RU2636401C1 - Method of determining content of vanadium and rare-earth elements on gamma-activity of sedimentary rocks - Google Patents

Abstract

FIELD: chemistry.SUBSTANCE: sampling the core samples from wells, examining the samples by gamma-ray logging and determining the gamma activity of uranium from the core are carried out, the core samples being sampled from the samples with the highest gamma ray logging characteristics, which are then examined on a gamma spectrometer for residual activity in uranium and thorium, the ratio of the gamma activity of uranium and thorium f determines the type of rock, the type of rock determines the value of the correlation coefficient for uranium and rare-earth elements for the samplef, in accordance with the rock lithology, the correlation coefficients K(uranium-vanadium) andK(thorium - rare-earth elements) for this type of deposits, then the amount of ore component is determined, taking into account the intermittent and area distribution.EFFECT: increasing the reliability and speed of determining intervals of well sections with ore content of vanadium and rare-earth elements.3 cl, 2 dwg, 4 tbl

Description

The invention relates to geology, including exploratory geochemistry for oil, gas and ore minerals, and can be used in geological exploration for oil and gas to identify sections of sedimentary rocks enriched in vanadium and / or rare earth elements (TR), according to gamma-ray logging of rock samples (core, sludge) and the results of measurements of gamma activity of thorium and uranium on a gamma spectrometer. The proposed method allows you to highlight new promising objects of ore components in dominicites, which, when they are shallow, provides the feasibility of integrated development of mineral raw materials (hydrocarbons and ore components).

In traditional petroleum geology, insufficient attention has been paid to the study of domanicoid formations as sources of associated oil components for a number of important strategic elements (vanadium, rare-earth elements) due to the fact that they were considered only as strata generating and accumulating hydrocarbons (HC). At the same time, domanic deposits are an oil prospecting object with associated components, for example, such as vanadium, since the latter is closely associated with organic matter, forming vanadylporphyrins. For rocks enriched with organic matter, a direct correlation is established with the uranium content, values of the correlation coefficient of the uranium and vanadium content are established, which allows the response on gamma-ray logs to trace levels with a high content of uranium and, accordingly, vanadium. Therefore, domanicoid deposits become a very relevant object for obtaining not only hydrocarbons, but also associated components in them.

The response on the gamma-ray log may also be due to the presence of radioactive thorium and potassium. Laboratory investigation of sludge on a gamma spectrometer with a highly sensitive germanium detector allows us to diagnose spectral peaks from uranium and thorium. The thorium content is not associated with the presence of organic matter and correlates with the mineral component of the rock, namely with its terrigenous component. An analysis of the data obtained by the ICP SM method and the neutron activation method in sedimentary rocks of various genesis from depressed deep-water facies (with domanicites) to relatively shallow terrigenous rocks revealed a direct correlation between the content of thorium (Th) and rare-earth elements (TR) ( the correlation coefficient between Th and TR) is determined. This allows, based on the analysis of gamma activity of rocks from the increased content of uranium and thorium, to identify sedimentary intervals in the sedimentary stratum with oreogenic and ore concentrations of vanadium and rare earth elements.

The main task that must be solved at the stage of rapid assessment of sediments is to directly determine the intervals of sedimentary rocks enriched in vanadium and / or thorium, and to trace them by area based on the analysis of the characteristics of gamma activity of sedimentary rocks.

The values of gamma activity, determined by radioactive logging, represent the total response of the uranium content in the rock and in the organic matter, in addition, clay rocks containing radioactive thorium and potassium contribute to the total gamma activity of the radioactive logging. Organic matter accumulates in marine carbonate and siliceous rocks of domanicites; the correlation of the content of uranium and organic matter is most clearly traced in them, especially where the content of clay particles and thorium is minimal. The correlation coefficient in dominicites is more than 0.67 [1].

As a result of the experiments, a direct relationship was established between the content:

- thorium and rare earth elements,

- uranium and vanadium,

and correlation coefficients were calculated for rocks of different genesis and type.

Taking into account the nature of the change in the gamma activity of uranium and thorium in the rock, determined by the laboratory method on a gamma spectrometer, and the ratio with the value of gamma activity from logging, it becomes possible to isolate and track both within the domanic deposits and terrigenous rocks of the cut intervals with ore-bearing concentrations of vanadium and rare earths. In terrigenous clay rocks, on the contrary, the content of organic matter is minimal and, therefore, the amount of uranium and vanadium bound to it is minimal. In such rocks with a low content of uranium and organic matter, the correlation coefficient of uranium and vanadium is very small, less than 0.5, whereas the correlation coefficient of thorium and rare-earth elements is much higher (k _ThTr 0.91 to 0.98).

The correlation coefficients of thorium and rare-earth elements, uranium and vanadium for rocks of different genesis and composition were calculated from experimental data for sedimentary Paleozoic rocks of the Timan-Pechora oil and gas province in 6 wells of the Pechora-Kolvinsky aulacogen and Ukhta-Izhemsky shaft.

Control samples for the content of elements were analyzed at the Central Analytical Laboratory of VSEGEI using inductively coupled plasma mass spectrometry (ICP MS).

There are different methods for determining the content of vanadium and rare earth elements in rocks.

The most famous methods in which the exact concentrations of TR, V are determined are:

- method of mass spectrometry with inductively coupled plasma (VSEGEI method),

- neutron activation method.

The disadvantages of these methods include the complexity and duration of laboratory tests, as well as high labor costs, because for such studies are required:

a) special sample preparation with preliminary chemical decomposition of the samples, their translation into the solution and the allocation of the studied elements;

b) complex equipment (nuclear reactor) for special purposes and the subsequent disposal of the resulting radioactive waste.

This imposes significant restrictions on research in areal works.

One of the main methods for quantitative chemical analysis of mineral raw materials is x-ray fluorescence analysis (XRF) [2]. The method allows you to analyze solid-phase samples without chemical opening and to determine almost all the elements of the periodic system. This method has drawbacks in determining the content of vanadium and rare-earth elements, since its implementation is complicated by very strong matrix effects: the main analytical parameter - the intensity of x-ray fluorescence nА - depends not only on the content of the determined element of SA, but also on the elemental composition of the matrix and the heterogeneity of the sample . When determining ore and scattered elements, to eliminate the influence of matrix effects, the most rational method of scattered radiation (standard-background) is used, in which the ratio of the x-ray fluorescence intensity of the determined element pA to the intensity of the scattered primary radiation sample nS is used as an analytical parameter.

However, difficulties arise when determining vanadium: in vanadium, the analytical VKα line (λ = 2.505 A) is separated from the internal standard (RhKα line) by the absorption edges of iron and uranium; these elements appear in the equation (the ratio of vanadium intensity to intensity nS) as interfering . Rare earth elements at low concentrations are outside the detection range of this method. In this regard, this method cannot be used to determine the content of vanadium, as well as the entire range of rare earth elements, in the presence of uranium and iron in the rock.

In [2], an attempt was made to improve the method of X-ray fluorescence determination of Hf, Ta, Th, U in soils and use all varieties of the X-ray fluorescence method (including X-ray radiometric) to study rare heavy d-metals (Zr, Nb, Hf, Ta), lanthanides ( Y, La, Ce, Pr, Nd, Sm) and actinides (Th, U) in soils. The use of several methodological approaches by the authors made it possible to determine the content of 12 rare heavy metals (Zr, Nb, Hf, Ta, Y, La, Ce, Pr, Nd, Sm, Th, U), as well as 15 macroelements and major heavy metals in soils. The proposed method [2] has also negative aspects, since it is rather laborious and requires the use of different approaches, which does not allow for rapid express research.

Despite the simultaneous presence of uranium and thorium in soils in the zone of development of a strong geochemical anomaly with rare earth elements, in the analysis of the materials mentioned by the authors in [2], no correlation between uranium and rare earth elements is observed.

As a result of the analysis of the original data obtained in the study of exposures and deep-lying Paleozoic rocks (0-3250 m), we established a direct correlation between thorium and rare-earth elements (Table 1 and Fig. 1), we observed a positive correlation between the uranium and vanadium content ( table 1 and Fig. 2), indicators of the ratio of the residual activity of uranium and thorium in the study of a specific sample f _i (tables 2, 3) and indicator f, the values of which are determined for different types of rocks, are introduced; for the latter, the values of the correlation coefficient are established (table 4).

This made it possible to develop an effective express method for detecting rare-earth elements and vanadium in sedimentary rocks when examining them for oil and gas in order to isolate associated industrially significant ore components.

As a prototype for the proposed method, the “Method for determining the zones of hydrocarbon generation domanicoid and shale deposits in sections of deep wells”, protected by RF patent No. 2541721, publ. 01/15/2015 g.

The method according to patent No. 2541721 consists in taking core samples from wells, extracting insoluble organic matter NOV from samples, examining samples using gamma-ray logging and optical microscopy, while the selected core samples determine the gamma activity of uranium from the core, then, the values of the indicator r are determined by the ratio of the values of gamma-ray logging activity to the gamma-ray activity of uranium by core, by these values the type of deposits differing in the content of organic carbon is established (Corp ) for domanicoids, domanicites and shales, core samples are taken from the intervals with the highest values of gamma-ray logging for further research, insoluble organic matter (NOV) is extracted from the selected samples, the uranium content is determined in it, the correlation coefficient k _i between the NOV radioactivity is calculated and the value of the gamma-ray logging activity, compare it with the values of k of the corresponding type of deposits and determine the promising zone of hydrocarbon generation, then in the selected samples of the NOV carry out an assessment of elosti organic matter on katagenesis gradation level by microscopy and IR spectroscopy and organic matter according to maturity detect promising areas hydrocarbon generation.

Thus, the express method was proposed for the objective allocation of the oil generation zone of the carbon-containing stratum and the establishment of its power over the area of the work area. The method is based on a comprehensive interpretation of gamma-ray and optical characteristics of rocks. A reliable interpretation of the gamma activity of rocks by radioactive logging does not require the use of expensive additional equipment when drilling wells, such as spectral gamma-ray logging. The method of sample preparation for various types of analysis does not require expensive chemicals and can reliably quantify the catagenesis of marine rocks at the level of gradation of catagenesis.

The disadvantage of the proposed method is the limitation of its use for assessing the content of associated ore components by correlating the uranium content with organic matter in domanicites and in other types of rocks that are not related to source rocks.

The technical result of the proposed method is to increase the reliability and expressness of determining the intervals of sections of wells with an ore content of vanadium and rare earth elements and their tracking over the area when drilling wells for oil and gas and the search for ore components.

To achieve the claimed technical result in the method for determining the content of vanadium and rare-earth elements from the gamma activity of sedimentary rocks of deep wells, including core sampling from wells, sampling by gamma-ray logging and determination of gamma activity of uranium from the core, a change in the research methodology of the selected samples Core samples with the highest values of gamma-ray characteristics, which are then examined on a gamma-ray spectrometer for residual activity in uranium and thorium, are taken from the studied samples. The ratio of these values determines f _i for the sample (tables 2, 3). By comparing f _i with the ratio of the gamma activity of uranium and thorium “f” (table 1), the lithotype of the rock is determined. In accordance with the lithotype of the rocks, the correlation coefficients (table 4) K _uv (uranium - vanadium, Fig. 2) and K _ThTr (thorium - rare-earth elements, Fig. 1) are selected and the element content for this type of deposits is determined with the values of f _i (table 2 and 3). Next, determine the amount of ore component, taking into account the interval and area distribution.

The total quantity Q of the ore component in the lithotype with a characteristic average statistical density (ρ) is calculated by the formula

- for vanadium Q v = C _v ⋅ρhS

- for rare earth elements Q _TR = C _TR hS,

where ρ is the density of rocks of a given lithotype (determined by reference tables), h is the thickness of the layer, S is the distribution area of the layer, traced along the sections.

The content of uranium ²³⁸ U and thorium ²³² Th in the rock is determined by calculation using the residual activity of the corresponding isotope A, (Bq), using data on the atomic mass of the element.

The proposed method allowed the use of the simplest and safest method for the study of core samples, which, in addition, provides rapid measurements in the field with high reliability for a wider type of rock.

The essence of the proposed method

The content of vanadium and rare-earth elements is determined based on the direct correlation of these elements with the content of uranium and thorium, respectively, and the type of rock is determined by the ratio of the gamma activity of uranium and thorium f. For the rock type, the value of the correlation coefficient is determined in accordance with the established data according to the results of experimental studies (see table 1, tables 2 and 3), the content of vanadium and rare-earth elements is determined according to the corresponding dependence graph (see Fig. 1. Fig. 2).

It is known that the U content correlates with organic matter in deposits of the Domanica deposits of the Timan-Pechora oil and gas field [1]. In turn, it was proved that the vanadium content correlates with organic matter and uranium [3].

Uranium-vanadium deposits in sandstones, conglomerates, carbon-siliceous schists in the reduction zones are characterized by oxides and hydroxides (montroseite, dattonite, etc.), as well as vanadium and vanadium-containing minerals of the mica group, sulfides (sulvanite, patronite); in the oxidation zones - minerals V + 5, less often - V + 4 (oxides, complex oxides such as vanadium bronzes, simple and polymerized vanadates). In deposits of asphaltites, bitumen, and oils, patronite V0 ² + minerals (minasragrite and its polymorphs, syncositis), as well as organometallic compounds and vanadyl porphyrins are developed. Moreover, in carbonate rocks, the correlation of organic matter is traced with authigenic uranium directly related to organic matter, the content of which is determined by the formula [4]:

Thus, according to published data, a direct correlation between the content of uranium and vanadium is proved in different types of rocks. Moreover, the vanadium content in vanadyl porphyrins of organic matter in carbonate rocks also correlates with authigenic uranium. The correlation coefficient between uranium and vanadium is determined on the basis of experimental data on the content of elements depending on the lithotypes of the rocks (Table 4 and Figs. 1, 2).

The most important remains to identify the correlation between thorium and rare earth elements. Such a correlation was established from experimental data for Paleozoic sediments (see Fig. 1).

It is also known that lanthanides (Y, La, Ce, Pr, Nd, Sm) form strong complexes with organic ligands, which contributes to their leaching from soils [2]. This suggests the presence of a weak correlation between organic matter and thorium. As a result of the work [2], it was found that in the region of weak geochemical anomaly (near Lovozero), all lanthanides are inherited from the loparite-containing rock, and only Th from actinides: their content is 1.3-5.4 times higher than the clarke value for the earth's crust. In the zone of strong geochemical anomaly (on the northern shore of Seydozer and on the bank of the Elmorayok river), the concentration of lanthanides and actinides is even higher: it is 4–9 times higher than the clark value. The following formula is determined on the territory of a strong geochemical anomaly: + (Hf, Zr, Ta, Nb, Th, U, La, Ce, Y, Pr, Mn, Nd, Zn, Sm, S, Sr, Ga) / - (Cu, Mg, Cr, Ca, Ni). Thus, thorium and uranium may be present in the rock's mineral matrix, so it is important to determine whether there is a correlation between the uranium and thorium content.

For this, in accordance with the data of A.I. Perelman and N.S. Kasimova [5] analyzed the paragenetic associations of elements V and TR for each type of groundwater deposited on geochemical barriers.

As a result, the paragenesis of V and TR is traced only for oxygen waters (differing in pH), and the deposition of elements occurs at different geochemical barriers:

- TR in the composition of strongly acidic waters is deposited on alkaline geochemical barriers (D1),

- V in the composition of strongly acidic - slightly weakly acidic waters is deposited on sorption barriers (G1, G2).

This fact indicates the absence or very weak correlation between the content of uranium and thorium.

According to our experimental data, such a correlation can be traced only at low contents of uranium and thorium, which determine both the low contents of vanadium and rare earth elements, which is controlled by the index f - the ratio of uranium activity to thorium, determined in the range of values from 3-6 (Table 1) . With this ratio of the activities of the rock elements, they do not contain significant amounts of associated ore components. The index f quantitatively varies in the range from 0.01 to the first tens from terrigenous rocks (sandstones, sand-clay and silty differences) to deep-sea marine siliceous-clay-carbonate and carbonate-clay (domanicoid) rocks. Tables 2 and 3 give examples of the determination of f _i taking into account data on the activity of uranium and thorium candy lithotypes - mudstones and dominicites - clay-siliceous-carbonate rocks.

Thus, the gamma spectrometric method is most optimal for measuring the residual activity of thorium and uranium, as the least environmentally friendly compared to the neutron activation method (requires a reactor and irradiation) and the least labor-intensive compared to the ICP method and X-ray fluorescence analysis (XRF) a method for which preliminary complex sample preparation and the use of various complex calculation methods (XRF) are required, as well as certain element contents corresponding to the region Sensitivity techniques.

The method is as follows.

Core samples are taken from the wells taking into account the highest values according to the gamma-ray logging characteristic for the well section. In the selected core samples, the residual gamma activity of uranium and thorium is determined from the core on a gamma spectrometer. Then, the ratio of the values of the gamma activity of uranium and thorium is determined from the results of a core study and the values of the index f _i are obtained (examples of tables 2 and 3). The results are compared with the tabulated values of f established for different lithotypes (see table 1), based on the study of Paleozoic deposits by the gamma spectroscopic method. The index f quantitatively varies in the range from 0.01 to the first tens from terrigenous rocks (sandstones, sand-clay and silty differences) to deep-sea marine siliceous-clay-carbonate and carbonate-clay (domanicoid) rocks. The ratio of indices f and f _i determine the lithotype of the rocks. In accordance with the lithotype of the rocks and the calculated data given in Table 4, the correlation coefficients K _uv (uranium - vanadium), K _ThTr (thorium - rare earth elements) for this type of deposits are selected. The values of the correlation coefficient of elements are determined in the program "Microcal Origin".

Based on correlation graphs (Figs. 1 and 2), the correlation coefficients K _ThTr (thorium - rare earth elements) K _uv (uranium - vanadium) for the corresponding type of deposits determine the content of vanadium and / or rare earth elements (C _v , C _TR ).

Such studies are carried out for different types of sediment in the context. Then select the intervals with the highest values of the content of elements (close to ore concentrations), determined by core. According to gamma-ray logging, section intervals with ore-bearing contents of vanadium and / or rare-earth elements are traced along the well section. Then, sections are correlated over the selected intervals, taking into account the power (h) and the distribution over the area (S), which are established by the GIS.

The total quantity Q of the ore component in the lithotype with a characteristic average statistical density (ρ) is calculated by the formula

- for vanadium Q v = C _v ⋅ρhS (2)

- for rare earth elements Q _TR = С _TR hS (3),

where ρ is the density of rocks of a given lithotype, determined by reference tables, h is the thickness of the layer, S is the distribution area of the layer, traced along the sections.

The content of residual activity of isotopes of uranium and thorium (Bq) in the rock is determined by gamma spectrometric analysis.

The activity of the samples was measured on a spectrometer with a semiconductor detector (HPGe) with a sensitive volume of 56 cm ³ and with a resolution of 2 keV on the 60 Co line.

The gamma-ray spectra were processed using the MICROSOFT standard SYSTEM-100 program.

The basis for the implementation of the method is the experimental data obtained for 30 samples of the Timan-Pechora oil and gas province and the Leningrad region, studied in the stratigraphic range from Ordovician to Upper Devonian for 6 wells and two outcrops.

Thus, the proposed method for determining the content of vanadium and rare-earth elements in ore-bearing concentrations in domanicoids and rocks of a different genesis based on a combination of gamma-ray data and characteristics of the residual activity of uranium and thorium can increase the speed, detail and reliability of identifying section intervals in sedimentary rocks and to trace the identified intervals by area, which is important for assessing the associated components of practical importance.

LITERATURE

1. The method of determining the zones of hydrocarbon generation domanicoid and shale deposits in sections of deep wells. RF patent No. 2541721 O.M. Prishchepa, A.A. Sukhanov, Valiev F.F., Sergeev V.O., Makarova I.R. registered in the State Register of Inventions of the Russian Federation on 15.01. 2015.

2. Vodyanitsky Yu.N., Savichev A.T. Possibilities of using the X-ray fluorescence method in the study of rare heavy metals in soils. Agrophysics. 2011, No. 2. - 3-12 s.

3. Karpenko V.Yu. Vanadium mineralization associated with carbon-siliceous schists of South Fergana / Abstract of dissertation for the degree of candidate of geological and mineralogical sciences. M., 2010 .-- 24 p.

4. Geochemical features of limestone and sedimentation conditions on an isolated carbonate platform in the Late Devonian and early Carboniferous on the eastern outskirts of the Urals / G.A. Miesens, T.I. Stepanova, N.A. Kucheva, S.A. Sapurin // Lithosphere, 2014, No. 6, p. 53-76.

5. Perelman A.I., Kasimov N.S. Geochemistry of the landscape.- M .: Astrea - 2000.1999 .-- 763 p.

Claims (6)

1. The method of determining the content of vanadium and rare earth elements from the gamma activity of sedimentary rocks of deep wells, including the selection of core samples from wells, the study of samples by gamma-ray logging and determination of gamma activity of uranium from the core, characterized in that samples are taken from the studied samples core with the highest gamma-ray characteristics, which are then examined on a gamma-ray spectrometer for residual activity of uranium and thorium, by the value of the ratio of gamma activity of uranium and thorium f determined divide the rock type, determine the value of the correlation coefficient for uranium and rare-earth elements for the sample f _i according to the rock type, in accordance with the lithotype of the rocks, select the correlation coefficients K _uv (uranium-vanadium) and K _ThTr (thorium - rare-earth elements) for this type of deposits, then determine the amount of ore component taking into account the interval and area distribution. 2. The method according to p. 1, characterized in that the total quantity Q of the ore component in the lithotype with a characteristic average statistical density (ρ) is calculated by the formula - for vanadium Qv = C _v ⋅ρhS - for rare earth elements Q _TR = C _TR hS, where ρ is the density of rocks of a given lithotype (determined by reference tables), h is the thickness of the layer, S is the distribution area of the layer, traced along the sections. 3. The method according to p. 1, characterized in that the content of uranium ²³⁸ U and thorium ²³² Th in the rock is determined by the residual activity of the isotope A, (Bq), determined according to gamma-spectrometric analysis, by a calculation method using atomic mass data.

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