Научная статья на тему 'Geophysical criteria for the separation of productive micaceous veins of the Mariinsky emerald-beryllium deposit (the Middle Urals)'

Geophysical criteria for the separation of productive micaceous veins of the Mariinsky emerald-beryllium deposit (the Middle Urals) Текст научной статьи по специальности «Науки о Земле и смежные экологические науки»

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Ключевые слова
The Urals / magnetic susceptibility / electrical resistance / glimmerites / quartz-plagioclase veins / emerald-beryllium deposits / Ural emerald mines / Урал / магнитная восприимчивость / электросопротивление / слюдиты / кварц-плагиоклазовые жилы / изумрудно-бериллиевые месторождения / Уральские изумрудные копи

Аннотация научной статьи по наукам о Земле и смежным экологическим наукам, автор научной работы — Mikhail Petrovich Popov, Oleg Petrovich Peleshko, Evgeniya Anatol’evna Bazhenova, Viktor Sergeevich Ivanchenko, Viktor Sergeevich Ivanchenko4, ****, Vladimir Vasil’evich Bakhterev

Relevance of the work is the development of new methods for rapid extraction (determination) of ore bodies in the underground mine of the field directly. Measurements were carried out both on specially prepared samples in the form of cubes of the same size, and under conditions of natural occurrence. Purpose of the work is to study the magnetic susceptibility and electrical resistivity of the main host rocks and the ore complex (emerald-bearing glimmerites and quartz-plagioclase veins with beryl) in the most famous Ural emerald-beryllium deposit, the Mariinsky deposit. Methodology of research. In order to study the magnetic properties of typical rocks and ore bodies of the Mariinsky deposit, the PIMV-M field magnetic susceptibility meter with a measurement range of 1 · 10–5… 1 SI units was used in the underground mine directly. The relative measurement error does not exceed ± 10% in the range of 10–4 ... 1 SI units. The measurement was carried out by applying the flat surface of the measuring transducer to the bottomhole wall in a lithologically homogeneous section with subsequent measurement and recording of the obtained value in the field document. To study the electrical resistivity, standard samples in the form of cubes of 24 × 24 × 24 mm were used; their composition was investigated with the help of binocular enhancer MBS-10. The measurements were carried out along three axes since almost all samples have anisotropy. The teraohmmeter E6-13A was used for working. Results. The data on the magnetic susceptibility and electrical resistance of the main host rocks and the ore complex (emerald-bearing glimmerites and quartz-plagioclase veins with beryl) from the Mariinsky deposit are presented. All data are adjusted with the petrographic characteristics of rocks. Conclusions. Possibility in principle is shown for creating a new express-method for isolating quick micaceous veins in wells and mine faces with the simultaneous measurement of magnetic susceptibility and electrical resistance of rocks during mining operations in an underground mine.

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Геофизические критерии выделения продуктивных слюдитовых жил Мариинского изумрудно-бериллиевого месторождения (Средний Урал)

Àêòóàëüíîñòüþ работы является разработка новых методов оперативного выделения (обнаружения) рудных тел непосредственно в подземном руднике месторождения. Измерения были проведены как на специально подготовленных образцах в форме кубиков одного размера, так и в условиях естественного залегания. Öåëüþ ðàáîòû является изучение магнитной восприимчивости и электросопротивления основных вмеùаюùих пород и рудного комплекса (изумрудоносных слюдитов и кварц-плагиоклазовых жил с бериллом) на самом известном уральском изумрудно-бериллиевом месторождении – Мариинском. Ìåòîäîëîãèÿ èññëåäîâàíèÿ: для исследований магнитных свойств типовых пород и рудных тел Мариинского месторождения непосредственно в подземном руднике использовался измеритель магнитной восприимчивости полевой ПИМВ-М с диапазоном измерения 1 · 10–5…1 ед. СИ. Относительная погрешность измерения не превосходит ±10 % в диапазоне 10–4…1 ед. СИ. Измерение проводилось путем плотного прикладывания плоской поверхности первичного преобразователя прибора к стенке забоя в литологически однородный участок с последуюùим измерением и записью полученного значения в полевой журнал документации горных выработок. Для изучения электросопротивления были использованы стандартные образцы в форме кубиков размером 24 × 24 × 24 мм, состав которых параллельно изучался под бинолупой МБС-10. Измерения проводились по трем осям, так как практически у всех образцов присутствует анизотропия. Для работы использовался тераомметр Е6-13А. Ðåçóëüòàòû. Приведены данные по магнитной восприимчивости и электросопротивлению основных вмеùаюùих пород и рудного комплекса (изумрудоносных слюдитов и кварц-плагиоклазовых жил с бериллом) с Мариинского месторождения. Все данные согласованы с петрографическими характеристиками пород. Âûâîäû. Показана принципиальная возможность создания новой экспресс-методики выделения продуктивных слюдитовых жил в скважинах и забоях по одновременному измерению магнитной восприимчивости и электросопротивления пород непосредственно в процессе добычных работ в подземном руднике.

Текст научной работы на тему «Geophysical criteria for the separation of productive micaceous veins of the Mariinsky emerald-beryllium deposit (the Middle Urals)»

Известия Уральского государственного горного университета. 2019. Вып. 1(53). С. 39-47 УДК 550.832.9 https://doi.org/10.21440/2307-2091-2019-1-39-47

Geophysical criteria for the separation of productive micaceous veins of the Mariinsky emerald-beryllium deposit (the Middle Urals)

Mikhail Petrovich POPOV1- 2*, Oleg Petrovich PELESHKO3- **, Evgeniya Anatol'evna BAZHENOVA4- ***, Viktor Sergeevich IVANCHENKO4- ****, Vladimir Vasil'evich BAKHTEREV4- *****

1Ural State Mining University, Ekaterinburg, Russia

2Zavaritsky Institute of Geology and Geochemistry of the Ural Branch of RAS, Ekaterinburg, Russia

3AO Mariinsky rudnik, Asbest, Malysheva, Russia

"Institute of Geophysics of the Ural Branch of RAS, Ekaterinburg, Russia

Relevance of the work is the development of new methods for rapid extraction (determination) of ore bodies in the underground mine of the field directly. Measurements were carried out both on specially prepared samples in the form of cubes of the same size, and under conditions of natural occurrence. Purpose of the work is to study the magnetic susceptibility and electrical resistivity of the main host rocks and the ore complex (emerald-bearing glimmerites and quartz-plagioclase veins with beryl) in the most famous Ural emerald-beryllium deposit, the Mariinsky deposit. Methodology of research. In order to study the magnetic properties of typical rocks and ore bodies of the Mariinsky deposit, the PIMV-M field magnetic susceptibility meter with a measurement range of 1 • 10-5... 1 SI units was used in the underground mine directly. The relative measurement error does not exceed ± 10% in the range of 10-4 ... 1 SI units. The measurement was carried out by applying the flat surface of the measuring transducer to the bottomhole wall in a lithologically homogeneous section with subsequent measurement and recording of the obtained value in the field document. To study the electrical resistivity, standard samples in the form of cubes of 24 x 24 x 24 mm were used; their composition was investigated with the help of binocular enhancer MBS-10. The measurements were carried out along three axes since almost all samples have anisotropy. The teraohmmeter E6-13A was used for working.

Results. The data on the magnetic susceptibility and electrical resistance of the main host rocks and the ore complex (emerald-bearing glimmerites and quartz-plagioclase veins with beryl) from the Mariinsky deposit are presented. All data are adjusted with the petrographic characteristics of rocks. Conclusions. Possibility in principle is shown for creating a new express-method for isolating quick micaceous veins in wells and mine faces with the simultaneous measurement of magnetic susceptibility and electrical resistance of rocks during mining operations in an underground mine.

Keywords: The Urals, magnetic susceptibility, electrical resistance, glimmerites, quartz-plagioclase veins, emerald-beryllium deposits, Ural emerald mines.

Introduction

Currently, the Government of Russia entrusts executives of the Malyshevsky (Mariinsky) emerald-beryllium deposit with the task to restore beryllium mining in Russia. During mining operations, a very important factor affecting the cost and quantity of the extracted commercial element is the possibility of isolating and sorting out quick micaceous veins carried out directly in the mine face while blasthole drilling. Earlier during the active mode of operation of the Malyshevsky mine group (1950-1990), the enterprise used the photoneutron method for such tasks [1]. The application of this method is associated with certain managerial difficulties (the use of strong radiation sources, the creation of isotopes storages, and the organization of a special control service). Therefore, at the early stage of geological exploration, geophysical methods are promising, operational, and low-cost methods of searching for quick micacious veins and serpentinite contacts [2-4].

According to early literature data [2], the magnetic susceptibility of highly basic rocks of the Emerald-bearing line of the Urals ranges from 25 ... 63 ■ 10-5 to 2520... 5040 ■ 10-5 SI units, and in some cases up to 12 600 ■ 10-5 SI units. The increased magnetic properties of ultrabasic rocks are associated with accessory magnetite. Moreover, a considerable heterogeneity of ultrabasic rocks was established according to the magnitude of magnetic susceptibility (Table 1), which is mainly due to their serpentini-zation, carbonatization, and development of talc. Table 1 shows the magnetic susceptibility values obtained by the authors of the work [2] for rocks typical of the deposit. Unfortunately, the authors did not indicate in their work the way the measurements were made (using samples or under conditions of natural occurrence). However, according to their data, rocks of the basic and acidic composition are mainly non-magnetic; amphibolites, gabbros, granitic rock, and glimmerites are distinguished by reduced magnetic susceptibility.

Additionally, according to literature data [2], the dependence of the specific electrical resistance of ultrabasites on the meta-morphism intensity is noted:

- slightly serpentized peridotites - 1210 ... 3900 Ohm ■ m, at an average 1900 Ohm • m;

- serpentinites - 300-960 Ohm ■ m, at an average 750 Ohm • m;

- serpentinite-talc-carbonate rocks - 16 ... 21 Ohm ■ m, at an average 18 Ohm • m;

- talc-carbonate rocks - 2 ... 26 Ohm ■ m, at an average 10 Ohm • m.

" ED [email protected]

http://orcid.org/0000-0002-0527-8234

** [email protected] """ [email protected]

https://orcid.org/0000-0002-2068-7140 *"*[email protected]

http://orcid.org/0000-0002-1294-6050 [email protected]

http://orcid.org/0000-0002-1174-1301

Table 1. Characteristics of magnetic susceptibility X of rocks of the Ural emerald mines [2].

Таблица 1. Характеристика магнитной восприимчивости X горных пород Уральской изумрудоносной полосы [2].

Rock X • 10-5 SI units

Number of determinations Measurements range Average

Amphibolites 3646 0...302 25

Gabbro 800 0...126 35

Diorites 3370 0.2520 21.370

Granitic rock 2375 0.630 10

Serpentinites 1226 6.10 000 1612

Dolerines 555 6.3126 831

Chlorite rocks 135 6.1612 227

Apoultrabasite glimmerites 324 9.40 18.21

Apodiorite glimmerites 120 12.50 23.30

Micaceous veins are distinguished among the host rocks by high electrical resistance, which is caused by their composition - these are shales, consisting mainly of phlogopite with mica scales oriented along shaliness. According to the data of parametric measurements of samples, the average electrical resistivity is 70 000 Ohm ■ m, which is significantly higher than the electrical resistance of the host rocks [2]. However, the measurement technique is also not specified in the work.

The brief geological structure of the Mariinsky emerald-beryllium deposit

The Ural emerald mines are the world-famous ore region, where the largest deposits of beryllium ores and gems are located in Russia: emerald, alexandrite, and phenakite. Gem-stones mining began in 1831 and do not stop until today. Within the Emerald Mines, the only source of beryl is micaceous veins, which are found in the contact of serpentinites in talc-chlorite rocks.

The Mariinskoe (Malyshevskoye) deposit is included in a group of fields that goes under the general name of the Emerald Mines of the Urals. The ore field is attributed to the deposit which is located in the eastern exocontact zone of the large Aduisky granite massif of the late orogenic type. Granites burst a complex of metamorphic and intrusive rocks, which includes: amphi-bolites and amphibolite schists, carbon-bearing siliceous schists, serpentinized ultrabasites, serpentinites and dolerines derived from them, diorites, quartz diorites and diorite porphyry (Fig. 1).

The contact of the granite massif with a complex of metamorphic and intrusive rocks has the east dip with 65 ... 80 ° angle and is complicated by bends with flat areas and broad warps. The Mariinskoe deposit is confined to one of such downwarps. The ore field is localized in the eastern flank of the anticlinal bend. The main ore-controlling and ore-distributing structures at the deposit are spatially connected fault zones and dikes of diorite porphyrites [6]. Fault zones are fixed by highly foliated and broken dolerines (usually with additions of chlorite, actinolite, and phlogopite); there are lenticular bodies of serpentinites, as well as dikes of diorite porphyrites and separate sheet-like bodies of carbonaceous silicious schists. Most ore bodies are concentrated in the fault zones oriented mainly in the near north-south and lateral directions. In the fault zones and adjacent areas, all rocks are subject to tectonical boudinage and profound metasomatic changes — phlogopitization, fluoritization, and development of talc (serpentinites). In addition, the most intensive formation of beryllium mineralization is observed in fault zones. In the vertical sections, schistosity zones often unite and diverge again; wedging out and bulges are often noted. It was also noted that sometimes separate feathering fractures depart from the main fault zones; large ore shoots are formed in the areas of intersection with faults. Fault zones can be tracked along the strike up to 1200 m, their thickness varies from 5 to 70 m. Dykes of diorite porphyry play an important role in the formation of the structure of the ore field of the deposit. Along the strike and the fall of the ore zone, five largest dykes are observed in accordance with it, the length of which reaches 1150 m with a thickness of 5 to 10 m. Dyke-like bodies are spatially closely associated with the identified large fault zones, and the development of ore-bearing structures occurs precisely here, that is, in the areas of occurrence of dykes that create a profound mechanical heterogeneity of the surrounding formation. The ore zone of the deposit has a southern declination at an angle of 50 °. On the strike, it is tracked for 1 100 m (horizon -30 m), and it has been explored to a depth of 360 ... 500 m [6]. The vein assemblage is represented by emerald-bearing micaceous and beryl-bearing quartz-plagioclase veins (Figure 1).

Micaceous ore bodies are the only carriers of beryllium raw materials. They contain an overwhelming (more than 95%) amount of beryl, which is also characterized by the highest (13.4 g/t) content of this component. Micaceous assemblage found in talc schists is characterized by the highest (16.1 g/t) content of emerald raw materials. They are quite diverse. This diversity is due to different chemical and mineral composition of protoliths, the duration and polygeneration of metasomatic processes. Among the rocks that have undergone metasomatic processing one can mention apohyperbasite and apodiorite rocks [7], apovulcanite and apocarbonate, apoamphibolite and apogabbroic rocks; according to mineral composition of the central zones: Biotite-plagioclase-phlogopite, quartz-plagioclase-phlogopite, topaz-plagioclase-phlogopite, and chrysoberyl-phenacite-phlogo-pite [5]. Within the ore zones of known deposits of beryl and emerald, micaceous assemblage is accompanied by small veins of talc-carbonate, quartz-epidote, plagioclase, or fluorite composition filling with open cracks.

Methods of studying the magnetic susceptibility of rocks and objects of study

The study of magnetic susceptibility to differentiate the magnetic properties of natural minerals has been repeatedly used by researchers [8-10]. In order to study the magnetic properties of typical rocks and ore bodies of the Mariinsky deposit, the PIMV-M field magnetic susceptibility meter with a measurement range of 1 • 10-5... 1 SI units was used in the underground mine directly. Relative measurement error does not exceed ± 10% in the range (10-4 ... 1) SI units, in the range (10-5 ... 10-4) SI units is not rated. Measurement was carried out at barings in mine workings (layering crossdrifts, dass, ore drifts) at horizons +15, -30, -120 m. The measurement was carried out by applying the flat surface of the measuring transducer to the bottomhole wall in a lithologically homogeneous section with subsequent measurement and recording of the obtained value in the field document. At

Figure 1. Geological structure of the Mariinsky Deposit [5]. Рисунок 1. Геологическое строение Мариинского месторождения [5].

the same time, the faces under study were uneven (rough), and the gap between the device and the surface under study was from 0.3 to 0.7 mm, 0.5 mm on average. Since the PIVM-M device measures the apparent magnetic susceptibility k ', the transition to the true magnetic susceptibility value k is realized by the formula k = k'/ (1 - 0.5 k). Since all obtained values of apparent magnetic susceptibility are less than 0.1 (k ' < 0.1 SI units), then it was considered to be k = k '[11]. Due to irregularities of the face walls, i.e. an "outshot-lobe" difference, as a result of which the gap between the measured surface and the flat surface of a transducer is 0.5 mm on average, the unevenness-correction factor of 1.41 was introduced to calculate the magnetic susceptibility. Table 2 shows the measurement data of magnetic susceptibility in the underground mine.

Methods of studying the electrical resistivity of rocks and objects of study

The electrical resistivity of rocks is carried out both using samples in a laboratory and in natural occurrence. This kind of work has already been done in laboratory setting but with other species of rocks [12, 13]. We used standard samples in the form of cubes of size 24 x 24 x 24 mm, the composition of which was examined using the binocular enhancer MBS-10 for studying the electrical resistance. The measurements were carried out along three axes since almost all samples have anisotropy. Table 3 shows the average measurement data for different axes. The teraohmmeter E6-13A was used for working. The measurements were carried out according to the method described in [ 14]. In addition, Table 3 shows the average data of magnetic susceptibility measured along three axes using the same samples in laboratory setting (PIMV-M device).

Discussion of results

The average values of magnetic susceptibility of various rocks and ore complexes of the Mariinsky emerald-beryllium deposit are close (with the exception of serpentinites). The unevenness in magnetization intensity of rocks indicates the connection of their magnetic properties with accessory minerals that are found in them. In serpentinites, magnetite Fe3O4 (magnetic susceptibility is 4 ... 25 SI units) is most common, and chromite is found. In diorite porphyrites - pyrrhotite Fe6O7 (magnetic susceptibility

Table 2. Average data for magnetic susceptibility of the main rocks of the Mariinsky field obtained directly from measurements in an underground mine.

Таблица 2. Средние показатели магнитной восприимчивости основных пород Мариинского месторождения, полученные непосредственно при измерениях в подземном руднике.

Names of rocks Number of measurements The average x, SI units ■ 10-4 The average, taking into account the coefficient 1.41, SI units

Serpentinites 25 7.2 10.2

Talc schists and rocks 39 3.4 4.8

Diorite porphyrite and quartz diorite 62 5.2 7.3

Tremolite-actinolite schists 13 3.1 4.4

Chlorite schists 7 2.7 3.8

Quartz-plagioclase veins 10 - -

Micaceous assemblage 43 1.5 2.1

Carbon-bearing-siliceous shales 10 5 7.1

Table 3. Characteristics of the main host rocks and ore complex of the Mariinsky deposit.

Таблица 3. Характеристики основных вмещающих пород и рудного комплекса Мариинского месторождения.

Sample number

Rock

Texture

Mineral composition

Magnetic

Peculiar properties susceptibility, SI units

Electrical resistivity, MOhm

1A 1B

Quartz-pla-gioclase

Quartz - 80 %, Massive plagioclase - 20 %,

sulfides (less than 1 %)

Sulphide mineralization in gray quartz

900 000 900 000

2A 2B

3A 3B

Glimmerite

Glimmerite

Schistic

Massive

Bastonite

Light-colored micas sulfides (less than 1 %)

Occasional ore inclusions

Small sulphides are

distributed

unevenly

2.4 • 10-4

4.3 • 10-4

200 000 320 000

100 95

4A 4B

Glimmerite

Stratified

Brown-colored mica - 90%, feldspar - 10 %

Feldspar grains in glimmerite

2.9 • 10-4

340 180

5A 5B

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Serpentinite

Massive, eutaxic

Serpentine - 90 %, talc - 10 %

Ore mineral is not visible

1.7 • 10-4

25 000 25 000

6A 6B

Plagioclase gabbro

Massive, spotted

Amphibole - 80 %, feldspar 20 %

Ore and sulphide mineralization is not detected

1.7 • 10-4

27 000

28 000

7A 7B

Quartz-muscovite Massive, rock eutaxic

Quartz - 20%, light-colored mica 0%, brown-colored mica - 50%

Rare small, sulphide mineralization

5.0 • 10-5

900 000 450 000

8A 8B

Talc-serpentinite Knotty

Serpentine - 68 %, talc - 30 %, ore mineral - 2 %

Pulverous ore inclusion

1.8 • 10-4

400 450

9A 9B

Talc

Massive, schistic

Talc - 95 %, ore mineral (4-5 %)

Ore mineral is distributed evenly along stratification

6.2 • 10-4

300 000 170 000

10A 10B

Phlogopite-pla-gioclase

Knotty

Plagioclase - 60 %, brown-colored mica (40 %)

Mica evaluates along cracks in plagioclase vein

5.0 • 10-5

70 000 80 000

11A 11B

Silicious-car-

bon-bearing rock Massive with mica

Mica - 80 %,

Carbon-bearing substance -14 %, ore mineral - 1 %

Single grains of ore mineral

3.2 • 10-4

0.36 0.24 700

12A 12B

Talc-actinolite

Massive

Actinolite - 70 %, talc -15 %, phlogopite -13 %, ore mineral (about 1-2 %)

Single grains of ore mineral are distributed unevenly.

1.4 • 10-4

90 000 17 000

13A 13B

Glimmerite

Schistous Brown-colored mica - 100 %,

Ore mineral is not identified

2.0 • 10-4

50 000 30 000

0

Sample number Rock Texture Mineral composition Peculiar properties Magnetic susceptibility, SI units Electrical resistivity, MOhm

14A 14B Amphibolite Massive Plagioclase - 40 %, amphibole - 45 %, mica - 5 % Single inclusions of ore mineral are noted. 3.2 • 10-4 2000 1750

15A 15B Quartz-mica schist Schistous Mica - 80 %, quartz - 15 %, Ore mineral is not identified 4.0 • 10-4 300 000 400 000

16A 16B Serpentinite Massive, spotted Serpentine - 96 %, ore mineral - 4 % Ore mineral (vein-lets) is unevenly distributed 2.8 • 10-4 310 360 2400 3500

17A 17B Serpentinite Massive Serpentine - 90 %, ore mineral - 10 % Ore mineral is distributed unevenly 2.5 • 10-3 25 000 18 000

18A 18B Diorite Massive, knotty Amphibole - 35%, plagioclase -45%, mica - 15%, quartz - 5% Ore mineral is not identified 1.5 • 10-4 1600 2400

19A 19B Quartz rock Massive Quartz - 100 %, Ore mineral is not identified 0 50 000 400 000

20A 20B Chlorite-talc Schistous Talc - 75 %, chlorite - 20 %, ore mineral (less than 5 %) Ore mineral (silt) is evenly distributed 2.0 • 10-4 9000 320 000

21A 21B Glimmerite with fluorite Schistous Mica - 75 %, fluorite- 25 % Ore mineral is not identified 1.7 • 10-4 150 000 100 000

22A 22B Serpentinite Massive Serpentine - 95 %, talc - 4 %, ore mineral - 1 % Ore mineral (single grains) is distributed unevenly 6.5 • 10-4 320 000 20 000

23A 23B Talcose ser-pentinite Massive Talc - 45 %, Serpentine - 40 %, ore mineral - 5 % Ore mineral (single grains) is distributed extremely unevenly 1.5 • 10-4 600 000 80 000

24A 24B Dolerine with phlogopite Schistous Talc - 65 %, mica - 34 %, ore mineral - 1 % Ore mineral in the form of small grains 2.2 • 10-4 170 000 100 000

25A 25B Diorite Schistous Amphibole 5-7 %, feldspar - 65 %, mica - 25-30 % Ore mineral is not identified 1.3 • 10-4 300 000 200 000

26A 26B Talcose ser-pentinite Massive Serpentine - 80 %, talc - 15 %, ore mineral (about 5 %) Ore mineral (bunches) is distributed very unevenly 4.0 • 10-4 90 000 150 000

27A 27B Actinolite-chlorite Schist Massive Actinolite - 60 %, talc - 35 %, ore mineral (about 5 %) Ore mineral (single grains) is distributed unevenly 1.7 • 10-4 110 115

28A 28B Chlorite-talc-ac-tinolite Schistic Amphibole - 44 %, chlorite - 25 %, talc - 30 %, ore mineral - 1 % Ore separation in the form of fine grains 2.3 • 10-4 32 40 2300 2200

29A 29B Serpentinite Knotty Serpentine - 80 %, talc - 15 % ore mineral (5 %) Ore mineral (fine impregnation) is distributed along cracks and occasionally 1.7 • 10-4 4500 4700

30A 30B Serpentine-talc rock Knotty, eutaxic Serpentine - 30 %, talc 65 %, ore mineral (5 %) Ore mineral (single grains) is distributed extremely unevenly 3.5 • 10-4 55 000 320 000

is 10-2 ... 10-1 SI units), ilmenite (magnetic susceptibility is 4... 25 SI units) and titanite (less commonly magnetite). There are magnetite, ilmenite, and titanite in talc, chlorite and tremolite-actinolite schists, which affect the overall magnetic susceptibility of rocks. Mica complexes mainly consist of phlogopite (magnetic susceptibility is 20 ■ 10-5 SI units), but chromite, ilmenite, and titanite are rarely found in them. The content of accessory minerals in micas does not exceed two decimal places and three decimal places [15]. Sometimes fine-grained magnetite is found in apodiorite glimmerites, which increases the overall magnetic

Figure 2. Values of electrical resistance and magnetic susceptibility for selected samples from the Mariinsky deposit. Рисунок 2. Значения электросопротивления и магнитной восприимчивости на отобранных образцах с Мариинского месторождения.

susceptibility of these rocks. The magnitude of the magnetic susceptibility of quartz-plagioclase veins is below the measurement limit of the PIVM-M device (k <10-5 SI units) due to the absence of the main "magnetic minerals" (magnetite, pyrrhotite, ilmen-ite). The location of ore-bearing zones along the boundaries of the contacts of serpentinites with glimmerites makes it possible to identify zones of these contacts by magnetic susceptibility. Serpentinites have a greater magnetic susceptibility (10-4 ... 10-3 SI units) than other rocks.

The works carried out by the authors in the mine of the Mariinsky emerald-beryllium deposit followed by laboratory studies showed that the main carrier rocks of beryllium mineralization (glimmerites and quartz-plagioclase veins) differ in magnetic susceptibility from other rocks of this deposit. Thus, the magnetic susceptibility of phlogopite schists ranges from 0.2 to 2.3 ■ 10-4 SI units. The magnetic susceptibility of plagioclase-quartz veins is equal to zero. The host rocks (serpentinites), in turn, have a magnetic susceptibility 30 ■ 10-4 SI units. The obtained values of apparent resistivity also show the difference between unproductive vein complexes and those containing the ore component (beryl). In addition, there is a dependence of the electrical resistance values of hyperbasites on the degree of metamorphism:

- peridotites slightly serpentinized - 1600 ... 2400 MOhm, sam. No 18;

- serpentinites -3500... 25 000 MOhm, sam. No 5, 16, 22;

- serpentinite-talc-carbonate rocks - 400 ... 450 MOhm, sam. No 8;

- mica veins - 30 000 ... 320 000 MOhm, sam. No 13, 2.

According to the results of the work, it was found that mica veins are found only in hyperbasites of low-resistivity. It is obvious that the decrease in electrical resistance is due to a complex of metamorphic processes. Mica veins are distinguished among host rocks by high electrical resistance, which is caused by their composition - these are schists consisting mainly of phlogopite with mica scales along schistosity. According to the data of parametric measurements of samples in early studies [2], the average specific electrical resistance of mica veins is 70 000 Ohm ■ m, which is significantly higher than the electrical resistance of host rocks. A similar situation is observed in our research.

If we jointly construct graphs (Fig. 2) of magnetic susceptibility and electrical resistance for various types of rocks found in the Mariinsky deposit, then it can be noted that the separation of mica veins only according to magnetic susceptibility is impossible due to a large number of nonmagnetic rocks. The separation of productive mica veins only according to the electrical resistiv-

ity data is also not possible due to the presence of rocks of the same electrical resistivity. However, the use of these two methods at the same time when setting certain studied parameters makes it possible to create equipment for the express method of inspection and selection of promising ore zones (complexes). Conclusions

The method proposed by the authors is based on difference in magnitude of the magnetic susceptibility and electrical resistance in the ore and ore-free sites. For each of the parameters studied, it is impossible to indicate unequivocally about the degree of mineralization; however, their complex use and interpretation allow us to identify signs by which ore zones can be distinguished in the field.

The use of this express method at the site (in mine workings) will allow for prompt determination of the location of serpentinite bodies and talc schists, in contact of which micaceous complexes productive for beryllium mineralization are often found.

This method (with a large set of statistical data) will allow us to confidently distinguish productive apohyperbasite glimmer-ites from unproductive apodiorite and other micaceous complexes at the Mariinsky deposit. Acknowledgements

This work was supported partly by the Ural Branch of the Russian Academy of Sciences Program called "Development of petrophysical methods for studying rocks and ores in order to study the geological structure of deposits and improve their prospecting and exploration methods" (Project 18-5-5-52) and the state program called "Reconstruction of the formation conditions complexes of the Ural-Mongolian fold belt and associated mineralization "(State number AAAA-A18-118052590033-3).

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The article was received on November 13, 2018

УДК 550.832.9

https://doi.org/10.21440/2307-2091-2019-1-39-47

Геофизические критерии выделения продуктивных слюдитовых жил Мариинского изумрудно-бериллиевого месторождения (Средний Урал)

Михаил Петрович Попов1, 2*, Олег Петрович Пелешко3**, Евгения Анатольевна Баженова4***, Виктор Сергеевич Иванченко4****, Владимир Васильевич Бахтерев4*****

1Уральский государственный горный университет, Россия, Екатеринбург 2Институт геологии и геохимии им. А. Н. Заварицкого УрО РАН, Россия, Екатеринбург 3АО «Мариинский рудник», Россия, Свердловская область, г Асбест, пос. Малышева "Институт геофизики им. Ю. П. Булашевича УрО РАН, Россия, Екатеринбург

Актуальностью работы является разработка новых методов оперативного выделения (обнаружения) рудных тел непосредственно в подземном руднике месторождения. Измерения были проведены как на специально подготовленных образцах в форме кубиков одного размера, так и в условиях естественного залегания.

Целью работы является изучение магнитной восприимчивости и электросопротивления основных вмещающих пород и рудного комплекса (изумрудоносных слюдитов и кварц-плагиоклазовых жил с бериллом) на самом известном уральском изумрудно-бериллиевом месторождении - Мариинском.

Метолология исслелования: для исследований магнитных свойств типовых пород и рудных тел Мариинского месторождения непосредственно в подземном руднике использовался измеритель магнитной восприимчивости полевой ПИМВ-М с диапазоном измерения 1 • 10-5_1 ед. СИ.

Относительная погрешность измерения не превосходит ±10 % в диапазоне 10-4___1 ед. СИ. Измерение проводилось путем плотного прикладывания

плоской поверхности первичного преобразователя прибора к стенке забоя в литологически однородный участок с последующим измерением и записью полученного значения в полевой журнал документации горных выработок. Для изучения электросопротивления были использованы стандартные образцы в форме кубиков размером 24 х 24 х 24 мм, состав которых параллельно изучался под бинолупой МБС-10. Измерения проводились по трем осям, так как практически у всех образцов присутствует анизотропия. Для работы использовался тераомметр Е6-13А. Результаты. Приведены данные по магнитной восприимчивости и электросопротивлению основных вмещающих пород и рудного комплекса (изумрудоносных слюдитов и кварц-плагиоклазовых жил с бериллом) с Мариинского месторождения. Все данные согласованы с петрографическими характеристиками пород.

Выволы. Показана принципиальная возможность создания новой экспресс-методики выделения продуктивных слюдитовых жил в скважинах и забоях по одновременному измерению магнитной восприимчивости и электросопротивления пород непосредственно в процессе добычных работ в подземном руднике.

Ключевые слова: Урал, магнитная восприимчивость, электросопротивление, слюдиты, кварц-плагиоклазовые жилы, изумрудно-бериллиевые месторождения, Уральские изумрудные копи.

Работа выполнена частично при поддержке Программы УрО РАН «Разработка петрофизических методов исследований горных пород и руд с целью изучения геологического строения месторождений и совершенствования методов их поиска и разведки» (Проект 18-5-5-52) и государственной программы «Реконструкция условий формирования габбро-ультрабазитовых комплексов Урало-Монгольского складчатого пояса и связанного с ними оруденения» (Гос. номер АААА-А18-118052590033-3).

ЛИТЕРАТУРА

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3. Everett M. E. Near-Surface Applied Geophysics. Cambridge: Cambridge University Press, 2013. 442 p.

4. Hao J., Gu Z., Zhou J. Anisotropy of magnetic susceptibility of rocks induced by experimental deformation // Annals of Geophysics. 1997. Vol. 40, № 2. P. 455-462. https://doi.org/10.4401/ag-3923

5. Жернаков В. И. Топаз-парагонитовые метасоматические комплексы Мариинского месторождения изумруда // Геология метаморфических комплексов. Екатеринбург: УГГГА, 1998. С. 94-101.

6. Золотухин Ф. Ф. Мариинское (Малышевское) месторождение изумруда, Средний Урал. Асбест; Екатеринбург; СПб.: СПбГУ, 1996. 70 с.

7. Жернаков В. И. Определение положения изумрудного оруденения в метасоматических колонках слюдитового типа // Метасоматизм и рудообразование: тез. докл. V Всерос. конф. (23-25 нояб.). Киев, 1982. С. 24-25.

8. Hoover D. B., Williams B., Williams C., Mitchell C. Magnetic susceptibility, a better approach to defining garnets // The Journal of Gemmology. 2008. Vol. 31, № 3/4. P. 91-103.

" ED [email protected]

http://orcid.org/0000-0002-0527-8234

** [email protected] """ [email protected]

https://orcid.org/0000-0002-2068-7140 *"*[email protected]

http://orcid.org/0000-0002-1294-6050 [email protected]

http://orcid.org/0000-0002-1174-1301

9. Grimley D. A., Wang J.-S., Liebert D. A., Dawson J. O. Soil magnetic susceptibility: a quantitative proxy of soil drainage for use in ecological restoration // Restoration Ecology. 2008. № 16. P. 657-667. https://doi.org/10.1111/j.1526-100X.2008.00479.x

10. Zhanxiang He, Yunxiang Liu, Xiaodong Suo, Dong Weibin. Application of Magnetic Prospecting in Recognition of Volcanic Reservoirs // Recorder (official publication of the Canadian Society of exploration geophysicists). 2008. Vol. 33, № 01. P. 45-48.

11. Филатов В. В. Магниторазведка: магнитная восприимчивость, индуцированная и естественная остаточная намагниченности. Екатеринбург: Изд-во УГГУ, 2008. 236 с.

12. Amadu Casmed Charles, Gawu Simon K. Y, Abanyie K. Samuel. Experimental Study of Electrical Resistivity to Rock Fracture Intensity and Aperture Size // International Journal of Physics. 2018. Vol. 6, № 3. P. 85-92. https://doi.org/10.12691/ijp-6-3-4

13. Permyakov M. E., Manchenko N. A., Duchkov A. D., Manakov A. Yu., Drobchik A. N., Manshtein A. K. Laboratory modeling and measurement of the electrical resistivity of hydrate-bearing sand samples // Russian Geology and Geophysics. 2017. Vol. 58. Issue 5. P. 642-649. https://doi. org/10.1016/j.rgg.2017.04.005

14. Бахтерев В. В. Закономерности изменения электрических параметров образцов горных пород гипербазитовых массивов Урала при высоких температурах // Изв. вузов. Геология и разведка. 2015. № 2. С. 41-47. https://doi.org/10.32454/0016-7762-2015-2-41-47

15. Laskovenkov А., Fand N., Zhernakov V. An Update on the Ural Emerald Mines // Gems & Gemology. 1990. Vol. 31, № 2. P. 106-113.

Статья поступила в редакцию 13 ноября 2018 г.

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