RU2728482C1 - Methods for direct geochemical prediction of hydrocarbon deposits - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to geochemical methods of hydrocarbon search and can be used in search and prediction of availability of hydrocarbon deposits. Disclosed is a method of geochemical prediction, including determining a list of hydrocarbon compounds capable of migration, from a sample of hydrocarbon fluid of one of deposit deposits, determination according to the list of hydrocarbon compounds capable of migration, reference quantitative hydrocarbon composition of samples obtained during geochemical testing in the zone of established presence of hydrocarbon influx, determination of hydrocarbon compounds capable of migration, reference quantitative hydrocarbon composition of samples obtained during geochemical testing in the zone of established absence of hydrocarbon influx. Method also includes obtaining hydrocarbon samples as a result of geochemical local testing in territory of prediction of hydrocarbon deposits and determination of hydrocarbon compounds capable of migration, quantitative hydrocarbon composition of said samples and assigning each hydrocarbon sample obtained on territory of prediction of hydrocarbon deposits to place of predicted presence or absence of hydrocarbon influx by criterion of similarity of quantitative hydrocarbon composition of samples obtained as a result of area geochemical testing, reference hydrocarbon compositions of samples obtained during geochemical testing in zones of established presence and absence of hydrocarbon influx.

EFFECT: technical result is higher efficiency and accuracy of prediction of availability of hydrocarbon deposits, as well as shorter analysis time of hydrocarbon composition of samples obtained during geochemical testing, and simplification of sampling.

32 cl, 2 tbl, 2 dwg

Description

The invention relates to geochemical methods for the search for hydrocarbons and can be used in the search and prediction of the presence of hydrocarbon deposits.

There is a known method of geochemical testing of local objects in predicting oil content (patent RU2298816, publ. 05/10/2007, IPC: G01V 9/00), in which soil samples are taken and analysis of hydrocarbon gases extracted from the natural sorbent (soil), data sampling of a nearby object with proven oil content, while at an object with a known oil and gas content, surface gas-geochemical calibration is carried out with soil sampling, the data obtained is used to calculate the background values of gas-geochemical indicators, contrast ratios of hydrocarbon gases, build maps of gas saturation for hydrocarbon gases and to build a model of probable oil-bearing area. Common features with the claimed invention are the determination of the composition (analysis) of hydrocarbon gases extracted from the sorbent (soil), obtaining reference data and comparing the results obtained in the territory of predicting the presence of a deposit with reference data.

However, a natural sorbent, especially in near-surface conditions, is characterized by heterogeneity of sorption properties, which leads to a differentiation of the background characteristics of geochemical fields and, accordingly, reduces the efficiency and accuracy of forecasting hydrocarbon deposits. Due to the uncertainty of the list of reference hydrocarbon compounds, the known method requires the analysis of all hydrocarbon compounds that are obtained at an object with a known oil and gas content, which leads to an increase in the analysis time of the hydrocarbon composition.

The known method of geochemical exploration (patent US 4573354, publ. 03/04/1986, IPC: G01V 9/00), which includes the preparation of holes in the soil, placement in the holes of sorbers, filling holes, sorption of volatile substances, subsequent removal from the holes of the sorbers, carrying out analysis of sorbed volatile substances, storage of the obtained data on a computer, statistical processing of the obtained data in order to determine the nature of the underground deposit and to determine the similarity with "fingerprints", i.e. in this context, the composition of volatiles from a known source (around a known well). In doing so, reference "fingerprints" are obtained around known oil and gas wells, and then a prediction map is made based on this similarity. The common features of the known and claimed technical solutions are geochemical testing, analysis of volatile substances (hydrocarbons) sorbed on the sorbent and comparison of the data obtained with the previously obtained (reference) data.

However, due to the variety of processes of changes in the composition of hydrocarbons during their migration from deposits to the day surface under the influence of the specific conditions in a particular part of the geological section, it is difficult to determine which hydrocarbon compounds will be informative for predicting the presence of hydrocarbon deposits. Therefore, using as reference data only hydrocarbons released during geochemical testing over known oil and gas wells, without data on the hydrocarbon composition of the reservoir fluid (oil, gas condensate) for subsequent comparison with the results of geochemical testing in the forecast area is not informative enough, which leads to decrease in the efficiency and accuracy of the forecast. The uncertainty of the list of reference hydrocarbon compounds leads to the need to analyze all hydrocarbon compounds that are obtained at an object with a known oil and gas content, which leads to an increase in the time for analyzing the composition of hydrocarbons.

The closest analogue (prototype) is a method of searching for hydrocarbon deposits based on the principle of passive adsorption (patent RU 2499285, published on November 20, 2013, IPC: G01V 9/00), according to which sorbers-collectors are placed in the soil holes, hold for sorption by sorbers - collectors of hydrocarbon gases, extraction of sorbers-collectors, determination of hydrocarbon gases in samples, comparing the results of analyzes with reference data, interpretation of data in the algorithm of the training and mapping system, at the same time, at least 150 hydrocarbon compounds are isolated, and data on hydrocarbon are used as reference data compounds adsorbed by sorbers-collectors around the empty well and the oil well. Common features are geochemical sampling, determination of the composition of hydrocarbons (analysis of adsorbed volatiles), and comparison of the data obtained during areal geochemical sampling with reference data.

However, as mentioned above, due to the variety of processes of changes in the composition of hydrocarbons during their migration from deposits to the day surface, as well as due to biochemical processes on the surface, it is difficult to determine which hydrocarbon compounds can be attributed to indicators of the presence of hydrocarbon deposits, and which reflect surface biochemical processes that also result in the formation of hydrocarbons. Therefore, the use of only hydrocarbons released during geochemical testing over known productive wells as reference data, without data on the hydrocarbon composition of the reservoir fluid, is not informative enough, which leads to a decrease in the efficiency and accuracy of the forecast. Also, the choice of 150 hydrocarbon compounds, which are proposed to be used as standards, is not justified, according to which, in order to increase the efficiency and accuracy of forecasting, it may be necessary to analyze the entire list of hydrocarbons from samples obtained at the reference facilities, which will lead to an increase in the time for analyzing the composition of hydrocarbons.

The technical result of the invention is to increase the efficiency and accuracy of predicting the presence of hydrocarbon deposits, as well as to reduce the time for analyzing the hydrocarbon composition of samples obtained during geochemical testing, and to simplify the taking of these samples. Predicting the presence of hydrocarbon deposits can also include delineating hydrocarbon deposits, determining the phase composition of the reservoir fluid (oil, gas condensate, gas) and the stratigraphic range of the location of the reservoir in the geological section. This makes it possible to increase the efficiency of areal geochemical works and reduce the material and time costs for more expensive methods of geological exploration. At the same time, the simplification of sampling is provided due to the ability to predict and preselect the effective composition of the sorbents used in the sorber.

The technical result is achieved by using the method, including determining the list of hydrocarbon compounds capable of migration from a sample of hydrocarbon fluid of one of the deposits of the field, determining the reference quantitative hydrocarbon composition of samples obtained during geochemical testing in the zone of the established the presence of an inflow of hydrocarbons, determination of the reference quantitative hydrocarbon composition of samples obtained during geochemical sampling in the zone of the established absence of inflow of hydrocarbons from the list of hydrocarbon compounds capable of migration, obtaining hydrocarbon samples as a result of areal geochemical sampling in the territory of forecasting hydrocarbon deposits and determination according to the list hydrocarbon compounds capable of migration, the quantitative hydrocarbon composition of these samples and the assignment of each hydrocarbon sample obtained at the territory of forecasting hydrocarbon deposits, to the place of the predicted presence or absence of hydrocarbon influx according to the criterion of similarity of the quantitative hydrocarbon composition of samples obtained as a result of areal geochemical sampling, reference hydrocarbon compositions of samples obtained during geochemical sampling in zones of established presence and absence of hydrocarbon influx.

The claimed method is aimed at using direct indicators of oil and gas content in geochemical testing - data on the hydrocarbon composition of the reservoir fluid, i.e. thermogenic hydrocarbons.

The technical result is achieved by determining from the sample of the hydrocarbon fluid of the deposit of the field a list of hydrocarbon compounds capable of migration from the depths to the day surface. This makes it possible to reasonably determine the amount and compile a list of hydrocarbon compounds that directly characterize the reservoir fluid and which are identified in the composition of the samples obtained during geochemical testing to predict the presence of a hydrocarbon reservoir, which improves the efficiency and accuracy of predicting hydrocarbon deposits.

The use of this list makes it possible to exclude from the comparative analysis with the standards those hydrocarbon compounds that are not part of the reservoir fluid. When analyzing the full list of hydrocarbons that are part of the samples obtained during geochemical sampling, it leads not only to an increase in the analysis time, but also to a decrease in the efficiency and accuracy of predicting the presence of a reservoir. This is due to the fact that the composition of the analyzed hydrocarbons will also include hydrocarbon compounds that are contained in the soil, and not the fluid of the hydrocarbon deposit. When analyzing a narrow list of hydrocarbons, the analysis time is reduced, but the probability of forecasting errors increases due to a decrease in the amount of hydrocarbon compounds that are identified in the composition of samples obtained during geochemical sampling, since identification error for several hydrocarbons can affect the conclusion about the prediction of the presence of a reservoir. When implementing the claimed methods, the comparative analysis of the quantitative hydrocarbon composition of samples with the reference quantitative hydrocarbon composition is carried out precisely in relation to a reasonable list of hydrocarbons characterizing the reservoir, which reduces the likelihood of prediction errors and reduces the research time in relation to the analysis of the full list of hydrocarbons. Preliminary determination of the indicated hydrocarbon compounds also allows to reduce the time of analysis of the hydrocarbon composition of samples obtained during geochemical sampling due to the fact that there is no need to analyze the complete list of hydrocarbon compounds of these samples.

The process of migration of hydrocarbon compounds from the depths to the surface is a complex combination of mass transfer processes (filtration, diffusion) of both liquid and gaseous hydrocarbons. Moreover, both forms of mass transfer occur in a heterogeneous lithological environment and are accompanied by natural fractionation of hydrocarbons. In this regard, from the list of hydrocarbon compounds that are obtained from a hydrocarbon fluid sample, a list of hydrocarbon compounds is determined, the properties of which allow them to migrate from hydrocarbon accumulations in the depths to the day's surface in the geological conditions of the area where geochemical sampling is carried out.

This makes it possible to obtain accurate quantitative characteristics, taking into account the properties of the geological section in the area of geochemical sampling, and only those hydrocarbon compounds that are part of the hydrocarbon fluid of the reservoir are taken into account. The indicated quantitative hydrocarbon compositions of the samples are taken as reference for the place of predicting the presence or absence of hydrocarbon influx.

An artificial sorbent is understood as any pretreated natural or synthesized sorbent that has homogeneous sorption characteristics, i.e. the sorption characteristics of sorbents located in different holes do not differ relative to each other.

When obtaining hydrocarbon samples as a result of conducting areal geochemical testing in the territory of forecasting hydrocarbon deposits, the quantitative hydrocarbon composition of these samples is determined according to the list of hydrocarbon compounds capable of migration.

Thus, only quantitative hydrocarbon data are compared, which are directly related to the composition of the hydrocarbon fluid of the reservoir. This makes it possible to assign the samples obtained in the forecasting territory to the place of the predicted presence or absence of hydrocarbon inflows in the forecasting territory according to the criterion of similarity of the quantitative hydrocarbon composition of these samples to the reference hydrocarbon compositions of the samples obtained during geochemical sampling in the zones of the established presence and absence of hydrocarbon inflow.

Geochemical testing may include fixing the geographic coordinates of the location of the holes in which the sorbers with sorbents are placed. The results obtained are saved and can be used, for example, to compile a geochemical map for predicting hydrocarbon deposits by the geographic coordinates of hydrocarbon samples obtained as a result of areal geochemical testing in the territory of predicting hydrocarbon deposits, indicating the places of the predicted presence or absence of hydrocarbon deposits.

Determination of the list of hydrocarbon compounds of a hydrocarbon deposit capable of migration may include taking at least one sample of hydrocarbon fluid from at least one well that has exposed one of the hydrocarbon deposits of the field, and holding at least one artificial sorbent over the sample of hydrocarbon fluid, obtaining a sample hydrocarbons as a result of desorption of sorbed hydrocarbons from the sorbent and determination of the list of desorbed hydrocarbons of the sample, selection of the list of hydrocarbon compounds by the criterion of migration ability to the surface from the list of desorbed hydrocarbons of the deposit. The well can be located on the territory or near the landfill for the areal geochemical sampling.

The criterion of migration ability to the surface may include the following indicators: thermogenic nature of hydrocarbon compounds; the content of hydrocarbon compounds of hydrogen and carbon; resistance of the selected compound to oxidation in near-surface conditions; reproducible identification of a hydrocarbon compound when the sorbent is held over a hydrocarbon fluid sample. The criterion of migration ability can also include other indicators, in particular, an increased pressure of saturated vapors of hydrocarbon compounds, which facilitates the process of migration of hydrocarbons through the lithological medium to the surface.

The reference quantitative hydrocarbon composition of the sample obtained in the zone of the established presence of a hydrocarbon inflow may correspond to a 100% probability of the presence of a hydrocarbon deposit. In this case, the criterion of similarity of quantitative compositions is also assessed by the value of the probability of the presence or absence of a deposit. The criterion for the similarity of the quantitative composition of hydrocarbon samples obtained in the predicted territory to the reference quantitative compositions of hydrocarbon samples obtained in the zone of the established presence of hydrocarbon inflow can correspond to the values of the probability of the presence of hydrocarbon deposits of more than 75%.

The choice of the criterion for the similarity of the quantitative composition of hydrocarbon samples obtained in the forecast area to the reference quantitative compositions of hydrocarbon samples that are obtained in the zone of the established presence of hydrocarbon influx can be carried out by any method known to a person skilled in the art.

The zone of the established presence of hydrocarbon inflow can correspond to an area within a radius of up to 100 meters from the wellhead of a productive well, or, for example, an area within the boundaries of the established contour of a known field.

The zone of the established lack of hydrocarbon inflow can correspond to an area within a radius of up to 100 meters from the wellhead of a non-productive well, or, for example, a background area located outside the established contour of a known field.

Determination of the reference quantitative hydrocarbon composition of a sample obtained as a result of geochemical testing in the zone of the established presence of an inflow may include drilling at least one hole in the zone of the established presence of hydrocarbon inflow and fixing the geographical coordinates of their location, placing at least one artificial sorbent in the hole, obtaining, as a result of desorption from the artificial sorbent, a sample of desorbed hydrocarbons and determining, from the list of hydrocarbon compounds capable of migration, a reference quantitative hydrocarbon composition of the obtained sample of desorbed hydrocarbons.

Determination of the reference quantitative hydrocarbon composition of the sample obtained as a result of geochemical testing in the zone of the established lack of inflow may include drilling at least one hole in the zone of the established absence of inflow of hydrocarbons and fixing the geographical coordinates of their location, placing at least one artificial sorbent in the hole, obtaining, as a result of desorption from the artificial sorbent, a sample of desorbed hydrocarbons and determining, from the list of hydrocarbon compounds capable of migration, a reference quantitative hydrocarbon composition of the obtained sample of desorbed hydrocarbons.

The method may additionally include determining the list of hydrocarbon compounds capable of migration from a sample of hydrocarbon fluid of the second reservoir of the field, determining, from the list of hydrocarbon compounds capable of migration, for the second reservoir, the reference quantitative hydrocarbon composition of samples obtained during geochemical testing in the zone of established presence hydrocarbon inflow, determination from the list of hydrocarbon compounds capable of migration for the second deposit of the reference quantitative hydrocarbon composition of samples obtained during geochemical testing in the zone of the established absence of hydrocarbon inflow, determination from the list of hydrocarbon compounds capable of migration for the second deposit of quantitative hydrocarbon composition samples obtained as a result of areal geochemical sampling in the territory of forecasting hydrocarbon deposits, and assignment of each hydrocarbon sample obtained to the territory and forecasting hydrocarbon deposits, to the place of the predicted presence or absence of hydrocarbon influx by the criterion of similarity of the quantitative hydrocarbon composition of samples obtained as a result of areal geochemical sampling, reference quantitative hydrocarbon compositions of samples obtained during geochemical sampling in zones of the established presence and absence of hydrocarbon influx, when this hydrocarbons are included in the list of hydrocarbon compounds capable of migration for the second reservoir.

Additionally, it is possible to compile a geochemical map for predicting hydrocarbon deposits by geographic coordinates of hydrocarbon samples obtained as a result of areal geochemical testing in the territory of predicting hydrocarbon deposits, indicating the places of the predicted presence or absence of the first hydrocarbon deposit and indicating the places of the predicted presence or absence of the second hydrocarbon deposit.

Due to the fact that hydrocarbon fluids from different deposits can differ significantly from each other, the lists of hydrocarbon compounds capable of migration of the first and second deposits of the field can also be different. This makes it possible, when using these two lists, to increase the efficiency and accuracy of predicting the presence and delineation of nearby deposits.

Determination of the list of hydrocarbon compounds capable of migration of the second reservoir of the field may include, as well as for the first reservoir of the field, taking at least one sample of hydrocarbon fluid from at least one well that opened the second hydrocarbon reservoir of the field, holding at least one artificial sorbent over a hydrocarbon fluid sample, obtaining a sample of desorbed hydrocarbons as a result of desorption from an artificial sorbent and determining a list of desorbed hydrocarbons, separating a list of hydrocarbon compounds capable of migration from the list of desorbed hydrocarbons according to the criterion of migration ability to the surface. The criterion of migration ability to the surface, as indicated above, may include the following indicators: thermogenic nature of hydrocarbon compounds; the content of hydrocarbon compounds of hydrogen and carbon; the stability of the hydrocarbon compound to oxidation in near-surface conditions; reproducible identification of a hydrocarbon compound when the sorbent is held over a hydrocarbon fluid sample.

Determination of reference quantitative hydrocarbon compositions of samples obtained during geochemical testing in zones of established presence and absence of hydrocarbon influx includes the stages indicated above for the first reservoir, taking into account the fact that it is carried out according to the list of hydrocarbon compounds capable of migration of the second reservoir of the field.

Achievement of the technical result is ensured by using a method that includes obtaining from a database a list of hydrocarbon compounds capable of migration, determined from a sample of a hydrocarbon fluid, determining from a list of hydrocarbon compounds capable of migration, a reference quantitative hydrocarbon composition of samples obtained during geochemical testing in zone of established presence of hydrocarbon inflow, determination of the reference quantitative hydrocarbon composition of samples obtained during geochemical testing in the zone of established absence of hydrocarbon inflow, based on the list of hydrocarbon compounds capable of migration, determination of hydrocarbon samples as a result of areal geochemical testing in the territory of forecasting hydrocarbon deposits and determination according to the list of hydrocarbon compounds capable of migration, the quantitative hydrocarbon composition of these samples and the assignment of each hydrocarbon sample, by obtained on the territory of forecasting hydrocarbon deposits, to the predicted presence or absence of hydrocarbon influx according to the criterion of similarity of the quantitative hydrocarbon composition of samples obtained as a result of areal geochemical sampling, reference hydrocarbon compositions of samples obtained during geochemical sampling in zones of the established presence and absence of hydrocarbon influx.

The specified database can be formed when performing the following stages: selection of at least one sample of hydrocarbon fluid from at least one well that has exposed one of the hydrocarbon deposits of the field; holding at least one artificial sorbent over a sample of hydrocarbon fluid, obtaining, as a result of desorption from the artificial sorbent, a sample of desorbed hydrocarbons and determining a list of desorbed hydrocarbons; selection of the list of hydrocarbon compounds capable of migration from the list of desorbed hydrocarbons according to the criterion of migration ability to the surface, and fixing the list of hydrocarbon compounds capable of migration in the database.

The technical result is also achieved when using the method, including the use of a database that contains at least one list of hydrocarbon compounds capable of migration, obtained from a sample of a hydrocarbon fluid, and the reference quantitative hydrocarbon compositions of samples determined from this list, obtained during geochemical testing in zones of established presence and absence of inflow of hydrocarbons, obtaining hydrocarbon samples as a result of conducting areal geochemical testing in the territory of forecasting hydrocarbon deposits and determining the quantitative hydrocarbon composition of these samples from the list of hydrocarbon compounds capable of migration, assigning each sample of hydrocarbons obtained in the territory of forecasting hydrocarbon deposits , to the place of the predicted presence or absence of hydrocarbon influx according to the criterion of similarity of the quantitative hydrocarbon composition of the samples obtained as a result of the area geochemical sampling, reference hydrocarbon compositions of samples obtained during geochemical sampling in zones of established presence and absence of hydrocarbon influx.

Formation of the database in this case may include the following stages: selection of at least one sample of hydrocarbon fluid from at least one well that has exposed one of the hydrocarbon deposits of the field; holding at least one artificial sorbent over the hydrocarbon fluid sample; obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons and determining a list of desorbed hydrocarbons; selection from the list of desorbed hydrocarbons according to the criterion of migration ability to the surface of the list of hydrocarbon compounds capable of migration; fixing the list of hydrocarbon compounds capable of migration in the database; drilling at least one hole in the area of the presence of hydrocarbon inflow and at least one hole in the area of no flow of hydrocarbons; placing in each hole at least one artificial sorbent; obtaining, as a result of desorption from artificial sorbents, samples of desorbed hydrocarbons; determination of the list of hydrocarbon compounds capable of migration, and recording in the database of the reference quantitative hydrocarbon composition of the sample of desorbed hydrocarbons obtained in the zone of presence of hydrocarbon influx; determination of the list of hydrocarbon compounds capable of migration, and recording in the database of the reference quantitative hydrocarbon composition of the sample of desorbed hydrocarbons obtained in the zone of no hydrocarbon influx.

The claimed methods can also additionally include the compilation of a geochemical map for predicting hydrocarbon deposits by the geographic coordinates of hydrocarbon samples obtained as a result of conducting areal geochemical testing in the territory of predicting hydrocarbon deposits, indicating the predicted presence or absence of the first hydrocarbon deposit and indicating the predicted presence or absence of a second hydrocarbon deposit ...

The reference quantitative hydrocarbon composition of the sample obtained during geochemical sampling in the zone of the established presence of hydrocarbon inflow can correspond to 100% of the probability of the presence of a hydrocarbon deposit, the criterion for the similarity of the quantitative hydrocarbon composition of the samples obtained in the forecast area, the reference quantitative hydrocarbon composition of the samples obtained during the geochemical sampling in the zone of the established presence of hydrocarbon inflow, while it can correspond to the values of the probability of the presence of hydrocarbon deposits over 75%.

The technical result when using methods, including the use of databases, is achieved due to a reasonable increase in the number of hydrocarbon compounds that are characteristic of fluids of hydrocarbon deposits and are capable of migrating from the bowels to the day surface, which makes it possible to use these hydrocarbon compounds as informative indicators in predicting the presence of hydrocarbon deposits.

The lists of hydrocarbon compounds capable of migration may include at least 200 hydrocarbon compounds. A decrease in the specified amount can only be associated with the use of an artificial sorbent, which, by its physical properties, does not provide for the sorption of the specified amount of hydrocarbon compounds. The increase in this amount is associated with the use of sorbents or a group of sorbents that provide sorption of various hydrocarbon compounds. In this connection, it is possible to use sorbers with various sorbents, which provide sorption of hydrocarbons of various compositions. Determination of the list of hydrocarbon compounds capable of migration also makes it possible to predict the effective composition of sorbents, which are optimally used when conducting areal geochemical sampling in geological conditions of specific territories. In particular, it can be both mono- (in the case of deposits with similar hydrocarbon composition) and combined (in the case of deposits with different hydrocarbon compositions) sorbent options, which allows you to sorb a wide range of hydrocarbons and improve the accuracy and efficiency of forecasting hydrocarbon deposits.

The depth of drilling a hole during geochemical testing can be from 1.5 to 3 meters, which is the most accessible depth from an economic point of view and can be achieved using a drilling tool that excludes the use of fuels and lubricants that can affect the results of geochemical testing.

Determination of the composition of desorbed hydrocarbons can be carried out by gas chromatography-mass spectroscopy.

The claimed methods can also additionally include the determination of the values of methane-free coefficients when conducting areal geochemical sampling in the forecast area, in particular ethane (C ₂ H ₆ / C ₃ H ₈ + higher hydrocarbons) and butane (iso-C ₄ H ₁₀ / n-C ₄ H ₁₀ ), and drawing up on the basis of these values a map for predicting the dominant phase composition of the hydrocarbon fluid of the hydrocarbon reservoir. Methane-free coefficients characterize the predominant type of fluid saturation of the section, i.e. indicate what type of hydrocarbon fluid is predominantly characteristic of the predicted hydrocarbon reservoir. This is provided in the case of using sorbents that allow the sorption of light fractions of hydrocarbons. The use of methane-free coefficients for assessing the dominant type of fluid saturation in a geological section is associated with the possible high activity of biochemical processes in the territory of predicting the presence of hydrocarbon deposits. Ethane coefficient values from 0.5 to 1.2 indicate the predominant content of oil, from 1.2 to 2.5 - gas condensate, from 2.5 to 4 - mainly gas deposits. When the butane coefficient values are less than 0.5, the deposits are mainly characterized by oil fluid, from 0.5 to 0.8 - oil and gas condensate, from 0.8 to 1.1 - gas condensate, more than 1.1 - gas. This makes it possible to additionally predict the phase composition of hydrocarbon deposits; In this connection, at the first stage of zoning according to the phase composition of fluid saturation, ethane and butane coefficients are used.

Determination of the predominant phase composition of the hydrocarbon fluid can also be established by hydrocarbons, which are included in the list of hydrocarbon compounds capable of migration. In this case, the predominant content of hydrocarbons is determined, either gas condensate (C ₄ -C ₆ hydrocarbons (alkanes)) or petroleum hydrocarbons (C ₆ + higher (alkanes, cyclic and aromatic) hydrocarbons).

Additionally, the claimed methods may include soil sampling during areal geochemical sampling, determination of the quantitative hydrocarbon composition of samples of hydrocarbon gases of the composition C ₁ -C ₅ , determination of the values of methane-free coefficients and drawing up on the basis of these values a geochemical prediction map of the dominant phase composition of hydrocarbon deposits. As mentioned above, the values of methane-free coefficients characterize the dominant type of fluid saturation of the geological section, which makes it possible, on their basis, to draw up a map of geochemical prediction of the dominant phase composition of hydrocarbon deposits.

Additionally, the methods can also include soil sampling during areal geochemical sampling, determination of the quantitative hydrocarbon composition of samples of hydrocarbon gases of composition C ₁ -C ₅ and determination of the isotopic composition of carbon and hydrogen of hydrocarbon gases of composition C ₁ -C ₅ . Based on the results of the analysis of the carbon isotopic composition (MCI) of thermogenic hydrocarbons, mainly the most representatively studied MCI of methane, an approximate geochemical assessment of the stratigraphic position of the sources of the "hydrocarbon deposit" type, revealed during the areal geochemical sampling, is provided. This is due to the fact that the fractionation of stable isotopes ¹² C and ¹³ C, as one of the components in the evolution of carbon Geosphere- - a process that is well-studied to date, until the allocation of intervals of methane ISU values rock complexes major hydrocarbon gas bearing regions.

The methods may additionally include taking soil samples during areal geochemical sampling, obtaining carbon dioxide, helium, hydrogen, oxygen as a result of degassing soil samples, and determining the isotopic composition of carbon in the composition of carbon dioxide. Based on the study of the distribution of concentrations of migratory-active gases (helium, hydrogen, methane, etc.) in soil sediments based on the results of studying soil samples obtained during geochemical sampling, it is also possible to predict the depth of occurrence of fluid-conducting zones of a geological section, including tectonic disturbances ...

Additionally, the methods may include taking soil samples when conducting areal geochemical sampling, analyzing the content of organic matter in soil samples obtained during areal geochemical sampling. This makes it possible to determine the zones of distribution of organogenic deposits (peat bogs), take into account and remove the distorting effect of organic matter containing hydrocarbons in soils when determining the quantitative composition of hydrocarbon samples obtained during areal geochemical sampling, which makes it possible to further increase the efficiency and accuracy of predicting the presence of hydrocarbon deposits.

The invention is illustrated by the following figures:

- figure 1 is a general diagram illustrating the implementation of the method,

- figure 2 - geochemical map of forecasting hydrocarbon deposits.

The figures indicate: 1 - sample of hydrocarbon fluid (oil), 2 - productive well, 3 - glass container in which oil is placed for sorption of hydrocarbons, 4 - list of hydrocarbon compounds capable of migration, 5 - zone of established presence of hydrocarbon influx, 6 - zone of the established absence of hydrocarbon inflow, 7 - unproductive well, 8 - boreholes, 9 - sorbers with artificial sorbent, which are placed in the boreholes, 10 - reference quantitative hydrocarbon composition of samples obtained in zone 5 of the established presence of hydrocarbon influx, 11 - reference quantitative hydrocarbon composition of samples obtained in zone 6 of the established absence of hydrocarbon inflow, 12 - forecast territory, 13 - quantitative hydrocarbon composition of samples obtained during areal geochemical sampling in forecast territory 12.

The method is carried out as follows.

Determine the list of hydrocarbon compounds capable of migration from a sample of hydrocarbon fluid. To do this, a sample of hydrocarbon fluid (oil) 1 is taken from the productive well 2, located within the polygon of areal geochemical works (Fig. 1). In the laboratory, oil 1 is placed in a glass container 3 and sorbers containing an artificial sorbent Tenax TA (Tenax TA) are placed over the oil. At the same time, the sorbers do not come into contact with oil and with each other. Exposure of artificial sorbents over oil is carried out preferably from 7 to 14 days, while it is recommended to use at least 5 sorbents with sorbent to assess the reproducibility of results. Then, the hydrocarbons sorbed on the sorbent are desorbed by the thermal desorption method. As a result of thermal desorption, adsorbed hydrocarbon compounds are isolated from the sorbents, and the extracted hydrocarbons are analyzed using gas chromatography-mass spectrometry (GCMS). Then, in accordance with the criterion of the migration ability of hydrocarbons from the subsurface to the surface, which includes, in particular, the resistance of the hydrocarbon compound to oxidation in near-surface conditions, the thermogenic nature of hydrocarbon compounds and other indicators, a list of 4 hydrocarbon compounds capable of migration is distinguished.

As a result, the specified list 4 included about 200 hydrocarbon compounds, some of which are presented in Table 1.

Based on the list of hydrocarbon compounds capable of migration, the reference quantitative hydrocarbon compositions of samples obtained during geochemical sampling in zone 5 of the established presence of hydrocarbon influx (i.e., in an area within a radius of up to 100 meters from the mouth of productive well 2, from which the sample was taken hydrocarbon fluid samples) and in zone 6 of the established absence of hydrocarbon inflow (i.e., in the area within a radius of up to 100 meters from the mouth of the non-productive well 7, which is also located within the area of geochemical operations). For this, geochemical testing is carried out in the indicated zones 5 and 6: boreholes 8 are drilled with a depth of 1.5 to 3 meters, in which sorbers 9 containing an artificial sorbent are placed, and the sorbent is held in a borehole 8 for 17 to 21 days. The specified period of time is optimal from the point of view of the accumulation of hydrocarbon compounds on the sorbent in an amount sufficient to obtain an intense signal of compounds when analyzing the composition of samples. For a specialist, it is known that the specified period can be increased or decreased when climatic conditions change. After the specified time has elapsed, the laboratory conducts thermal desorption of hydrocarbon components from the surface of the sorbent and analyzes the desorbed hydrocarbons, which are included in the list of hydrocarbon compounds capable of migration, by gas chromatography-mass spectroscopy (GCMS). The quality assessment and grading of the data obtained using the CMS are carried out. Obtained after grading quantitative hydrocarbon compositions of samples 10, obtained in zone 5 of the established presence of hydrocarbon influx, and samples 11 obtained in zone 6 of the established absence of hydrocarbon influx, are used as reference quantitative hydrocarbon compositions of samples.

The reference quantitative hydrocarbon compositions of samples 10 obtained in zone 5 of the established presence of hydrocarbon inflow are taken as 100% probability of the presence of a hydrocarbon deposit. The reference quantitative hydrocarbon compositions of the samples 11 obtained in the zone 6 of the established absence of hydrocarbon inflows are taken as 0% the probability of the presence of hydrocarbon deposits.

Hydrocarbon samples are obtained as a result of areal geochemical sampling in the forecast area of 12 hydrocarbon deposits and the quantitative hydrocarbon composition of these samples is determined in accordance with the list of 4 hydrocarbon compounds capable of migration. In this case, areal geochemical sampling is carried out similarly to the above geochemical sampling to determine the reference quantitative compositions of samples, but according to a given grid (the dimensions of the grid of the location of sorbents can be determined by a specialist, in this case the grid size was 2 km by 2 km). For the data obtained as a result of areal geochemical sampling, quality assessment and grading are also carried out. After that, according to the quantitative hydrocarbon composition of samples 13, the values of the probability of the presence of a deposit (oil and gas promising object) are determined in accordance with the fact that the reference quantitative hydrocarbon compositions of samples 10 obtained in zone 5 of the established presence of hydrocarbon inflows correspond to 100% of the probability of the presence of a deposit, and the reference quantitative hydrocarbon compositions the compositions of the samples 11 obtained in the zone 6 of the established absence of hydrocarbon inflow correspond to 0% probability of the presence of a deposit. The criterion for the similarity of the quantitative hydrocarbon composition of the samples obtained during the areal geochemical sampling, the reference quantitative hydrocarbon composition of the samples 10, obtained in the zone of the established presence of hydrocarbon inflow, was determined as the value of the probability of the presence of hydrocarbon deposits over 75%.

According to the obtained probability values, each hydrocarbon sample obtained in the territory 12 of reservoir prediction is attributed, according to the similarity criterion, to the place of predicted availability (with probability values of more than 75%) and to the place of predicted absence (with probability values less than 75%) of hydrocarbon inflow.

The obtained probability values are stored, on their basis and according to the geographic coordinates of hydrocarbon samples obtained as a result of the areal geochemical testing in the territory 12 of forecasting hydrocarbon deposits, a geochemical map for forecasting hydrocarbon deposits (oil and gas content of the forecast territory) is compiled. A predicted hydrocarbon reservoir map is shown in FIG. 2.

It is clear for a specialist that the determination of the quantitative compositions of hydrocarbons, the process of assigning them to the zones of predicted presence 5 or predicted absence 6 of hydrocarbon inflow and building, if necessary, a geochemical forecasting map requires statistical data processing, which consists, in particular, in the primary sorting of the analytical data array , in the assessment of background and anomalous amounts of hydrocarbons, the allocation of principal vectors (principal components) responsible for most of the variance of the selected values, using the principal component analysis, factor analysis, discriminant analysis, etc. This allows you to get rid of insignificant variables and reduce the variance of values.

). В таблице 2 указаны известные из публикаций стратиграфические интервалы значений ИСУ метана залежей севера Западной Сибири.Additionally, they can carry out sampling of soil during areal geochemical sampling, determination of the quantitative hydrocarbon composition of samples of hydrocarbon gases of composition C ₁ -C ₅ and determination of carbon and hydrogen of hydrocarbon gases of composition C ₁ -C ₅ . As a result, it was found that the geochemical sampling site is characterized by the presence of methane with a wide range of IMS (from -93.83 to

). Table 2 shows the stratigraphic intervals of the methane AIS values for deposits in the north of Western Siberia known from publications.

Of the total array of hydrocarbon gas samples, the isotopic composition of which was analytically determined, 9% by isotopic composition in accordance with Table 2 can be attributed to methane from the Paleozoic and deeper horizons, 3% from the Jurassic-Valanginian, 10% or more - mixtures of methane from pre-Senomanian rocks of different ages, 18% - from Cenomanian rocks. At the same time, determining the intervals in accordance with the characteristics of the MIS of gases of rocks and deposits, exclude from consideration a significant part of thermogenic methane, the MIS of which has changed due to a mixture with biogenic methane of modern sediments, due to the fact that such a dilution process cannot be taken into account quantitatively. Frequency distribution can be used to obtain qualitative information about the dilution process. As a result, a point or local-areal character of the distribution of thermogenic methane outputs was established according to the ISU of rocks of different ages similar to methane, starting from the Paleozoic rocks and deeper horizons of the section to the Cenomanian deposits. With an extremely tentative nature of the assessment, it is obvious that even such very approximate gradations can make it possible to predict the stratigraphic position of the predicted deposit. The use of these studies makes it possible to further increase the efficiency and accuracy of predicting the stratigraphic position and the dominant type of phase composition of the fluid of the hydrocarbon reservoir.

Thus, increasing the efficiency and accuracy of predicting the presence of hydrocarbon deposits, as well as reducing the time for analyzing the hydrocarbon composition of samples obtained during geochemical testing, and simplifying the taking of these samples when implementing the claimed method is provided due to a predetermined list of hydrocarbon compounds capable of migration from the subsoil to the surface, which in this case are part of the hydrocarbon fluid of the reservoir.

Claims (101)

1. A method for geochemical forecasting of hydrocarbon deposits, including: - determination of the list of hydrocarbon compounds capable of migration from a sample of hydrocarbon fluid from one of the deposits of the field; - determination, according to the list of hydrocarbon compounds capable of migration, of the reference quantitative hydrocarbon composition of the samples obtained during geochemical sampling in the zone of the established presence of hydrocarbon influx; - determination, according to the list of hydrocarbon compounds capable of migration, of the reference quantitative hydrocarbon composition of the samples obtained during geochemical testing in the zone of the established absence of hydrocarbon influx; obtaining hydrocarbon samples as a result of conducting areal geochemical testing in the territory of forecasting hydrocarbon deposits and determining the quantitative hydrocarbon composition of these samples from the list of hydrocarbon compounds capable of migration; - assignment of each hydrocarbon sample obtained on the territory of forecasting hydrocarbon deposits to the place of the predicted presence or absence of hydrocarbon inflow according to the criterion of similarity of the quantitative hydrocarbon composition of samples obtained as a result of areal geochemical sampling, to reference hydrocarbon compositions of samples obtained during geochemical sampling in the zones of the established presence and absence of hydrocarbon inflow. 2. The method for geochemical forecasting of hydrocarbon deposits according to claim 1, additionally including the compilation of a geochemical map for forecasting hydrocarbon deposits by geographic coordinates of hydrocarbon samples obtained as a result of areal geochemical testing in the territory of forecasting hydrocarbon deposits, indicating the locations of the predicted presence or absence of hydrocarbon deposits. 3. The method for geochemical forecasting of hydrocarbon deposits according to claim 1, in which the reference quantitative hydrocarbon composition of the sample obtained in the zone of the established presence of hydrocarbon inflow corresponds to 100% probability of the presence of hydrocarbon deposits. 4. The method of geochemical forecasting of hydrocarbon deposits according to claim 3, in which the criterion for the similarity of the quantitative hydrocarbon composition of the samples obtained in the forecast area to the reference quantitative hydrocarbon compositions of the samples obtained during geochemical testing in the zone of the established presence of hydrocarbon inflow corresponds to the values of the probability of the presence of the deposit hydrocarbons more than 75%. 5. The method of geochemical forecasting of hydrocarbon deposits according to claim 1, in which the definition of the list of hydrocarbon compounds capable of migration includes: - selection of at least one sample of hydrocarbon fluid from at least one well that has exposed one of the hydrocarbon deposits of the field; - holding at least one artificial sorbent over the hydrocarbon fluid sample; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons and determining the list of desorbed hydrocarbons; - selection from the list of desorbed hydrocarbons according to the criterion of migration ability to the surface of the list of hydrocarbon compounds capable of migration. 6. The method of geochemical forecasting of hydrocarbon deposits according to claim 5, in which the criterion of migration ability to the surface includes indicators: - thermogenic nature of hydrocarbon compounds; - content in the composition of hydrocarbon compounds of hydrogen and carbon; - stability of the hydrocarbon compound to oxidation in near-surface conditions; - reproducible identification of a hydrocarbon compound when the sorbent is held over a hydrocarbon fluid sample. 7. The method of geochemical forecasting of hydrocarbon deposits according to claim 1, in which the zone of the established presence of hydrocarbon inflow corresponds to an area within a radius of up to 100 meters from the productive well mouth. 8. The method of geochemical forecasting of hydrocarbon deposits according to claim 1, in which the zone of the established absence of hydrocarbon inflow corresponds to an area within a radius of up to 100 meters from the mouth of an unproductive well. 9. The method for geochemical forecasting of hydrocarbon deposits according to claim 1, in which the determination of the reference quantitative hydrocarbon composition of the sample obtained during geochemical testing in the zone of the established presence of hydrocarbon inflow includes: - drilling at least one borehole in the zone of the established presence of hydrocarbon inflow and fixing the geographic coordinates of their location; - placing in the borehole at least one artificial sorbent; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons; - determination of the reference quantitative hydrocarbon composition of the obtained sample of desorbed hydrocarbons according to the list of hydrocarbon compounds capable of migration. 10. The method for geochemical forecasting of hydrocarbon deposits according to claim 1, in which the determination of the quantitative reference hydrocarbon composition of the sample obtained during geochemical testing in the zone of the established absence of hydrocarbon inflow includes: - drilling at least one borehole in the zone of the established absence of hydrocarbon inflows and fixing the geographical coordinates of their location; - placing in the borehole at least one artificial sorbent; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons; - determination of the reference quantitative hydrocarbon composition of the obtained sample of desorbed hydrocarbons according to the list of hydrocarbon compounds capable of migration. 11. The method of geochemical forecasting of hydrocarbon deposits according to claim 1, in which conducting areal geochemical testing in the forecasting area includes: - drilling bore-holes in the territory of forecasting hydrocarbon deposits, placing at least one artificial sorbent in each bore-hole and fixing the geographical coordinates of their location; - holding artificial sorbents in boreholes for sorption of hydrocarbons on them; - obtaining, as a result of desorption from artificial sorbents, samples of desorbed hydrocarbons; - determination of the quantitative hydrocarbon composition of the desorbed hydrocarbon samples from the list of hydrocarbon compounds capable of migration. 12. The method of geochemical forecasting of hydrocarbon deposits according to claim 1, which additionally includes: - determination of the list of hydrocarbon compounds capable of migration from a sample of hydrocarbon fluid of the second reservoir of the field; - determination, according to the list of hydrocarbon compounds capable of migration, for the second deposit, the reference quantitative hydrocarbon composition of samples obtained during geochemical sampling in the zone of the established presence of hydrocarbon influx; - determination, according to the list of hydrocarbon compounds capable of migration, for the second deposit of the reference quantitative hydrocarbon composition of samples obtained during geochemical sampling in the zone of the established absence of hydrocarbon inflow; - determination, according to the list of hydrocarbon compounds capable of migration, for the second deposit of the quantitative hydrocarbon composition of the samples obtained as a result of areal geochemical sampling in the territory of forecasting hydrocarbon deposits; - assignment of each hydrocarbon sample obtained on the territory of forecasting hydrocarbon deposits to the place of the predicted presence or absence of hydrocarbon influx according to the criterion of similarity of the quantitative hydrocarbon composition of the samples obtained as a result of areal geochemical sampling, to the reference quantitative hydrocarbon compositions of the samples obtained during the geochemical sampling in the zones the established presence and absence of hydrocarbon inflow, while hydrocarbons are included in the list of hydrocarbon compounds capable of migration for the second reservoir. 13. The method of geochemical forecasting of hydrocarbon deposits according to claim 12, additionally including fixing the geographic coordinates of hydrocarbon samples obtained as a result of areal geochemical sampling in the forecast area, and drawing up a geochemical map for predicting hydrocarbon deposits by geographical coordinates indicating the places of the predicted presence or absence of the first deposit hydrocarbons and indicating the locations of the predicted presence or absence of the second hydrocarbon accumulation. 14. The method for geochemical forecasting of hydrocarbon deposits according to claim 12, in which determining the list of hydrocarbon compounds capable of migration of the second deposit of the field includes: - taking at least one sample of hydrocarbon fluid from at least one well that has exposed the second hydrocarbon reservoir of the field; - holding at least one artificial sorbent over the hydrocarbon fluid sample; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons and determining the list of desorbed hydrocarbons; - selection from the list of desorbed hydrocarbons according to the criterion of migration ability to the surface of the list of hydrocarbon compounds capable of migration. 15. The method of geochemical forecasting of hydrocarbon deposits according to claim 14, in which the criterion of the migration ability to the surface includes indicators: - thermogenic nature of hydrocarbon compounds; - content in the composition of hydrocarbon compounds of hydrogen and carbon; - stability of the hydrocarbon compound to oxidation in near-surface conditions; - reproducible identification of a hydrocarbon compound when the sorbent is held over a hydrocarbon fluid sample. 16. The method for geochemical forecasting of hydrocarbon deposits according to claim 12, in which the determination of the reference quantitative hydrocarbon composition of the sample obtained during geochemical testing in the zone of the established presence of hydrocarbon inflow includes: - drilling at least one borehole in the zone of presence of hydrocarbon inflow; - placing in each borehole at least one artificial sorbent; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons; - determination according to the list of hydrocarbon compounds capable of migration for the second reservoir of the reference quantitative hydrocarbon composition of the obtained sample of desorbed hydrocarbons. 17. The method for geochemical forecasting of hydrocarbon deposits according to claim 12, in which the determination of the quantitative reference hydrocarbon composition of the sample obtained during geochemical testing in the zone of the established absence of hydrocarbon inflow includes: - drilling at least one borehole in the zone of presence of hydrocarbon inflow; - placing in the borehole at least one artificial sorbent; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons; - determination of the second deposit of the reference quantitative hydrocarbon composition of the obtained sample of desorbed hydrocarbons according to the list of hydrocarbon compounds capable of migration. 18. Method for geochemical forecasting of hydrocarbon deposits, including: - obtaining from the database a list of hydrocarbon compounds capable of migration, determined from a sample of hydrocarbon fluid; - determination, according to the list of hydrocarbon compounds capable of migration, of the reference quantitative hydrocarbon composition of the samples obtained during geochemical sampling in the zone of the established presence of hydrocarbon influx; - determination, according to the list of hydrocarbon compounds capable of migration, of the reference quantitative hydrocarbon composition of the samples obtained during geochemical testing in the zone of the established absence of hydrocarbon influx; - Obtaining hydrocarbon samples as a result of areal geochemical testing in the territory of forecasting hydrocarbon deposits and determining the quantitative hydrocarbon composition of these samples from the list of hydrocarbon compounds capable of migration; - assignment of each hydrocarbon sample obtained on the territory of forecasting hydrocarbon deposits to the place of the predicted presence or absence of hydrocarbon inflow according to the criterion of similarity of the quantitative hydrocarbon composition of samples obtained as a result of areal geochemical sampling, to reference hydrocarbon compositions of samples obtained during geochemical sampling in the zones of the established presence and absence of hydrocarbon inflow. 19. The method of geochemical forecasting of hydrocarbon deposits according to claim 18, in which the database is formed during the following stages: - selection of at least one sample of hydrocarbon fluid from at least one well that has exposed one of the hydrocarbon deposits of the field; - holding at least one artificial sorbent over the hydrocarbon fluid sample; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons and determining the list of desorbed hydrocarbons; - selection from the list of desorbed hydrocarbons according to the criterion of migration ability to the surface of the list of hydrocarbon compounds capable of migration; - fixing the list of hydrocarbon compounds capable of migration in the database. 20. Method for geochemical forecasting of hydrocarbon deposits, including: - obtaining from the database a list of hydrocarbon compounds capable of migration, determined from a hydrocarbon fluid sample and determined from this list of reference quantitative hydrocarbon compositions of samples obtained during geochemical sampling in zones of established presence and absence of hydrocarbon influx; - Obtaining hydrocarbon samples as a result of areal geochemical testing in the territory of forecasting hydrocarbon deposits and determining the quantitative hydrocarbon composition of these samples from the list of hydrocarbon compounds capable of migration; - assignment of each hydrocarbon sample obtained on the territory of forecasting hydrocarbon deposits to the place of the predicted presence or absence of hydrocarbon inflow according to the criterion of similarity of the quantitative hydrocarbon composition of samples obtained as a result of areal geochemical sampling, to reference hydrocarbon compositions of samples obtained during geochemical sampling in the zones of the established presence and absence of hydrocarbon inflow. 21. The method of geochemical forecasting of hydrocarbon deposits according to claim 20, in which the database is formed when performing the following stages: - selection of at least one sample of hydrocarbon fluid from at least one well that has exposed one of the hydrocarbon deposits of the field; - holding at least one artificial sorbent over the hydrocarbon fluid sample; - obtaining, as a result of desorption from an artificial sorbent, a sample of desorbed hydrocarbons and determining the list of desorbed hydrocarbons; - selection from the list of desorbed hydrocarbons according to the criterion of migration ability to the surface of the list of hydrocarbon compounds capable of migration; - fixing the list of hydrocarbon compounds capable of migration in the database; - drilling at least one hole in the zone of the established presence of hydrocarbon inflow and at least one hole in the zone of the established absence of hydrocarbon inflow; - placing in each borehole at least one artificial sorbent; - obtaining, as a result of desorption from artificial sorbents, samples of desorbed hydrocarbons; - determination of the list of hydrocarbon compounds capable of migration, and recording in the database of the reference quantitative hydrocarbon composition of the sample of desorbed hydrocarbons obtained in the zone of the established presence of hydrocarbon inflow; - determination of the list of hydrocarbon compounds capable of migration and recording in the database of the reference quantitative hydrocarbon composition of the sample of desorbed hydrocarbons obtained in the zone of the established absence of hydrocarbon influx. 22. The method of geochemical forecasting of hydrocarbon deposits according to claim 18 or 20, additionally including the compilation of a geochemical map for forecasting hydrocarbon deposits by the geographic coordinates of hydrocarbon samples obtained as a result of areal geochemical testing in the territory of forecasting hydrocarbon deposits, indicating the places of the predicted presence or absence of the first deposit hydrocarbons and indicating the locations of the predicted presence or absence of the second hydrocarbon accumulation. 23. The method of geochemical forecasting of hydrocarbon deposits according to claim 18 or 20, in which the reference quantitative hydrocarbon composition of the sample obtained during geochemical testing in the zone of the established presence of hydrocarbon inflow corresponds to 100% probability of the presence of hydrocarbon deposits. 24. The method of geochemical forecasting of hydrocarbon deposits according to claim 23, in which the criterion of similarity of the quantitative hydrocarbon composition of the samples obtained in the forecast area to the reference quantitative hydrocarbon compositions of the samples obtained during geochemical testing in the zone of the established presence of hydrocarbon inflow corresponds to the values of the probability of the presence of hydrocarbon deposits more than 75%. 25. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 1, 5, 12, 14, 18-21, in which the list of hydrocarbon compounds capable of migration includes at least 200 hydrocarbon compounds. 26. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 9-11, 16, 17, 21, in which the borehole drilling depth is from 1.5 to 3 meters. 27. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 5, 9-11, 14, 16, 17, 19, 21, in which the determination of the composition of the desorbed hydrocarbons is carried out by the method of chromatography-mass spectroscopy. 28. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 1, 12, 18, 20, which additionally includes determining the values of methane-free coefficients when conducting areal geochemical testing in the forecast area and drawing up, based on these values, a map for predicting the dominant phase composition of the hydrocarbon fluid of a hydrocarbon pool. 29. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 1, 12, 18, 20, which additionally includes soil sampling during areal geochemical sampling, determination of the quantitative hydrocarbon composition of samples of hydrocarbon gases of composition C ₁ -C ₅ and determination of the isotopic composition of carbon and hydrogen of hydrocarbon gases of composition C ₁ -C ₅ . 30. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 1, 12, 18, 20, which additionally includes soil sampling during areal geochemical sampling, determination of the quantitative hydrocarbon composition of samples of hydrocarbon gases of composition C ₁ -C ₅ , determination of the values of methane-free coefficients and drawing up on the basis of these values a geochemical prediction map of the dominant phase composition hydrocarbon deposits. 31. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 1, 12, 18, 20, which additionally includes soil sampling during areal geochemical sampling, obtaining carbon dioxide, helium, oxygen as a result of degassing soil samples and determining the isotopic composition of carbon in the composition of carbon dioxide. 32. A method for geochemical forecasting of hydrocarbon deposits according to any one of paragraphs. 1, 12, 18, 20, which additionally includes soil sampling during areal geochemical sampling and obtaining, as a result of degassing soil samples, carbon dioxide, helium, oxygen and analysis of the organic matter content of soil samples obtained during areal geochemical sampling.

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