RU2485510C1 - Method of determining concentration of nitrate compounds in atmospheric air - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method of determining concentration of nitrate compounds in atmospheric air involves measuring concentration of nitrogen-containing compounds in atmospheric air at a given point, calculating on that basis concentration of nitrate compounds using a certain relationship based on graphs plotted beforehand. First, concentration of nitrogen dioxide at a given point is determined and concentration of nitrate compounds is then calculated using the relationship:

where: C(NO₂) is the measured concentration of nitrogen dioxide, mg/m³; k_α is the solar declination influence coefficient; k_cl is the total cloud cover influence coefficient. The solar declination influence coefficient (k_α) is determined based on the degree of transformation of nitrogen dioxide in different periods of the year, and the total cloud cover influence coefficient (k_cl) is determined depending on total cloud cover.

EFFECT: easier and more accurate determination of concentration of nitrate compounds in atmospheric air.

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Description

The invention relates to the field of hydrometeorology of environmental control and can be used to determine the concentration of nitrate compounds (suspended particles) in the atmospheric air of populated areas in the range of geographical latitudes 50-60 ° north latitude.

A known method for the determination of nitrates and nitrites in liquid media by the test method along the length of the lilac-colored zone of the test strip measuring (3-4) × (80-90) mm, sealed in a polymer film and contacting one end with the test liquid. As absorbent paper, dialdehyde cellulose paper with which 1-naphthylamine or N- (naphthyl-1) ethylenediamine is covalently bonded is used, novocaine or anestezin immobilized on paper are used as the diazo component. As a reducing agent in the determination of nitrates, zinc dust was used [RF patent No.RU 2173851 from 09/20/2001].

The disadvantage of this method is the limited scope of its application exclusively in liquid media.

There is a reactive indicator strip for the determination of nitrate ions Rip-Nitrat-Test. The essence of the invention is as follows: between the layer with the acid reagent and the layer with organic indicator reagents of the Griss test there is a layer consisting of zinc dust with an adhesive filler, the layer with the acid reagent containing a secondary amine as a maskrant for nitrite ions, and under the indicator layer a polymer substrate holder is made, a hole is made in the polymer substrate, and zinc dust is placed in the hole of the adhesive layer, an equidistant hole in the polymer substrate, as a secondary amine with enen diphenylamine, N-phenyl-1-naphthylamine, 3-hydroxy-1,2,3,4-tetrahydro / h / quinoline, fixed on modified chromatographic paper containing polyamido (amino) epichlorohydrin resin, epoxidized cellulose [RF patent No.RU 2009486 dated 03/15/1994].

The disadvantage of this method is the difficulty of taking measurements and the impossibility of taking them in atmospheric air.

There is a method for estimating the distribution of aerosol particles, which consists in the deposition of a polydisperse aerosol on a cascade sampler. The method consists in the deposition of a polydisperse aerosol on a cascade sampler, in which filter elements, for example polyurethanes, are sequentially placed, in order of increasing fiber packing density and with a known filtering efficiency of particles of various sizes. When studying aerosols of solids, filter elements are pre-wetted with an adhesive fluid with a viscosity of 100 cSt, for example polymethylsiloxane. A method for assessing the mass distribution of aerosol particles by size includes sampling the aerosol on a cascade sampler, conducting a quantitative analysis of the impurity content on each element and then calculating the distribution parameters [application for invention No.93012769 of 08/20/1996].

The disadvantage of this method is the inability to determine the concentration of nitrate compounds (suspended particles) in atmospheric air.

A known method for the determination of nitrates and nitrites in biological environments of small volumes. According to the method, protein precipitation is carried out with 1.5 ml of 96% ethanol cooled to + 4-8 ° C and 0.1 ml of distilled water at a final concentration of 86.4%, then 2 ml of ammonia-chloride buffer pH 9.6 ± 0 is added. 05 and with distilled water bring the volume to 10 ml. Nitrates and nitrites are extracted through a cadmium column, a color reaction is carried out with the addition of N-naphthylethylenediamine dihydrochloride, photometry, determination of the concentration of nitrates and nitrites according to a graph of the concentration versus optical density. The concentration of nitrates and nitrites is determined by the formula:

[патент РФ RU 2317545 от 20.02.2008].where C ₁ is the concentration of nitrite ions found from the calibration graph,

[RF patent RU 2317545 dated 02.20.2008].

A disadvantage of the known method for the determination of nitrates is the inability to determine the amount of nitrate compounds (suspended solids) in the atmospheric air of populated areas.

The closest in technical essence to the claimed method is a method for the photometric determination of the concentration of calcium nitrite-nitrate (NNCC) in the air of the working area [MUK 4.1.146-96 Guidelines for the photometric measurement of the concentrations of calcium nitrite-nitrate (NLC) in the air of the working area ]. The technique is based on the reaction of the interaction of the analyte with the Griss-Ilosvay reagent and subsequent photometric measurement of the colored reaction product at 540 nm. According to this method, air with a volume flow of 1 l / min is aspirated through filters such as AFA-VP-20. The filter with the sample is placed in a glass, pour 10 ml of distilled water. After 3-4 minutes, the filter is squeezed with a glass rod and 2 ml of the resulting solution is removed and transferred to a porcelain cup. Next, the samples are processed similarly to calibration solutions. The optical density of the obtained analyzed sample solution is measured similarly to calibration solutions in comparison with the control, which is prepared simultaneously and similarly to the sample. Quantitative determination of the substance content (μg) in the analyzed sample is carried out according to a previously constructed calibration schedule. The concentration of the substance (C) in air (mg / m ³ ) is calculated by the formula:

where a is the content of sodium nitrate in the analyzed sample volume, determined by the calibration graph, mcg; in - the total volume of the sample solution, ml; b - the volume of the sample solution taken for analysis, ml; V is the volume of air taken for analysis and reduced to standard conditions, l.

The disadvantages of this method are its high complexity, due to the need for sampling of air with subsequent sample preparation.

The technical task of the proposed method is to reduce the complexity and increase the accuracy of determining the concentration of nitrate compounds in atmospheric air.

The specified problem is solved as follows.

A method for determining the concentration of nitrate compounds in atmospheric air includes measuring the concentration of nitrogen-containing compounds in atmospheric air at a given point, calculating, on this basis, the concentration of nitrate compounds according to a certain dependence based on previously constructed graphs, first, measuring the concentration of nitrogen dioxide at a given point, then calculating the concentration nitrate compounds according to:

where C (NO ₂ ) is the concentration of nitrogen dioxide according to the measurement results, mg / m ³ ;

k _α is the coefficient of influence of the declination angle of the Sun;

k _region - coefficient of influence of the degree of total cloud cover.

The coefficient of influence of the declination angle of the Sun (k _α ) is determined taking into account the degree of transformation of nitrogen dioxide at different time periods of the year, and the coefficient of influence of the degree of general cloud cover (k _region ) is determined depending on the total cloud cover, while with a total cloud cover of 1 point, the cloud coefficient is 1, with a total cloud of 2 points, the cloud cover is 2.75, with a total cloud of 3 points, the cloud cover is 4.5, with a total cloud of 4 points, the cloud cover is 6.25, with a total cloud of 5 points, the cloud cover is 8, with a total cloud of 6 points, the cloud cover is 9.75, with a total cloud of 7 points, the cloud cover is 11.5, with a total cloud of 8 points, the cloud cover is 13.25, with total cloud cover at 9 points, the cloud cover is 15, with a total cloud of 10 points, the cloud cover is 16.75.

The invention is illustrated by drawings. Figure 1 presents the change in daily concentrations of nitrogen dioxide (NO ₂ ) and ozone (O ₃ ): 1 - graph of the daily concentration (mg / m ³ ) of ozone (O ₃ ); 2 is a graph of daily concentration (mg / m ³ ) of nitrogen dioxide (NO ₂ ). Figure 2 presents the change in the thickness of the optical layer of the atmosphere by months: α ₁ is the angle of declination of the Sun in July, α ₂ is the angle of declination of the Sun in August, α ₃ is the angle of declination of the Sun in September. Figure 3 presents graphs: the concentration of nitric oxide (IV), 03/30/09, on a cloudy day, cloudiness 10 points; 1 is a graph of the concentration of nitric oxide (IV); 2 - the value of the average daily maximum permissible concentration of nitric oxide (IV). Figure 4 presents graphs of the concentration of nitric oxide (IV), 04/02/09, sunny day, cloudiness 1 point; 1 is a graph of the concentration of nitric oxide (IV); 2 - the value of the average daily maximum permissible concentration of nitric oxide (IV)

The proposed method is as follows.

To determine the concentration of nitrate compounds in atmospheric air at a given point in a settlement, the concentration of nitrogen dioxide is first measured. Then find the coefficient of influence of the declination angle of the Sun k _α according to table 1 depending on the time of year and day.

Table 1 The values of the coefficients of the degree of transformation of nitrogen dioxide in different time periods of the year for a range of geographical latitudes of 50-60 ° north latitude Month Hours of the day 6 8 10 12 fourteen 16 eighteen twenty The value of the transformation coefficient k _α January 0 0 0.1 0.5 one 0.4 0 0 February 0 0 0.2 0.6 one 0.5 0 0 March 0 0 0.3 0.6 one 0.6 0.1 0 April 0 0 0.4 0.7 one one 0.6 0 May 0 0 0.5 0.75 one one one 0.6 June 0 0.1 0.6 0.9 one one one one July 0 0 0.5 0.75 one one one 0.9 August 0 0 0.4 0.65 one one 0.7 0.3 September 0 0 0.3 0.5 one one 0.4 0 October 0 0 0.2 0.4 one 0.4 0 0 November 0 0 0.1 0.3 one 0.3 0 0 December 0 0 0 0.3 one 0.1 0 0

A table of numerical values of the degree of transformation (completeness of chemical transformations) of nitrogen dioxide in the form of a coefficient - k _α , depending on the declination angle of the Sun, corresponding to a certain time interval, was developed according to the results of experiments conducted in the period 2008-2010 by the method of differential optical absorption spectroscopy (DOAS). Using the DOAS method, a relationship was established between a decrease in the concentration of nitrogen dioxide and an increase in the concentration of ozone at different times of the day and seasons (Fig. 1), depending on the angle of declination of the Sun (Fig. 2) corresponding to a certain time interval.

The study was conducted in the range of geographical latitudes 50-60 ° north latitude.

Next, determine the value of the coefficient of influence of cloudiness k _obl according to table 2 based on the value of the total cloud cover (in points).

Table 2 The values of the coefficient of influence of the degree of total cloudiness on the degree of transformation of nitrogen dioxide Total cloud cover (points) k _reg one one 2 2.75 3 4,5 four 6.25 5 8 6 9.75 7 11.5 8 13.25 9 fifteen 10 16.75

The table of values of the coefficient of influence of cloudiness k _obl was compiled on the basis of the results of experiments carried out over two adjacent days, it can be seen that the concentration of nitrogen dioxide on sunny and cloudy days differs many times. So, figure 3 shows a graph of the concentration of nitrogen dioxide measured on March 30 in Tula on a cloudy day with ten points of cloudiness, an excess of the maximum permissible concentration by 2.5 times is noted. And when measuring the concentration of nitrogen dioxide on April 2, 2009 in the city of Tula on a sunny day with a cloud of one point, there is no excess of the maximum permissible concentration (Fig. 4).

In accordance with the law of conservation of mass, each molecule formed in atmospheric air, nitric acid forms a molecule of ammonium nitrate - solid suspended matter - PM according to international classification. Accordingly, the mass concentration of suspended matter (NH ₄ NO ₃ ) will be proportional to the concentration of nitrogen dioxide.

For practical confirmation of the formation of precisely this nitrate by atomic absorption spectroscopy, an analysis was made of the snow cover of the winter of 2009-2010 at three different points in Tula. The theoretical justification for choosing this approach is that the water obtained from snow dissolves the substances in it, breaking them into separate molecules, forming true molecular solutions. Qualitative and quantitative chemical composition of snow samples is presented in table 3.

Table 3 Qualitative and quantitative chemical composition of snow samples Substance Selection Points in Tula 1 point (Oboronnaya St.) 2 point (Lenin Ave.) 3 point (Mira street) mg / l

9 9 8.7

2.6 2,5 2,4

1 point: Tula, st. Defense

2 point: Tula, Lenin Ave.

3 point: Tula, st. Of the world

As can be seen from the calculation, the molar concentrations of ammonium ions and the nitrate group coincide, i.e. ammonium nitrate is dissolved in water.

The proposed method is based on the law of conservation of mass and the results of experimental studies of the dynamics of diurnal transformations of nitrogen and oxygen compounds in the troposphere.

The process of nitrate formation is based on the sensitizing properties of nitrogen dioxide - the ability to absorb a quantum of sunlight and transfer excess excitation energy to oxygen molecules, thereby translating them into a singlet state - O ( ¹ D) and O ( ³ P).

The appearance of oxygen singlets, in turn, triggers a chain reaction of free radical formation, which proceeds according to the following reaction (2):

Subsequently, during the interaction of the OH radical with NO ₂ , nitric acid is formed, which accumulates in air (3).

Thus, with the maximum exposure to solar radiation, depending on the thickness of the optical layer of the atmosphere (angle of declination of the sun) and its degree of permeability (cloudiness), each molecule of nitrogen dioxide (gas) is transformed into a molecule of nitric acid (liquid). As evidenced by experimental data (Fig.1-3).

In turn, nitric acid, which is highly reactive, reacts with ammonia - NH ₃ , which is always present in the atmosphere due to biological transformation and decomposition of biological material. As a result, ammonium nitrate NH ₄ NO _{3 is formed} (4).

After that, calculate the value of the concentration of nitrate compounds in the atmospheric air of populated areas according to the following relationship:

where C (NO ₂ ) is the concentration of nitrogen dioxide according to the measurement results, mg / m ³ ; k _α is the coefficient of influence of the angle of inclination (table of the optical layer); k _region - coefficient of influence of the degree of total cloud cover;

The present invention allows to reduce the complexity and improve the accuracy of measuring the concentration of nitrate compounds in atmospheric air, which makes it possible to implement in practice the requirement "Methods for calculating the concentrations in the air of harmful substances contained in emissions of enterprises" OND-86 in paragraph 1.5, which states that " Calculation of the concentration of harmful substances undergoing fully or partially chemical transformations (transformation) into more harmful substances is carried out for each source and forming substance separately. "

Example. Determine the concentration of nitrate compounds in the air at 12 hours, May 15, with a cloud level of 3 points at point A, populated area B 55 ⁰ north latitude.

1. Measurement of the concentration of nitrogen dioxide at a given point in the village. According to the measurement results, C (NO ₂ ) = 0.18 mg / m ³ .

2. According to table 1 we find the value of the coefficient k _α . In our case, for the considered time period, k _α = 0.75.

3. According to table 2, we determine the value of the coefficient k _obl for three-point cloud cover. In our case, k _region = 4.5.

находим искомое значение концентрации нитратных соединений в атмосферном воздухе в точке А населенного места Б:4. According to

we find the desired value of the concentration of nitrate compounds in atmospheric air at point A of populated area B:

Claims (1)

A method for determining the concentration of nitrate compounds in atmospheric air, including measuring the concentration of nitrogen-containing compounds in atmospheric air at a given point, calculating, on this basis, the concentration of nitrate compounds according to a certain relationship based on previously constructed graphs, characterized in that the concentration of nitrogen dioxide at a given point is first measured, then calculate the concentration of nitrate compounds but dependencies:

where C (NO ₂ ) is the concentration of nitrogen dioxide according to the measurement results, mg / m ³ ;
k _α is the coefficient of influence of the declination angle of the Sun;
k _region - coefficient of influence of the degree of total cloud cover;
the coefficient of influence of the declination angle of the Sun (k _α ) is determined taking into account the degree of transformation of nitrogen dioxide in different time periods of the year, and the coefficient of influence of the degree of general cloud cover (k _region ) is determined depending on the total cloud cover, while with a total cloud cover of 1 point, the coefficient the cloud cover is 1, with a total cloud of 2 points, the cloud cover is 2.75, with a total cloud of 3 points, the cloud cover is 4.5, with a total cloud of 4 points, the cloud cover is 6.25, with a total cloud with a cloudiness of 5 points, the cloud cover is 8, with a total cloud of 6 points, the cloud cover is 9.75, with a total cloud of 7 points the cloud cover is 11.5, with a total cloud of 8 points the cloud cover is 13.25, with a total cloud a cloud cover of 9 points, a cloud cover ratio of 15, with a total cloud cover of 10 points, a cloud cover is 16.75.

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