode to measure resonant spectra. The vapors tested were hydrogen peroxide, ethanolamine, water, chlorine dioxide, ammonia and water. The concentrations of the tested vapors were 1/8, 1/4 and 1/2 P / Po, where P is the partial vapor pressure and Po is the saturated vapor pressure. The sensor response 76 was measured as real and imagined parts of the resonance impedance. Figure 13 shows a graph of scores 170 after principal component analysis of various responses from sensor 76. This chart 170 shows that sensor 76 with SnO2 as the capture material can distinguish between the five different vapors to which sensor 76 was exposed .
    [0062] [062] Figure 14 is a 180 graphical representation of experimental results obtained with a resonant sensor after exposure to three different vapors. The experimental setup 70 used to produce the results in Figure 14 is illustrated in Figure 4. Figure 14 represents a response from sensor 76 to various vapors (eg, ethanol, methyl ethyl ketone, and water), where sensor 76 has a silver ink that has silver nanoparticles as a pickup material. The silver nanoparticles were about 20 nm in diameter and had a polyvinylpyrrolidone polymer shell. The experiment was conducted at room temperature (for example, approximately 20 ° C) and sensor 76 was operated in a resonant mode to measure resonant spectra. The vapors tested were ethanol, methyl ethyl ketone and water. The concentrations of the tested vapors were 1/8, 1/4 and 1/2 P / Po. The sensor response 76 was measured as real and imagined parts of the resonance impedance. Figure 14 shows a graph of scores 180 after principal component analysis of various responses from sensor 76. This graph 180 shows that sensor 76 with silver nanoparticles that has a polyvinylpyrrolidone shell uptake material can distinguish between the three different vapors to which sensor 76 was exposed.
    [0063] [063] While only certain features of the invention have been illustrated and described in this document, many modifications and changes will occur to the technician in the subject. Therefore, it should be understood that the attached claims are intended to cover all such modifications and changes as long as they fall within the scope of the invention.
    权利要求:
    Claims (13)
    [0001]
    SENSOR (10, 36, 76, 110) CONFIGURED TO DETECT A GASEOUS AGENT, comprising: - a transducer, in which the transducer comprises a resonant electrical circuit that forms an antenna (14, 22); and - a pickup material (12, 18) disposed at least in the portion of the transducer, wherein the pickup material (12, 18) comprises an adjustable polymer additive configured to allow the pickup material (12, 18) to reach a improved detection performance, and in which the pickup material (12, 18) is configured to display both a capacitance response and a resistance response when exposed to a gaseous agent; Where - the capture material (12, 18) comprises a semiconductor metal oxide, where the semiconductor metal oxide is a semiconductor compound metal oxide, characterized by the capture material (12, 18) further comprising a noble metal catalyst deposited in the semiconductor metal oxide and a polymer matrix, where the polymer matrix is configured to control the sensitivity of the sensor.
    [0002]
    SENSOR (10, 36, 76, 110) according to claim 1, characterized in that the gaseous agent is a sterilizing agent, a fumigation agent or a decontamination agent.
    [0003]
    SENSOR (10, 36, 76, 110) according to any one of claims 1 to 2, characterized in that the capture material (12, 18) has a reversible response when exposed to the gaseous agent.
    [0004]
    SENSOR (10, 36, 76, 110) according to any one of claims 1 to 3, characterized in that the capture material (12, 18) is configured to measure a concentration of the gaseous agent as a dosimeter providing a sensor signal that increases as the vapor concentration increases, but does not return to its original value after removal of the vapor.
    [0005]
    SENSOR (10, 36, 76, 110) according to any one of claims 1 to 4, characterized in that the capture material (12, 18) comprises metal nanoparticles coated at least in part with an organic layer.
    [0006]
    SENSOR (10, 36, 76, 110) according to any one of claims 1 to 5, characterized in that the noble metal catalyst is any one of the following: platinum, palladium, gold, silver, ruthenium or any combination thereof and where the semiconductor metal oxide is any of the following: In2O3, ZnO, WO3, SnO2, TiO2, Fe2O3, Ga2O3 and Sb2O3 or a combination of one or more metals that includes In2O3 with SnO2, In2O3 with ZnO, SnO2 with ZnO .
    [0007]
    SENSOR (10, 36, 76, 110), according to any one of claims 1 to 6, characterized in that the weight percentage of noble metal catalyst for semiconductor metal oxide is in the range of 0.01% to 1%.
    [0008]
    SENSOR (10, 36, 76, 110) according to any one of claims 1 to 7, characterized in that the sensor (10, 26, 76, 110) is configured to operate at an ambient temperature between -40 ° C to 1000 ° C .
    [0009]
    SENSOR (10, 36, 76, 110) according to any one of claims 1 to 8, characterized in that the transducer is a passive RFID platform transducer, an inductor-capacitor-resistor (LCR) resonator, a mode resonator thick shear, an interdigital electrode structure or an electrode structure.
    [0010]
    SENSOR (10, 36, 76, 110), according to any one of claims 1 to 9, characterized in that the pickup material (12, 18) is arranged in a complementary pickup region of the sensor instead of the entire antenna ( 14, 22).
    [0011]
    METHOD FOR PREPARING A CONFIGURED SENSOR TO DETECT A GASEOUS AGENT, characterized by comprising: - mount a transducer with an antenna (14, 22) on a substrate; - doping a noble metal catalyst to a semiconductor metal oxide to form a metal oxide powder; - mixing the metal oxide powder with an aqueous solution of a polymer matrix to form a stable metal oxide suspension; - deposit the metal oxide suspension on the transducer; and - drying the metal oxide suspension to form a pickup material (12, 18), and - where the capture material (12, 18) further comprises a polymer matrix, where the polymer matrix is configured to control the sensitivity of the sensor, and where the semiconductor metal oxide is a semiconductor compound metal oxide.
    [0012]
    METHOD, according to claim 11, characterized by the fact that the noble metal catalyst is any one of the following: platinum, palladium, gold, silver, ruthenium or any combination thereof.
    [0013]
    METHOD according to any of claims 11 to 12, characterized by the fact that the noble metal catalyst is deposited on the semiconductor metal oxide using moisture impregnation or local synthesis.
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    同族专利:
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    KR20160081826A|2016-07-08|
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    TWI678531B|2019-12-01|
    TW201629478A|2016-08-16|
    JP2016128803A|2016-07-14|
    US9678030B2|2017-06-13|
    BR102015032845A2|2016-07-05|
    EP3040716A1|2016-07-06|
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    WO2002068947A2|2000-10-16|2002-09-06|E.I. Du Pont De Nemours And Company|Infrared thermographic screening technique for semiconductor-based chemical sensors|
    EP1864122A2|2005-03-18|2007-12-12|Nano-Proprietary, Inc.|Gated gas sensor|
    US8318099B2|2005-10-26|2012-11-27|General Electric Company|Chemical and biological sensors, systems and methods based on radio frequency identification|
    KR100812357B1|2005-12-23|2008-03-11|한국과학기술연구원|Ultra-sensitive metal oxide gas sensor and fbrication method thereof|
    US8636883B2|2006-03-10|2014-01-28|Element One, Inc.|Monitorable hydrogen sensor system|
    WO2008041983A2|2006-10-05|2008-04-10|University Of Flordia Research Foundation, Inc.|System for hydrogen sensing|
    US20090020422A1|2007-07-18|2009-01-22|Honeywell International, Inc.|Sensor Assemblies For Analyzing NO and NO2 Concentrations In An Emission Gas And Methods For Fabricating The Same|
    US7911345B2|2008-05-12|2011-03-22|General Electric Company|Methods and systems for calibration of RFID sensors|
    TWI374265B|2008-12-01|2012-10-11|Ind Tech Res Inst|Gas sensor|
    US8364419B2|2009-04-15|2013-01-29|General Electric Company|Sensor system and methods for selective analyte detection using resonance sensor circuit|
    US9052263B2|2009-04-15|2015-06-09|General Electric Company|Methods for analyte detection|
    US8736425B2|2009-10-30|2014-05-27|General Electric Company|Method and system for performance enhancement of resonant sensors|
    US20120166095A1|2010-12-23|2012-06-28|General Electric Company|Highly selective chemical and biological sensors|
    US8542024B2|2010-12-23|2013-09-24|General Electric Company|Temperature-independent chemical and biological sensors|
    US9239346B2|2012-01-28|2016-01-19|The Regents Of The University Of California|Systems for providing electro-mechanical sensors|
    US9494541B2|2012-07-05|2016-11-15|General Electricity Company|Sensors for gas dosimetry|
    CN104034763A|2014-05-28|2014-09-10|南京工业大学|Noble metal doped particles and metallic oxide film integrated gas sensor and preparation method thereof|US8568027B2|2009-08-26|2013-10-29|Ut-Battelle, Llc|Carbon nanotube temperature and pressure sensors|
    US9876183B2|2015-01-30|2018-01-23|Northwestern University|Charge-transporting metal oxide-polymer blend thin films|
    US20170052161A1|2015-08-19|2017-02-23|Invensense, Inc.|Gas sensing material for a gas sensor device|
    US10578572B2|2016-01-19|2020-03-03|Invensense, Inc.|CMOS integrated microheater for a gas sensor device|
    US9824252B1|2016-05-13|2017-11-21|Xerox Corporation|Chemical sensors based on chipless radio frequency identificationarchitectures|
    US10383967B2|2016-11-30|2019-08-20|Invensense, Inc.|Substance sensing with tracers|
    US10739211B2|2016-12-16|2020-08-11|Vdw Design, Llc|Chipless RFID-based temperature threshold sensor|
    US10436737B2|2017-01-17|2019-10-08|Matrix Sensors, Inc.|Gas sensor with humidity correction|
    US10060872B1|2017-02-13|2018-08-28|General Electric Company|Sensing system and method|
    EP3370073B1|2017-03-01|2020-04-29|ABB Power Grids Switzerland AG|Method and device for determining capacitive component parameters|
    RU2642158C1|2017-06-09|2018-01-24|Общество с ограниченной ответственностью "ЭкоСенсор"|Method of obtaining nanostructured gas sensor for ozone|
    EP3622288A1|2017-06-13|2020-03-18|General Electric Company|Dissolved gas analysis with impedimetric gas sensor|
    WO2019040422A1|2017-08-21|2019-02-28|Avery Dennison Retail Information Services, Llc|Rfid based energy monitoring device|
    RU2020124115A|2018-01-11|2022-02-11|Шелл Интернэшнл Рисерч Маатсхаппий Б.В.|WIRELESS MONITORING AND PROFILE OF REACTOR PARAMETERS USING A PLATE OF SENSORED RFID TAGS WITH KNOWN LOCATIONS|
    CN108490040A|2018-02-23|2018-09-04|天智羲王管道科技有限公司|Graphene gas is printed on one side capacitive sensing structure|
    EP3791164A1|2018-05-11|2021-03-17|Carrier Corporation|Surface plasmon resonance gas detection system|
    CN109030564B|2018-06-04|2021-05-11|深圳大学|Transistor type formaldehyde sensor and manufacturing method thereof|
    CN108663417B|2018-06-22|2019-09-13|山东大学|One kind being directed to low concentration of NO2The novel I n of gas2O3/Sb2O3Composite hollow nanotube gas sensitive|
    US20210262965A1|2018-06-25|2021-08-26|Nanoscent Ltd.|Particles for chemiresistor sensor|
    GB2577073A|2018-09-12|2020-03-18|Univ Of Northumbria At Newcastle|Characterisation method and apparatus|
    US10872238B2|2018-10-07|2020-12-22|General Electric Company|Augmented reality system to map and visualize sensor data|
    CN109467127A|2018-10-31|2019-03-15|青岛大学|A kind of preparation method of more Metal Supported tungsten oxide composite nano-lines|
    CN112881485B|2021-01-14|2021-12-17|西安电子科技大学|GaN sensor for detecting hypochlorite and detection method|
    法律状态:
    2016-07-05| B03A| Publication of an application: publication of a patent application or of a certificate of addition of invention|
    2020-03-10| B06U| Preliminary requirement: requests with searches performed by other patent offices: suspension of the patent application procedure|
    2020-09-15| B09A| Decision: intention to grant|
    2020-12-01| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 29/12/2015, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    US14/586,485|US9678030B2|2014-12-30|2014-12-30|Materials and sensors for detecting gaseous agents|
    US14/586,485|2014-12-30|
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