RU91763U1 - DIFFERENTIAL GAS SENSOR - Google Patents

Abstract

1. A differential gas sensor, including a measuring and supporting arms, each of which contains a dielectric substrate, on one side of which a tape heater is applied with contacts for connection to a power source, and on the other a gas-sensitive element with contact leads for connection with a measuring unit, characterized in that the gas-sensitive element in the measuring and supporting arms is made in the form of gas-sensitive films of the same semiconductor material, the indicator R the ratio of the concentration of acceptor centers with an acid constant constant value pKa = 3.3 to the center concentration with an acid constant constant in the range pKa 6.4-6.8 in the material of the measuring arm differs no less than 10-15 times from the same R supporting shoulder material. ! 2. The sensor according to claim 1, characterized in that antimony doped tin oxide is used as the semiconductor material of the gas-sensitive films. ! 3. The sensor according to claim 1, characterized in that the concentration of antimony in the gas-sensitive film material is from 0.2 to 0.4 wt.% For the measuring arm and beyond this interval for the supporting arm. ! 4. The sensor according to claim 3, characterized in that the concentration of antimony in the gas-sensitive film material for the support arm is from 0.04 to 0.12 wt.% Or from 0.4 to 0.5 wt.%. ! 5. The sensor according to claim 1, characterized in that the gas-sensitive films are deposited on a dielectric substrate by the method of thick-film technology. ! 6. The sensor according to claim 1, characterized in that the dielectric substrate is made of heat-resistant ceramic, for example from

Description

The utility model relates to the field of analytical instrumentation, namely, semiconductor sensitive elements of gas analyzer sensors designed to determine the content of gaseous toxic substances and various impurities in the air, in particular, carbon monoxide, hydrogen sulfide, methane and others.

As you know, one of the disadvantages of such sensitive elements (sensors) is the drift of the base signal level, depending, for example, on the operating time, temperature, and relative humidity. To eliminate this drawback, it is advisable to use a differential measurement scheme.

There are known sensors with differential type sensors manufactured by domestic industry, for example, Avangard NPO, St. Petersburg (see the product catalog on the Internet link http://www.avangard-gas.ru), in which the gas concentration is measured by the difference in the adsorption catalytic activity of the semiconductor in the reference and measuring arms of the differential circuit of the sensor. However, the use of catalytic processes, which the sensor detects, significantly reduces the service life of the sensors due to the very high tendency of the catalysts to “poison” with gas impurities of the ambient air and, thereby, to a partial loss of catalytic activity.

A known gas sensor is known in which a difference signal (voltage jump) occurs when gas is adsorbed on sensitive layers of a sensor having semiconductors with different types of conductivity, p or n, in the measuring and reference arms (see Japan Application No. 2006133007, IPC G01N 27/12 ; G01N 27/04, publ. 25.05.2006). This device, mounted in a gas analyzer operating by the gas flow method, well captures a change in the polarity of the voltage jump at the pn junction.

However, the use of different materials (n- and p-semiconductors) in the sensor circuit can lead to a difference in reaction to possible random factors, such as gas impurities, changes in humidity and ambient temperature, etc.), which leads to a zero level drift , which was mentioned above, and does not allow the device to work in the mode of measuring the gas concentration level, that is, the device can only perform the functions of a gas detector. In addition, the forced gas flow used in the instrument limits its use for portable and portable gas analyzers using the natural diffusion of the analyzed gas.

The above problem can be solved by changing the sensitivity (sorption activity) of the same sensor material, increasing it in the measuring arm of the differential circuit and lowering it in the reference one.

To increase the sensitivity of the sensor can, for example, by increasing the specific surface of the gas-sensitive film, as is done in the sensor for determining the concentration of gases according to the patent of the Russian Federation for invention No. 2096774, IPC G01N 27/12, publ. November 20, 1997, in which the entire surface of the gas-sensitive element is made in the form of a layer of alternating microroughnesses having a sawtooth profile obtained by ion or plasma etching. This solution makes it possible to increase the response to the detected gases, but complicates and increases the cost of the sensor manufacturing technology.

Increases in the specific surface area of a sensitive element by Hae-Ryong Kim, Kwon-Il Choi, Jong-Heun Lee, Sheikh A. Akbar “Highly sensitive and ultra-fast responding gas sensors using self-assembled hierarchical SnO ₂ spheres”, “Sensors and Actuators B: Chemical ”v.136, 2009, p.138-143) are obtained by hydrothermal synthesis of tin dioxide particles, in which needles are formed on the surface of SnO ₂ microspheres. However, according to the method proposed by them, particles with a composition different from tin dioxide, in particular Sn ₃ O ₄ , are formed, which indicates the presence of oxides in which tin is in a lower oxidation state. When using the material as a gas-sensitive film, its heating is used, and under such conditions Sn ^{+ 2} , for example, is oxidized by atmospheric oxygen, passing into a higher valence state of Sn ^{+ 4} , while the sensor properties of the particles change for the worse.

The sensitivity of the sensor can also be increased by modifying the surface of the sensitive layer.

A known method of modifying the surface of the sensing element of a gas sensor by applying catalysts to its surface, for example, according to RF patent No. 2343470, IPC G01N 27/12, publ. January 10, 2009. In the specified sensitive element, the metal oxide gas sensitive film includes ruthenium dioxide, iron oxide and copper oxide in a certain ratio of components. This film composition makes it possible to provide a high degree of sensitivity and selectivity of the sensor, however, in the general case, the catalysts significantly change the nature of the sensor material (in particular, its thermophysical properties), therefore, this modification method is unacceptable because of the differential measurement scheme. Such a scheme assumes that the material properties are identical on both arms of the sensing element, with the exception of the value of the resistive response to the detected gas.

Sensitivity can also be increased by doping a metal oxide semiconductor.

A known sensor for determining the concentration of gases according to the patent of Russian Federation No. 2291416, IPC G01N 27/12, publ. September 10, 2008. This sensor, which consists of a rough dielectric substrate with a platinum heater on one side and a gas-sensitive element in the form of a 100 nm thick film based on tin dioxide doped with indium and antimony in equal proportions, was manufactured magnetron sputtering (thin-film technology). Having better sensitivity compared to similar thin-film sensors, these films, however, are uncompetitive with respect to films made according to thick-film technology and having a porous structure, i.e. a larger contact area with the studied gases with the same geometric dimensions of the sensor film.

There are known attempts to solve this problem by creating multilayer thin-film sensor coatings (see, for example, A. Teeramongkonrasmee, M. Sriyudthsak "Methanol and ammonia sensing characteristics of sol-gel derived thin film gas sensor", "Sensors and Actuators B: Chemical", v. 66, 2000, p. 256-259). This technique allows you to increase the sensitivity of the sensor film, but still it is much lower than that of films formed by thick-film technology, because the sensitivity of the material depends on its porosity.

The closest in technical essence to the claimed is a gas sensor according to Japanese application No. 2006133007, mentioned above, in which a differential measurement scheme is used, including measuring and reference arms, in which semiconductors with different types of conductivity are used - p or n.

Each arm of the sensor contains a dielectric ceramic substrate, on one side of which a ribbon heater is applied by spraying with contacts for connection to a power source, and on the other a gas-sensitive element with contact leads for connection with a measuring unit, this element in the measuring and supporting arms made of semiconductors with different types of conductivity - p or n. Then, both arms of the sensor are installed in such a way that their sensory surfaces are facing each other with the formation of a closed module containing two pn junctions, and the gaseous medium under investigation is pumped along the contact line of the shoulders along the annular channel.

As noted above, the use of various materials (n- and p-semiconductors) in this sensor leads to different reactions of gas-sensitive elements of the sensor arms to possible random factors, such as changes in humidity and ambient temperature, the presence of gas impurities, etc., and thereby, to a bias (drift) of the zero level, which significantly affects the stability of the characteristics of the sensor as a whole and reduces the reliability of the results.

The utility model solves the problem of creating a sensor for gas analyzers, which allows to increase the reliability of the data obtained through the use of a differential measurement scheme and is highly sensitive to various gases. In addition, the technical result of the invention is to simplify the design and increase the manufacturability of the sensor.

The technical result is achieved by the fact that in the differential sensor sensor, including the measuring and supporting arms, containing a dielectric substrate, on one side of which a tape heater is applied with contacts for connecting to a power source, and on the other a gas-sensitive element with contact leads for connecting to the measuring unit According to the invention, the gas sensitive element in the measuring and supporting arms is made in the form of gas sensitive films from the same semiconductor material ala, wherein R component ratio of the concentration of acceptor centers with acidity constant index value pK _a = 3.3 to a concentration centers with metric value acidity constant pKa in the range of 6.4-6.8 _and a measuring arm material differs by at least 10 -15 times from the same indicator R in the material of the supporting arm.

Antimony doped tin oxide was used as the semiconductor material of gas-sensitive films, while the concentration of antimony in the gas-sensitive film material is from 0.2 to 0.4 wt.% For the measuring arm and going beyond this interval for the supporting arm. In particular, the concentration of antimony in the material of the gas-sensitive film for the supporting arm is from 0.04 to 0.12 wt.%, Or from 0.4 to 0.5 wt.%.

In addition, gas-sensitive films were deposited on a dielectric substrate by the method of thick-film technology, and the dielectric substrate was made of heat-resistant ceramics, for example, polycor, and made rough from the side of gas-sensitive films.

In addition, to increase the specific surface in the manufacture of gas-sensitive films, the material of each arm of the sensor is pre-treated with a finely dispersed sol, including the dispersed phase of the same chemical composition as the material of the corresponding gas-sensitive film, and ashless burnout of the dispersion medium.

The essence of the utility model is that the sorption activity of the sensor material in the sensor’s supporting and measuring arms is purposefully changed in the inventive sensor by changing the ratio (R) of the concentrations of the acceptor and donor centers responsible for gas adsorption.

The utility model is illustrated by drawings, where in Fig.1 shows a General view of the sensor sensor (side view); figure 2 is the same, a top view; figure 3 is a graph of the dependence of the sorption activity of the surface of the gas-sensitive film on the concentration of antimony.

The sensor consists of a dielectric, mainly ceramic, substrate 1, on one side of which a tape heater 2 with contact pads for connecting to a power source (not shown) is applied, and on the other side of the substrate 1, the method of thick-film technology is applied at some distance from another gas-sensitive (sensory) film 3 of the supporting arm and gas-sensitive film 4 of the measuring arm. At one end, each of the films 3 and 4 is in contact with a common bus 5, which is their common point in the electrical circuit, and the other ends of these films are connected to the contact pads 6.

Thick-film technology can also be used when applying a tape heater. To fix the applied film materials, the sensor (microchip) is dried and annealed in an oven at a temperature of 800-850 ° C.

The dielectric substrate 1 is made of a heat-resistant ceramic material, for example, of polycor (polycrystalline alumina) with a thickness of about 0.3 mm. Moreover, the side of the substrate 1, on which the gas-sensitive films 3 and 4 are applied, is roughened in order to increase its adhesion to the film.

The belt heater 2 can be made, for example, of platinum, or ruthenium, or palladium, or their alloys, and applied to the substrate 1, for example, in the form of a meander, comb, diagonally of the substrate or in any other configuration.

The gas-sensitive films 4 and 5 are made of a semiconductor material based on tin oxide SnO ₂ with a different concentration of dopant, which is used as antimony, which is introduced into the crystal lattice of the base material (SnО ₂ ) by co-precipitation of hydroxides of both metals.

As is known, acceptor centers (or Lewis acid centers) in semiconductor materials are localized on surface incompletely coordinated metal atoms (in this case, Sn ⁺⁴ and Sr ⁺² ), which have vacant levels capable of accepting an electron pair.

The strength of acid acceptor centers (acceptor ability) can be characterized by an indicator of acidity constant - pK _a . The distribution q (mg · eq / g) of the concentration of centers on the value of pK _a is, therefore, a fairly complete characteristic of the surface of the particles of the sensor material. As the studies showed, the gas-sensor properties of the synthesized material are directly dependent on the ratio R of the concentration of centers with a pK value of _a = 3.3 to the concentration of centers in the range of pK _{a of} 6.4-6.8. In this case, an increase in the sensitivity of the material is proportional to the change (growth) of R.

Alloying SnO ₂ with antimony, in addition to imparting to the material the properties of an impurity semiconductor having a higher level of resistive response to gas sorption, when heated, it induces redox processes leading to the formation of new acceptor centers (Sr ^{+ 2} ) with slightly different properties than the properties of the centers of the doped intrinsic semiconductor (Sr ⁺⁴ ).

By changing the concentration of the dopant, one can achieve a targeted change in the sensitivity of the material (increase for the measuring arm of the sensor and decrease for the reference).

To do this, in the process of manufacturing a gas-sensitive film for one sensor arm, coprecipitation of tin and antimony hydroxides is carried out in the required calculated proportions, followed by washing, drying and calcination (heat treatment) of the obtained material at 600 ° C for 2 hours. Then, by the method of photocolorimetry in the SnO ₂ : Sb sample, the distribution of donor-acceptor centers is analyzed and the R value is calculated. The material with a different antimony concentration is synthesized in the same way for the other arm of the sensor differential circuit, which is also analyzed.

As the results of the studies showed, for satisfactory operation of the sensor in differential mode, the R values in the material of the supporting and measuring arms should differ by at least 10-15 times. In this case, the concentration of antimony in the film material should be from 0.2 to 0.4 wt.% For the measuring arm and going beyond this interval for the supporting arm. It was experimentally established that the optimal concentration of antimony in the film material for the supporting arm should be in the range from 0.04 to 0.12 wt.%, Or from 0.4 to 0.5 wt.%. A graph of the dependence of the change in the value of R on the concentration of the dopant is presented in Fig.3.

Next, a paste is prepared from the powder of the doped sensor material for application onto a ceramic substrate 1, on which a heater 2 with contact pads and contact pads 5 and 6 for the sensor support and measuring arm are preliminarily applied, also made by thick-film technology.

To prepare a paste for one shoulder of the sensor, a binder material (e.g., glass powder) and a plasticizer (e.g., terpeneol or glycerin) are added to the corresponding powder material obtained, mixed until a homogeneous mass is obtained, and then applied to a ceramic substrate. Similarly, a paste of material with a different concentration of antimony for the other shoulder is prepared and applied to the substrate. To fix the applied sensor films, the sensor (microchip) is dried at a temperature of 150-180 ° C and annealed in an oven at a temperature of 800-850 ° C.

To further increase the concentration of acceptor centers, you can increase the specific surface area of the sensor material (for example, from 60-70 to 150-155 m ² / g). For this, the material intended for the measuring arm of the sensor sensor (microchip) is mixed with finely dispersed sol (for example, having a particle radius of 10-20 nm) of tin oxide activated with antimony in the same ratio as the particles of the main material (as a dispersion medium of such a sol use ashless burnable substances, for example, glycerin).

The synthesis of this sol can be carried out by sol-gel technology from tin isopropylate, similar to that described in the work cited above (A. Teeramongkonrasmee, M. Sriyudthsak "Methanol and ammonia sensing characteristics of sol-gel derived thin film gas sensor", " Sensors and Actuators B: Chemical ", v. 66, 2000, p. 256-259).

Under the same conditions, namely, subject to the identity of the chemical composition of the dispersed phase of the sol and the material of the sensor film, a sol is synthesized and applied to treat the powder for the support arm of the sensor (microchip).

Next, the resulting material is dried and subjected to secondary heat treatment at a temperature of 600-650 ° C.

As a result of this treatment, the surface of the particles of the gas-sensitive film due to the coagulation is covered with a layer of particles that are identical in composition and structure, but almost an order of magnitude different in size compared with the particles of the main powder, which leads to an increase in the specific surface area of the sensor material, and, thereby, to a concentration active centers on particles formed after sol treatment.

The device operates as follows.

The sensor sensor (microchip) through the leads connected to the pads 5 and 6 is connected to the measuring unit of the gas analyzer (not shown in the drawing). Heated by the heater 2 to the operating temperature (each type of gas to be identified has its own characteristic operating temperature), gas sensitive films 3 and 4, located on the opposite side of the substrate 1 with respect to the heater, are placed in the analyzed gas. The gas molecules coming into contact with the gas-sensitive film 4 of the measuring arm of the sensor are sorbed on the surface active centers and thereby change the surface conductivity of the semiconductor particles. The gas-sensitive film 3 of the support arm, where the concentration of active centers is much lower, does not give a similar response, and a difference signal arises between the arms, which is detected by the measuring unit of the gas analyzer.

With a change in the concentration of the controlled gas, the resistance of the metal oxide gas-sensitive films changes. The measured value of the voltage difference at the measuring and supporting arms of the sensor judges the quantitative content of the gas being monitored.

Thus, the use of the claimed utility model can significantly increase the sensitivity of the sensor to various gases due to the fact that the sensitive film in the support and measuring arms is made using the thick-film technology based on a semiconductor of the same nature, that is, it has the same reaction to changes in external conditions, but at this different sensitivity to adsorbed gases: high in the measuring and low in the supporting arm - due to different concentrations of acceptor centers. Moreover, the use of a differential measurement scheme makes it possible to increase the reliability of the information obtained by eliminating the influence of a baseline level drift on the measurement results. In addition, the design of the sensor is quite simple and technologically advanced, which reduces the cost of its manufacture.

Claims (9)

1. A differential gas sensor, including a measuring and supporting arms, each of which contains a dielectric substrate, on one side of which is a ribbon heater with contacts for connecting to a power source, and on the other a gas-sensing element with contact leads for connecting to the measuring unit, characterized in that the gas-sensitive element in the measuring and supporting arms is made in the form of gas-sensitive films of the same semiconductor material, the indicator R ratio of the concentration of acceptor centers with index value acidity constant pK _a = 3.3 to a concentration centers with metric value acidity constant pKa in the range of 6.4-6.8 _and a measuring arm material differs by at least 10-15 times of that of R in the material of the supporting arm. 2. The sensor according to claim 1, characterized in that antimony doped tin oxide is used as the semiconductor material of the gas-sensitive films. 3. The sensor according to claim 1, characterized in that the concentration of antimony in the gas-sensitive film material is from 0.2 to 0.4 wt.% For the measuring arm and beyond this interval for the supporting arm. 4. The sensor according to claim 3, characterized in that the concentration of antimony in the gas-sensitive film material for the support arm is from 0.04 to 0.12 wt.% Or from 0.4 to 0.5 wt.%. 5. The sensor according to claim 1, characterized in that the gas-sensitive films are deposited on a dielectric substrate by the method of thick-film technology. 6. The sensor according to claim 1, characterized in that the dielectric substrate is made of heat-resistant ceramic, for example, polycor. 7. The sensor according to claim 1, characterized in that the dielectric substrate is roughened from the location of the gas-sensitive films. 8. The sensor according to claim 1, characterized in that to increase the specific surface in the manufacture of gas-sensitive films, the material of each shoulder of the sensor sensor is pre-treated with highly dispersed sol. 9. The sensor of claim 8, characterized in that the finely dispersed sol for processing gas-sensitive films includes a dispersed phase of the same chemical composition as the material of the corresponding gas-sensitive film and ashless burnout dispersion medium.