RU2080771C1 - Soil fertility evaluation method - Google Patents

Abstract

FIELD: agriculture and forestry. SUBSTANCE: method involves taking samples of concrete soils; determining content of physical clay and actual parameters of fertility properties to be evaluated by physical and chemical analysis, with fertility properties including pH, humus content, content of macro and microelements, soil depth. Soil containing 20-50% of physical clay is taken as standard soil. Parameters corresponding to potential fertility of soil are set for evaluation properties of standard soil. Method further involves plotting evaluation scale, in which, relative to standard soil to which highest point is given, points are set for soils having clay content different from that of standard soil; introducing parameters of potential fertility of standard soil into scale and optimum parameters of evaluation properties of soil fertility, having concrete number of points in terms of evaluation scale; setting point, corresponding to actual parameter of each evaluation property of fertility of concrete soil and to optimum parameters of each evaluation property of fertility of soil having certain number of points, on single evaluation base calculated by formula: y = K [1 - (1 -

Description

 The invention relates to agriculture and forestry, and in particular to methods for assessing soil fertility.

 A known method of evaluating soil fertility, used in Poland, according to which the soil is divided into classes regarding the suitability of their use in agricultural production / see Vostokova L.B. Yakushevskaya I.V. Soil appraisal. M. Moscow State University, 1979, p. 82 85 /.

 The known method does not allow to accurately quantify the soil fertility due to the lack of a single assessment basis and the imperfection of the method, which complicates the effective use of soil fertility and fertilizers.

 There is a method of fertility assessment used in the humid tropics of Africa, according to which fertility assessments are carried out by the properties of soils that correlate with their productivity / cm. in the same place, with. 88, 89 /.

 The known method does not allow sufficiently accurate assessment of soil fertility due to the lack of a single assessment basis, a limited number of evaluation features and the imperfection of the method, which complicates its effective and widespread use.

 A known method of evaluating soil fertility, used in India, which is based on a mathematical equation. According to the known method, for each evaluative sign of fertility, tables are developed that include several gradations, in which each gradation of the attribute corresponds to an estimate, expressed as a percentage. Soil is divided into six groups / cm depending on the total estimated score. ibid., p.90 /.

 The known method does not allow a sufficiently accurate assessment of soil fertility due to the limited number of evaluation features, their parameters, imperfections in the calculation basis and complexity, which makes it difficult to use it widely and efficiently.

 There is a method of assessing land by biological productivity, according to which the assessment is based on objective indicators of biological productivity and which is expressed by the relative values of soil and bioclimatic potential. A comparative assessment of biological productivity is carried out according to the values of bioclimatic potential, which is determined by the sum of active temperatures, multiplied by the coefficient of biological productivity / cm. in the same place, with. 79 81 /.

 The known method allows you to set the potential / environmentally possible / crop yields through which you can set the parameters of potential soil fertility and determine the level of comparison / standard /.

 However, the known method does not allow a sufficiently accurate assessment of soil fertility due to the limited number of evaluative signs of fertility and the lack of a single assessment basis, which makes it difficult to widely use it.

 There is a method of evaluating soil fertility, including the construction of an assessment scale indicating the names of various soils and their corresponding rating points, established on the basis of some soil properties that correlate with crop yields / cm. in the same place, with. 20, 21 /.

 The known method allows you to perform a rough assessment of arable land for their suitability for cultivation of crops.

 However, it is not possible to sufficiently quantify the soil fertility due to the limited number of evaluative signs of fertility and the lack of a single assessment framework, which makes it difficult to use it widely and widely.

 A known method for evaluating soil fertility, including the selection of a reference soil and the construction of an assessment scale in the form of tables, according to which the ordinary chernozem of the Central Chernozem zone / Voronezh, Tambov regions / is selected as a reference soil, which is estimated at 100 points, then places are set relative to the reference other soils that are assigned the appropriate scoring score, taking into account the conditions of various soil and climatic zones / cm. Karmanov I.I. Soil fertility of the USSR. M. Kolos, 1984, p. 63 103 /.

 The known method allows a comparative assessment of various soils by their productivity relative to the reference soil.

 However, the known method does not allow a sufficiently accurate quantitative assessment of soil fertility, depending on the content of nutrients in them due to the limited number of evaluation features and the lack of a single assessment basis, which makes it difficult to use.

 The soil grouping is known by the content of mobile forms of nitrogen / cm. Alexandrova L.N. 0naydenova O.A. Laboratory and practical classes in soil science. L. Agropromizdat, L.O. 1986, p. 261 /.

 The content of mobile forms of nitrogen in the soil serves as an evaluative sign of soil fertility and, therefore, the well-known grouping makes it possible to subdivide soils into fertility groups relative to this trait.

 However, the well-known grouping according to the content of mobile nitrogen in relative units of points due to the lack of a single assessment basis, which complicates the use of the known grouping, as well as soil fertility and nitrogen fertilizers.

 The soil grouping is known by the content of mobile phosphorus and exchange potassium in them / cm. in the same place, with. 261 /.

 The content of mobile phosphorus and exchange potassium in the soil is an objective indicator of the level of soil fertility, and therefore the well-known grouping allows you to subdivide the soil into groups according to fertility relative to the indicated signs of fertility, which is often on cartograms.

 However, the well-known grouping does not allow to accurately assess soil fertility in relative units by the content of the parameters of these characteristics due to the lack of a single assessment basis, which complicates the effective use of the well-known grouping, soil fertility and phosphorus-potassium fertilizers.

 A group of soils is known by their humus content / cm. in the same place, with. 261 /.

 The content of humus in the kidney is an objective indicator of its fertility and culture, therefore, the well-known grouping allows you to subdivide the soil into groups relative to the indicated trait, which is often depicted in the form of cartograms.

 However, the well-known grouping does not contain a single estimated calculation basis, which does not allow a sufficiently accurate assessment of soil fertility on this basis in relative scores. This makes it difficult to effectively use soils and organic fertilizers of different cultivation.

 There is a well-known grouping of soils according to the content of mobile forms of trace elements: B, Mo, Cu, Zn, Co, including the construction of an assessment scale with groups and their corresponding gradations of the content of trace elements in the soil.

 The content of mobile forms of trace elements in the soil is an objective indicator of the level of soil fertility, and the well-known grouping allows you to evaluate the soil by fertility relative to these characteristics with their division into groups.

 However, the well-known grouping was developed not according to a single estimated calculation basis, as a result of which it is not possible to accurately assess soil fertility by the content of these trace elements in the soil and express it in relative units, which makes it difficult to use soil fertility and micronutrients effectively.

 There is a method for evaluating soils by fertility, according to which soddy-podzolic soil containing 2% humus is selected as a standard, which is estimated at 50 points, then an assessment scale is built in which places of other soils are established relative to the standard and their corresponding points / cm are determined. The optimal parameters of soil fertility. M. Kolos, 1984, p. 230,234 /.

 The known method allows you to make a rough assessment of the quality of various soils according to their suitability for agricultural use relative to the standard.

 However, the known method does not allow to sufficiently evaluate soil fertility by the content of nutrients, humus and pH due to the lack of a single assessment basis and a uniform rating scale, which makes it difficult to widely use it.

 Closest to the technical solution to the claimed method is a method for evaluating soil fertility, in which they select the reference soil, establish the main and additional signs of fertility, and the main features include pH and humus content, and the additional composition of the arable layer and the content of mobile phosphorus, an assessment scale is built in which the physical clay content and the optimal parameter of the main characteristics of the fertility of the reference soil are assigned the highest score, for example 100, and in which On the vertical and horizontal axes, the parameters of fertility signs are established, and at the intersection of the vertical and horizontal lines of these parameters, soil fertility scores are placed, then the physical clay content and the actual parameters of the main and additional signs of fertility of the particular studied soil are determined by physicochemical analysis by comparing the data obtained with a rating scale, the studied soil is assessed, while the main points establish a preliminary fertility score of e oh the soil, and the final score of fertility is determined by correction factors for additional signs of fertility / cm. Alexandrova L.N. Naydenova O.A. Laboratory and practical classes in soil science. L. Agropromizdat, L.O. 1086, p. 265-269 /.

 The known method allows you to compare the quality of various soils by their fertility and suitability for cultivation of certain crops. In this case, the soil grouping is carried out on the basis of their genetic classification, and soil fertility assessment is expressed in relative scores. As an assessment, a 100-point scale is used, divided into 10 classes and including a number of assessment tables, which show specific combinations of soil properties or parameters of the estimated signs of fertility. On the axes of the table, they find the combination of soil properties and parameters of the valuation attributes that is established by the evaluator for a particular soil, and get a preliminary assessment score at the crossing point of the vertical and horizontal lines. The difference in the quality of one soil from another is determined by the difference in the number of points that the compared soils possess. For each crop, the crop price of the point is set, which is expressed in fractions of the crop, for example, in tons per hectare. The yield price of a point is determined by dividing the average long-term yield of a crop cultivated on a reference soil by the point of this soil. Then, the crop price of a specific crop point is used to determine the soils most favorable for cultivating a given crop. To do this, the yield price of the point is multiplied by the point of a particular soil and thus determine the yield of a given crop, which can be obtained on a specific soil, and the most favorable soils.

 However, the known method does not allow to accurately assess soil fertility, for example, by the content of nutrients and humus in the soil, because the assessment scale does not contain a continuous change in the parameters of the estimated signs of soil fertility, but contains only a few / 3 4 / gradations of the parameters of the main signs of fertility, for example, pH is expressed in 4 gradations, the humus content in 3 gradations, and for each content of physical clay / particle size distribution / a separate table is given. Along with this, the evaluation tables contain a large number of combinations of evaluation attributes, are designed for the average level of agricultural technology and include a limited composition of evaluation attributes of soil fertility, which does not provide a sufficiently complete picture of the completeness of the assessment of soil fertility. In addition, the known method does not contain a single assessment basis and a single scale for assessing soil fertility, which increases the role of the subjective approach in assessing the fertility of various soils. The method does not allow to evaluate the different fertility of the same soil, which may occur as a result of economic activity, that is, it does not allow to assess the change in soil fertility as a result of its use and reproduction: simple or expanded.

 All this taken together complicates the effective use of soil fertility and its reproduction, and also reduces the effectiveness of the use of organic and mineral fertilizers, micronutrient fertilizers, reclamation materials, agricultural and land reclamation measures. Along with this, the known method does not allow to establish a fertility limiting factor / sign of fertility, the parameter of which has the lowest score, i.e. minimum value, and limits the law of minimum plant life, because the vital activity of plants depends on the parameters of the estimated attributes of soil fertility. It is limited by a factor that is at a minimum. This circumstance, in turn, does not allow us to accurately determine the need for soil in fertilizers, their types, forms and quantities.

 Along with this, the choice of reference soil by a known method does not fully reveal the essence of the phenomenon, because they select the best soil for the standard, but do not indicate its potential / do not set the parameters of the estimated fertility characteristics corresponding to the potential fertility of the standard soil, which provide the highest crop yield /, but limit its actual capabilities. This circumstance complicates the effective use of soil fertility and its fairly accurate assessment.

 An accurate and objective assessment of soil fertility underlies efficient land use in agriculture and forestry. Such an assessment is necessary to assess the productive capacity of specific soils, to quantify their fertility and the effective use of fertilizers, land reclamation agents, agricultural and land reclamation measures. The analogues considered above are difficult to implement, are indirect and not objective enough. Known methods for assessing soil fertility do not contain a single basis for assessing the parameters of the estimated characteristics of soil fertility and a single rating scale, which does not allow a sufficiently accurate assessment of soil fertility and determine the need for specific soils in fertilizers and reclamants. This complicates the effective use and reproduction of soil fertility on the scale of the economy, region, country. Known methods are of little use for the economic evaluation of soil fertility and soil with different physical clay contents.

 The objective of the invention is to increase the accuracy of the assessment of soil fertility, simplifying the method and expanding the scope.

где
x фактический параметр конкретного основного признака плодородия почвы;
a оптимальный параметр того же признака плодородия эталонной почвы, соответствующий ее потенциальному плодородию;
y балл плодородия почвы;
K объем оценочной шкалы в баллах (высший балл плодородия почвы), баллы фактических параметров каждого основного признака плодородия исследуемой почвы определяют по единой оценочной основе, рассчитываемой по формуле

где
y балл плодородия почвы;
x фактический параметр конкретного основного признака плодородия почвы;
a оптимальный параметр того же признака плодородия эталонной почвы, соответствующий ее потенциальному плодородию;
K объем оценочной шкалы в баллах (высший балл плодородия почвы),
предварительный балл плодородия исследуемой почвы и признак, лимитирующий ее плодородие, определяют по наименьшему баллу из числа основных признаков плодородия этой почвы.The essence of the proposed method lies in the fact that in the known method, in which the reference soil is selected, the main and additional signs of fertility are established, and the pH and humus content are included in the main characteristics of fertility, an assessment scale is built in which the physical clay content and optimal parameters of the main signs of fertility of the reference soil are assigned the highest score and in which the parameters of each main sign of fertility are established and the points of soil fertility are placed, and for additional correction factors are established, then physico-chemical analysis determines the content of physical clay and the actual parameters of the main and additional signs of fertility of a particular studied soil, by comparing the obtained data with an assessment scale, the studied soil is evaluated and a preliminary score of its fertility is established by the parameters of the main characteristics, and the final fertility score of the studied soil is determined using correction factors for additional features its fertility, for example, on the thickness of the arable layer, it is new that, among the main signs of fertility, the content of macro- and microelements is additionally determined, soil that contains 20 50% physical clay is taken as a reference soil, and optimal parameters of the main signs of fertility are taken the reference soil set the parameters corresponding to its potential fertility, soil fertility scores are placed in the form of a scale of fertility points, and the parameters of each main sign of soil fertility, respectively that are specific to the fertility score that fit into the scale, set on a single assessment basis, calculated by the formula

Where
x the actual parameter of a particular underlying trait of soil fertility;
a optimal parameter of the same sign of fertility of the reference soil, corresponding to its potential fertility;
y soil fertility score;
K the volume of the assessment scale in points (the highest score of soil fertility), the points of the actual parameters of each main sign of fertility of the studied soil is determined by a single assessment basis, calculated by the formula

Where
y soil fertility score;
x the actual parameter of a particular underlying trait of soil fertility;
a optimal parameter of the same sign of fertility of the reference soil, corresponding to its potential fertility;
K the volume of the rating scale in points (the highest score of soil fertility),
the preliminary fertility score of the studied soil and the trait that limits its fertility are determined by the lowest score among the main features of the fertility of this soil.

 New significant features.

 1. Among the main signs of fertility, the content of macro- and microelements is additionally determined.

 As a reference soil, take soil that contains 20 to 50% physical clay.

 3. The parameters corresponding to its potential fertility are established as optimal parameters of the main signs of fertility of the reference soil.

 4. Soil fertility scores in the rating scale are placed in the form of a fertility score scale.

6. Баллы фактических параметров каждого основного признака плодородия исследуемой почвы определяют по единой оценочной основе, рассчитываемой по формуле

7. Предварительный балл плодородия конкретной исследуемой почвы определяют по наименьшему баллу из числа основных признаков плодородия этой почвы.5. The parameters of each main feature of soil fertility, corresponding to a specific fertility score, entered into the scale, are set according to a single assessment basis, calculated by the formula

6. The points of the actual parameters of each main sign of fertility of the studied soil are determined by a single assessment basis, calculated by the formula

7. A preliminary fertility score of a particular studied soil is determined by the lowest score among the main signs of fertility of this soil.

 8. A sign limiting the fertility of the studied soil is determined by the lowest score among the main signs of its fertility.

 These new essential features, together with the known ones, provide a technical result in all cases to which the requested scope of right protection applies.

 Due to the fact that, among the main signs of soil fertility, the content of macro- and microelements is additionally determined, and the accuracy of soil fertility assessment is increased. These additional characteristics serve as objective indicators of soil fertility, the growth and development of plants / agricultural and forest crops /, the defeat of their diseases and pests, as well as the size of the crop and its quality depend on their parameters. Therefore, the determination of the parameters of additional features among the estimated signs of fertility allows you to make a more accurate, complete and objective assessment of the soil fertility of a particular soil and to sufficiently fully judge its need for fertilizers, reclamants, agricultural and reclamation techniques, which expands the scope of the method.

 The actual parameters of each evaluation feature of the fertility of a particular soil is determined by physicochemical analysis of a sample of this soil. According to the obtained parameters, they are judged on the fertility of the studied soil, on its need for types and forms of fertilizers, their norms and doses, and the norms of reclamants. These parameters determine the cost of fertility of a particular soil, determine the reimbursement fund in the form of penalties for reducing soil fertility as a result of economic activity or the amount of remuneration for increasing soil fertility. This extends the scope of the method.

 Soil samples are taken according to the generally accepted method, for example, one sample for its entire thickness from the arable layer of a specific soil. The taken sample along with the label is placed in a cloth or plastic bag and sent for physico-chemical analysis.

Physico-chemical analysis of the soil sample is carried out according to the generally accepted method, for example, the content of mobile phosphorus and exchange potassium in the soil sample is determined by the Kirsanov method, the content of humus according to Tyurin, a pH potentiometer in a solution of 0.1 KCl, the content of physical clay according to the Kachinsky method, the content of easily hydrolyzable nitrogen / NO ₃ + NH ₄ / - according to the method of Tyurin-Kononova, the content of mobile forms of magnesium according to the Al method, the content of trace elements according to the method of TsINA / GOST 26487-85 /.

 The actual parameters of the estimated signs of fertility of a particular soil are used to assess soil fertility in relative terms - points, which are used to judge the fertility of different soils and the different fertility of the same soil.

 Due to the fact that as the reference soil they take soil that contains 20 50% of physical clay, the best granulometric composition of the soil is established, capable of possessing a higher potential fertility. These are loamy soils. Such soils have a wide range of physical ripeness, possess water-physical properties favorable for plant life, for example, bulk density, total porosity, lowest moisture capacity, good water permeability, well retain moisture that is beneficial to plants, and well fix nutrients introduced with fertilizers. All this allows us to create thermal, water, air and nutrient regimes favorable for plant growth on such soils.

 Soils with a lower content of physical clay / <20% / it is sandy loam / 10 20% physical clay / and sandy soil, cohesive sand contains 5 10% physical clay, and loose sand 0 5% physical clay. These soils are structureless, contain little humus and nutrients, poorly retain moisture. Excess moisture that seeps down the profile of the soil removes readily soluble nutrient compounds. Organic matter in such soils is subject to rapid mineralization. Therefore, the scores for such soils in the rating scale / cm. table / set relative to the reference soil as follows. Soils that contain 15% physical clay are assigned 90 points; soils that contain 10% physical clay are assigned 80 points; soils that contain 5 percent or less of physical clay 60 points. This is due to the fact that the less soil contains physical clay, the less fertility it can possess. Increasing the actual parameters, estimated signs of fertility of such soils above the optimal parameters indicated in the rating scale / table /, by applying fertilizers, ameliorants, is impractical, because batteries will not be fixed by soil, but may be subject to leaching with leaking water, while contaminating groundwater and open water. The fertility of such soils can be increased by claying, which increases the content of physical clay in the soil, but this is a very expensive reclamation measure.

 Soils with a higher (> 50%) content of physical clay have high connectivity, have great resistance to processing, have a narrow range of physical ripeness, poor gas exchange with atmospheric air, and also have high moisture capacity and poor water permeability. Water stagnates on the surface of such soils / with excessive rainfall /, when this water dries, a soil crust forms. As a result of this, the vital activity of aerobic bacteria is suppressed on such soils, the mineralization of organic matter is suspended, recovery processes develop, and ferrous compounds Al and Fe harmful to plants accumulate. Therefore, the points for such soils in the rating scale / table / are set relative to the reference soil as follows. Soils that contain 55% physical clay are assigned 90 points; soils that contain 60% physical clay, 80 points; soils that contain 70% physical clay 70 points; soils that contain 80 or more percent of physical clay, 60 points. This is due to the fact that with an increase in the content of physical clay, the water-physical properties of the soil deteriorate, and fertility decreases. Since these soils retain moisture well and fix nutrients well, the actual parameters of fertility signs on these soils can be increased relative to their optimal levels / table / by applying fertilizers, for example, to the highest score. It will not lead to harmful environmental consequences. Therefore, fertilizers on such soils can be added to the reserve. Clay soil fertility can be enhanced by sanding, which reduces the amount of physical clay in the soil, but this is a very expensive reclamation measure.

Due to the fact that the parameters corresponding to its potential fertility (the highest score) are set for the estimated signs of fertility of the reference soil, a comparison object is established, relative to which another soil fertility of the same soil or different soils is evaluated. This solution improves the accuracy and objectivity of the soil fertility assessment and simplifies the method of its assessment. The parameters of the potential fertility of the reference soil are associated or should be coupled with agroclimatic resources, for example, with the arrival of photosynthetically active radiation of the Sun / PAR /, with bioclimatic potential / BKP /, amount of precipitation and concentration of CO ₂ in the atmosphere. These factors together provide the formation of a potential / environmentally possible maximum / crop yield. Therefore, the parameters of the estimated signs of fertility of the reference soil according to the claimed method, corresponding to its potential fertility, are set taking into account environmental conditions. These parameters are determined either on the basis of the analysis of numerous data on the calculation of potential crop yields, or they are determined by calculation.

 The soil with parameters of potential fertility allows you to get the highest crop yield in the given environmental conditions. At the same time, the actual amount of precipitation falling in a particular area is not taken into account, because the lack of moisture can be compensated by reclamation techniques, such as irrigation, even in the desert zone, where at present the coefficient of bioclimatic productivity is taken equal to zero.

 The potential yield of agricultural crops determines the yield price of the reference soil score. This price is determined by dividing the potential yield of a particular crop by the reference soil score / highest score /. Next, the crop price of the point is used to determine the yield of a particular crop on soil with other fertility.

 Due to the fact that the parameters of the estimated signs of fertility of the reference soil, corresponding to its potential fertility, are introduced into the rating scale, the object of comparison and the reference point for constructing the rating scale are established, that is, to determine other parameters of soil fertility, the method for evaluating soil fertility is simplified. These parameters of each evaluative sign of fertility are assigned the highest score, for example 100, and relative to these parameters, the optimal parameters corresponding to another soil fertility with a specific number of points, for example 90, 80, 70, are set on a single assessment basis. The rating scale can be built with less than 10 points, the step of evaluating soil fertility, for example 5, 2 or 1. It all depends on the degree of accuracy of the assessment of soil fertility using an assessment scale.

 Due to the fact that the score that corresponds to the actual parameter of each evaluation feature of the fertility of a particular soil is established on a single evaluation basis, the accuracy of soil fertility assessment is improved and the method for assessing this fertility is simplified. All evaluative signs of fertility are put in the same position and the influence of the subjective approach to assessing soil fertility is removed. As a result of the calculation, an exact fertility score is obtained that corresponds to a specific parameter of the estimated fertility trait.

где
y балл плодородия почвы;
x фактический параметр конкретного основного признака плодородия почвы;
a оптимальный параметр того же признака плодородия эталонной почвы, соответствующей ее потенциальному плодородию;
K объем оценочной шкалы в баллах.A single assessment basis is calculated by the formula

Where
y soil fertility score;
x the actual parameter of a particular underlying trait of soil fertility;
a optimal parameter of the same sign of fertility of the reference soil, corresponding to its potential fertility;
K the volume of the rating scale in points.

 The volume of the rating scale is chosen taking into account the accuracy of the calculations. The crop price of a point for a given crop depends on the scale. Usually use a 100-point or 50-point scale. However, another scale may be selected.

 The x / a ratio in the formula characterizes the saturation of a particular soil with the content of humus or a specific nutrient element relative to its content in the reference soil at the highest score.

 The difference (1 x / a) in the formula characterizes the tension / deficiency, deficit / of one or another sign of fertility, for example, the content of mobile phosphorus in a particular soil relative to its content in the reference soil at the highest score. The greater the saturation of the soil, for example, with the content of mobile phosphorus, the less is the tension of this factor / evaluation feature / in the soil.

в формуле свидетельствует о том, что относительная оценка /балл/ того или иного признака плодородия конкретной почвы обратно пропорциональна напряженности этого признака в почве. Чем меньше напряженность признака, например, подвижного фосфора в почве, тем выше его содержание в почве, тем выше его балл, т.е. чем выше параметр оценочного признака, тем выше его балл. При x a /фактический параметр оценочного признака плодородия равен параметру потенциального плодородия/ напряженность равна нулю, а балл признака /его параметра/ равен высшему баллу, например 100.Expression

in the formula indicates that the relative score / score / of one or another trait of fertility of a particular soil is inversely proportional to the strength of this trait in the soil. The lower the intensity of the trait, for example, mobile phosphorus in the soil, the higher its content in the soil, the higher its score, i.e. the higher the parameter of the evaluation feature, the higher its score. At xa /, the actual parameter of the estimated fertility trait is equal to the potential fertility parameter / tension is zero, and the score of the trait / its parameter / is equal to the highest score, for example 100.

 The exponent square indicates that the dependence of soil fertility on its content of humus, nutrients, pH is non-linear, and the nature of the quadratic function.

 It follows from a single assessment basis that soil fertility is inversely proportional to the squared tension of the limiting factor. Thus, a single assessment basis, calculated according to the specified formula, allows you to objectively judge the fertility of specific soils, objectively evaluate and compare them by fertility, assess the change in fertility of the same soil, since all objective signs of soil fertility are put in the same estimated position relative to each other and reference soil. A single assessment basis allows a fairly accurate assessment of soil fertility in relative terms, points, it is enough to accurately establish a sign of soil fertility, to one degree or another, limiting or not limiting its fertility, and, consequently, plant productivity. Along with this, to judge the soil needs for fertilizers and ameliorants, it is enough to determine their forms, types, norms and doses, which expands the scope of the method.

 Due to the fact that the optimal parameters of each evaluation feature of soil fertility, which has a specific number of points in the volume of the evaluation scale, are established on a single evaluation basis, the construction of an evaluation scale is introduced into which these optimal parameters of soil fertility attributes are introduced. The use of a rating scale simplifies the method of evaluating soil fertility, provides sufficient accuracy and expands the scope of the method. According to the physicochemical analysis, soil samples determine the actual parameter of a particular fertility assessment criterion, find its value in the vertical scale of this trait, and horizontally / table / determine the soil fertility limiting factor, a preliminary fertility score of a particular soil, judge the soil's need for fertilizers and land reclamants, on the possibilities of expanded reproduction of the fertility of a particular soil, determine the cost of soil fertility.

откуда

где
y балл плодородия почвы;
x фактический параметр основного признака плодородия почвы;
a оптимальный параметр того же признака плодородия эталонной почвы, соответствующий ее потенциальному плодородию;
K объем оценочной шкалы в баллах.A single assessment basis is calculated by the formula

where from

Where
y soil fertility score;
x actual parameter of the main sign of soil fertility;
a optimal parameter of the same sign of fertility of the reference soil, corresponding to its potential fertility;
K the volume of the rating scale in points.

 Due to the fact that they determine a sign that limits the fertility of a particular soil, establish the level of fertility of this soil, ensuring normal growth and development of plants and the size of the crop. Above this level, a soil limiting soil fertility trait causes disturbances in plant ontogenesis / metabolism, photosynthesis processes /, worsens product quality, plants are more likely to affect diseases and pests. A limiting trait is determined using the rating scale for the lowest score among the estimated fertility traits. The smallest score corresponds to a well-defined parameter of the estimated sign of fertility, which indicates the presence and deficiency of a particular nutrient element in the soil, as well as the pH value. The definition of a feature limiting soil fertility expands the scope of the method for assessing soil fertility, because the limiting feature determines the need for soil in specific types of fertilizers, ameliorants and their quantity, as well as determine the preliminary fertility score of a particular soil.

 Due to the fact that the preliminary score of the fertility of a particular soil is determined by the lowest score among the main characteristics of soil fertility, a preliminary level of soil fertility, which ensures the normal development of plants, is established, and the quality of a particular soil and its suitability for cultivating crops are judged. Based on this, measures are being developed to increase the fertility of a particular soil, for example, a system of fertilizers, reclamation techniques, determine the crops that are most suitable for cultivation on a given soil, and introduce the appropriate crop rotation.

 The method is as follows.

 1. Determine the potential crop of crops that can be obtained in the environmental conditions of a particular region. For example, in the environmental conditions of the Leningrad Region, solar energy allows you to get a barley crop of 7 t / ha.

 2. Set the parameters of the main signs of fertility of the reference soil, corresponding to its potential fertility, which are necessary to obtain a potential crop of crops.

For example, loamy soils that contain from 20 to 50% physical clay should have a pH of 6.5 to 7.0 and contain 5% or more humus, 30 mg per 100 g of soil mobile phosphorus / P ₂ O ₅ /, 30 mg per 100 g of potassium exchange soil / K ₂ O /, 14 mg per 100 g of soil of easily hydrolyzable nitrogen, 30 mg per 100 g of soil of mobile magnesium / MgO /, more than 10 mg per 1 kg of soil of mobile manganese, 1.5 mg of boron, 0, 5 mg per 1 kg of molybdenum soil, 10 mg of zinc, 7 mg per 1 kg of copper soil, 5 mg of cobalt. The fertility of such soil is assigned the highest score, for example 100 points / cm. table.

3. Determine the crop price of the crop score. It is determined by dividing the potential yield of a particular crop by the score of the potential fertility of the reference soil. For example, for barley, the crop price of a point will be:
7.0 t / ha 100 0.07 t / ha.

 4. Build a rating scale / table /, in which, relative to the points and parameters of the estimated signs of fertility of the reference soil, which are entered in the rating scale, points are set for other soils with less clay in terms of physical clay content.

 For example, soils that contain more than 80% of physical clay are assigned 60 points as soils with a narrow range of physical ripeness and unfavorable hydrothermal conditions and water-physical properties for plant growth and development.

откуда

где
x фактический параметр основного признака плодородия почвы;
a оптимальный параметр того же признака плодородия эталонной почвы, соответствующий ее потенциальному плодородию;
y балл плодородия почвы;
K объем оценочной шкалы в баллах.The optimal parameters of the main signs of fertility, which have a specific number of points in the volume of the rating scale, are established. To do this, use a single assessment basis, calculated by the formula

where from

Where
x actual parameter of the main sign of soil fertility;
a optimal parameter of the same sign of fertility of the reference soil, corresponding to its potential fertility;
y soil fertility score;
K the volume of the rating scale in points.

 For example, the soil, which is assigned 60 points / table /, should contain 1.9% humus, 11 mg per 100 g of soil of mobile phosphorus and exchange potassium, 5 mg per 100 g of soil of hydrolyzable nitrogen, etc. /cm. table. In this way, for the rating scale / table /, the optimal parameters of soil fertility characteristics are established that correspond to a specific soil fertility score in the volume of the rating scale, for example 60 points.

 5. A sample of a specific soil is taken and its physical and chemical analysis is carried out, in which the content of physical clay and the actual parameters of the main and additional signs of fertility of the studied soil are determined.

 For example, a physico-chemical analysis of a sample of a particular soil showed the following results. A soil sample contains 37% physical clay, has a soil solution pH of 6.6, contains 5.1% humus, 10 mg per 100 g of soil of mobile phosphorus, 17 mg of metabolized potassium, 8 mg of easily hydrolyzable nitrogen, 20 mg of mobile magnesium, 7 mg per 1 kg of soil of mobile manganese, 10 mg of boron, 0.4 mg of molybdenum, 7 mg of zinc, 8 mg of copper, 3.2 mg of cobalt.

где
y балл плодородия почвы;
x фактический параметр основного признака плодородия почвы;
a оптимальный параметр того же признака плодородия эталонной почвы, соответствующий ее потенциальному плодородию;
K объем оценочной шкалы в баллах.6. Set the fertility score, which corresponds to the actual parameter of each evaluation feature of the fertility of a particular soil. To do this, use the rating scale / table / or a single assessment basis, calculated by the formula

Where
y soil fertility score;
x actual parameter of the main sign of soil fertility;
a optimal parameter of the same sign of fertility of the reference soil, corresponding to its potential fertility;
K the volume of the rating scale in points.

For example, the fertility scores of the actual parameters of the above specific soil samples, determined using an assessment scale or a single calculation basis, will be the following, score:
37% physical clay 100
pH 6.6 100
5.1% humus 100
10 mg per 100 g of soil mobile phosphorus 51
17 mg per 100 g of potassium exchange soil 80
8 mg per 100 g of soil easily hydrolyzed nitrogen 80
20 mg per 100 g of mobile magnesium soil 88
7 mg per 1 kg of soil of mobile manganese 90
10 mg per 1 kg of soil of mobile boron 90
0.4 mg per 1 kg of soil of mobile molybdenum 96
7 mg per 1 kg of soil mobile a 90
8 mg per 1 kg of soil of mobile copper 100
3.2 mg per 1 kg of soil of mobile cobalt 87
7. Determine the sign that limits the fertility of the studied soil and the parameter score of this sign.

 For example, a sign that limits the fertility of the soil in question is the content of mobile phosphorus in it. The content of mobile phosphorus is 10 mg per 100 g of soil, which is 51 points. This feature, namely, the content in the soil of 10 mg per 100 g of soil of mobile phosphorus, limits the growth and development of plants and their productivity in the studied soil.

 8. Determine the preliminary fertility score of a particular soil. It is taken equal to the score of the trait limiting the fertility of this soil. For example, for the soil in question, the preliminary fertility score was 51 points.

 9. The total fertility score of a particular soil is determined taking into account correction factors, for example, on the thickness of the arable layer. For example, when the thickness of the arable layer is 22 cm, the correction factor is unity. Then the total fertility score of a particular soil in our example will be equal to the preliminary 51 • 1,0 51.

 The yield of crops that can be obtained on specific soil is determined. For example, the barley crop on the soil in question can be 0.07 t / ha • 51 3.38 t / ha. This yield is determined by multiplying the yield of the price of a specific crop point by the total fertility score of a specific soil.

 10. From the physicochemical analysis of a specific soil sample it follows that other parameters of the estimated fertility traits have higher scores than the score of the limiting trait. For example, the content of mobile potassium and easily hydrolyzable nitrogen in the soil is 80 points, and the parameters of other signs of fertility have even higher scores. Therefore, the preliminary and total fertility scores of the soil considered in the example can be increased by eliminating the influence of the trait limiting the fertility of this soil by adding phosphorus fertilizers at the rate of / 80 51 points / 17 mg 10 mg per 100 g of soil 7 mg per 100 g of soil in the current substance, which will increase the possible level of productivity, for example, barley up to 5.6 tons per 1 hectare; 0.07 • 80 5.6 t / ha.

11. From the physico-chemical analysis of the sample of the studied soil, it follows that in order to increase its fertility, considered in the example, to the level of 100 points, it should be added to it due to fertilizer / cm. table /:
mobile phosphorus 30 10 20 mg per 100 g of soil
exchange potassium 30 17 13 mg per 100 g of soil
easily hydrolyzable nitrogen 14 8 6 mg per 100 g of soil
mobile magnesium 30 20 10 mg per 100 g of soil
mobile manganese 10 7 3 mg per 1 kg of soil
mobile boron 1.5 1.0 0.5 mg per 1 kg of soil
mobile molybdenum 0.5 0.36 0.14 mg per 1 kg of soil
mobile zinc 10 7 3 mg per 1 kg of soil
no mobile forms of copper 7 8 no
mobile cobalt 5 3.2 1.8 mg per 1 kg of soil
in the active substance.

 Such soil will have the parameters of potential fertility of the reference soil, and have the highest score. With a favorable hydrothermal regime of soil and atmosphere on such soil, the maximum / potential / environmentally possible crop yield, for example, barley, 7 tons per 1 ha, can be obtained.

 The cost parameters of soil fertility are determined by the actual parameters of soil fertility, and the costs of soil fertility reproduction are determined by the cost of fertilizer, land reclamation materials, agricultural and land reclamation techniques. To reduce the parameters of signs of fertility, determine the compensation fund necessary to restore the original fertility of a particular soil.

Claims (1)

A method for evaluating soil fertility, according to which the content of physical clay and the actual parameters of the main and additional signs of fertility are determined by physicochemical analysis in the studied soil, while the pH and humus content are determined among the main characteristics of fertility, by comparing the obtained data with the scale, the studied soil is evaluated as a result of which, according to the actual parameters of the main features, a preliminary score of the fertility of the studied soil is established, and the final score of its fertility determined after correction coefficients on additional parameters of fertility characteristics, characterized in that among the main features of fertility further determine the content of macro- and trace elements based on the estimated, which is calculated by the formula

where y is the soil fertility score;
x the actual parameter of a specific main sign of fertility of the studied soil;
and the optimal parameter of the same sign of fertility, corresponding to the highest score of soil fertility;
To the volume of the rating scale (the highest score of soil fertility),
scores of the actual parameters of each main sign of fertility of the studied soil are determined, the preliminary score of the fertility of the studied soil and a sign limiting its fertility are determined by the smallest score of the main features.

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