RU2667329C1 - Method of geological mapping of accretive complexes - Google Patents

Abstract

FIELD: geology.

SUBSTANCE: invention relates to the field of geological mapping and can be used to map accretionary rock complexes. Separate groups of rocks limited by two systems of thrusts, characterized by the repetition of identical rock associations, including basalt-silicon-siliciclastic sandstone in different combinations, and the same age of rocks. Reconstruct the true stratigraphic sequence of layers according to the model of a stratigraphic oceanic plate. Determine the direction of subduction of the oceanic plate and make a geological map.

EFFECT: correct geological mapping.

1 cl, 3 dwg

Description

Technical field

The invention relates to geology, in particular to the field of reconstruction of geological processes in the development of the earth's crust based on mapping accretionary complexes having a complex structure.

State of the art

Modern methods of geological interpretation of mapping are based on the Steno law, which assumes that if one layer (layer) of rocks lies on another, then the upper layer is formed later than the lower. Accordingly, in the absence of data on absolute age (paleontology, isotopy) for different rock layers, their relative age is determined according to the Steno law. This situation is extremely widespread in geological mapping, because it is impossible to measure the exact age of each layer.

The present invention provides another method for reconstructing geological processes based on isolating the alternation of repeating rock layer complexes.

For convenience, the description of the method provides a definition of the terms used.

Subduction of the oceanic lithosphere is the process of movement of the oceanic crust from the place of its formation in the mid-ocean ridge towards the subduction zone, where it moves under an island arc or an active continental margin and plunges into the mantle.

Accretion complexes are a complex of rocks formed as a result of subduction of the oceanic crust, “cutting” of its upper layers and their attachment to either an island arc complex or an active continental margin. Also, the composition of the accretionary complex includes terrigenous rocks formed by the destruction of adjacent island or continental arcs. After the ocean closes as a result of a continental collision, later magmatic formations may also be included in the composition of the accretion complex: syn- and post-collisional or intraplate formations.

Convergent margins are the boundaries of converging or converging lithospheric plates.

Stratigraphic sequence - the sequence and subordination of the stratigraphic units of rocks that make up the earth's crust.

Orogenesis (orogen) is a geological process of formation of mountain structures under the influence of intense ascending tectonic movements, the speed of which exceeds the speed of processes leading to the alignment of the Earth's surface (denudation, discharge)

Ocean floor spreading is the geodynamic process of pushing hard lithospheric plates under the influence of magmatic melt injected from below in the region of mid-ocean ridges.

However, the Steno law does not work or works poorly in accretion complexes formed on convergent margins of the Pacific type, i.e. during subduction of the oceanic lithosphere, accompanied by accretion (joining) of oceanic rocks to intraoceanic island arcs or their joint accretion to active continental margins. Accretionary complexes have an extremely complex geological structure, as during subduction, the upper layers of the submerging oceanic lithosphere - basalts and still slightly consolidated oceanic sediments (pelagic flints - hereinafter “pelagites”, chemipalegic siliceous mudstones and siltstones - hereinafter “chemipelagites”), are separated (“cut off”) from the lower layers of the oceanic and move under each other, thereby violating the original stratigraphic sequence.

In this case, duplex structures are often formed, which are two thrust systems: 1) two parallel thrusts, limiting the plates of oceanic rocks above and below, which in the literature are called roof thrust (top thrust) and bottom thrust (bottom thrust); 2) a system of linking thrusts or sub-thrusts (“linking thrusts”), separating individual plates / packs of oceanic rocks and ending at the surfaces of the thrust of the roof and thrust of the sole. Such separate packs of rocks, separated by connecting thrusts, are called “horse” in English literature, which can be translated as “saddle” (hereinafter - “horse”).

Diagnosis of such thrusts / subthrusts is very difficult, especially in the field, since sedimentary rocks still have a weak degree of consolidation or lithification during accretion, i.e. they are still very saturated with water. As a result, the younger layers are shifted to the older, accreted earlier; the boundaries between the questioned strata of oceanic sediments are unclear, blurry, and therefore they are often mistaken for a consonant occurrence.

Such a feature of the formation of accretionary complexes can lead to errors in the mapping of accretionary complexes that are part of the Pacific fold type belts. This is especially important when mapping similar folded belts of ancient age, which are currently located in the inland continental regions formed during the closure of ancient oceans, such as, for example, the Central Asian folded belt (CASP), which stretches from the Urals to the Far East and is the main accretionary Orogen of Russia. A huge number of mineral deposits are associated with the formation of TsASP, so their search and exploration directly depend on the quality of mapping complex structures of accretion complexes, which is the subject of this application.

Disclosure of invention

The objective of the invention is to develop a new method that allows you to reconstruct the original sequence of oceanic rocks in the mapping of accretionary complexes.

The technical result consists in compiling a correct geological map of a particular accretionary complex and the entire area.

The problem is solved by reliable diagnostics of fragments of the oceanic crust in the composition of intracontinental folded belts and the identification of a convergent margin of the Pacific type, for which it is proposed to use the model of ocean plate stratigraphy (SOP), which allows reliable reconstruction of the true stratigraphic sequence and thereby ensures the compilation of a correct geological map.

SOP is a stable association of igneous and sedimentary rocks formed in various parts of the ocean floor: from the place of origin of the oceanic crust in the mid-ocean ridge and the deep-sea conditions of the ocean floor (pelagic zone) to less deep-seated conditions of oceanic uplifts (seamounts, plateaus and islands ) and the continental slope (chemipelagic zone), to the zone of the deep-sea ocean trench in the place of direct subduction of the oceanic lithosphere. During subduction, SOP rocks are involved in the accretion process and are part of accretion complexes (Isozaki et al., 1990).

SOP consists of material, lithologically and structurally different elements. Under the conditions of the ocean floor, basalts of mid-ocean ridges (MORB type) deposit pelagic flints (pelagites), which often have a ribbon texture and contain the remains of microorganisms by which it is possible to determine the age of the rocks. In the process of ocean floor spreading, flints move toward the subduction zone, and their thickness and, accordingly, increase.

Over time, pelagic sediments approach the subduction zone and find themselves in a less deep or chemipelagic setting, i.e. on the offshore or oceanic segment of the deepwater trench, usually near an island arc or continental margin. There, the pelagites begin to overlap with hemipelagites, consisting of fine-grained clastic material (siliceous mudstones, siltstones) coming from an adjacent volcanic arc or active margin. Such rainfall may also contain fauna. After this bundle of sediments reaches a deep-sea trench, terrigenous material coming from an island arc or an active continental margin begins to be deposited on top of them, with the formation of turbidites and conglomerates.

Thus, the schematic section of SOP includes (from bottom to top) basalts of the MORB type - pelagites - chemipelagites - turbidites (Isozaki et al., 1990; Kusky et al., 2013).

Each pack of rocks of accretionary SOP or each horse is separated from the other by connecting overthrusts, and all the horses are together, separated from other rock associations of the accretion complex (melange, island arc volcanics, terrigenous matrix) by roof and sole thrusts. In the process of accretion, each subsequent one, i.e. the younger horse moves under the accretion of the earlier older horse.

At the same time, in the field or on the map, we can observe a uniform alternation of the layers (packs, layers) of SOP without visible signs of disagreement. In accordance with the law of Steno, the lowermost strata must be older than the upper ones. But on the example of the Inuyama complex, where all layers of SOPs were sold by radiolarians and conodonts (fauna), previous researchers showed that this sequence is a repeating alternation of packs of Triassic pelagites (flints) and Jurassic chemipelagites, i.e. these structures are duplexes. Therefore, accreted SOP rocks cannot be studied by traditional methods, since There are no clear signs of an inconsistent occurrence (poorly consolidated precipitation), and the Steno law does not work. And when constructing a geological map in accordance with the official recommendations of the Ministry of Natural Resources of the Russian Federation, the stratigraphic sequence is determined on the basis of the principles of the Steno law.

In the geological mapping of accretionary complexes, we propose to distinguish repeated packs of SOP rocks and, if available, their “chorses”, i.e. structures limited by 2 thrust / sub-thrust systems - roof-sole thrusts and their interconnections. In this case, each chors should have the same composition of SOP rocks (basalts - pelagites - chemipelagites), the structure itself should be characterized by repeatability, i.e. the alternation of chors composed by the same SOPs and the close age of the breeds within each chorus, but with different ages of the chors themselves.

Description of the invention is illustrated by drawings.

In fig. 1a, the formation of duplex structures consisting of separate “chorses” during subduction of the oceanic crust is depicted (Isozaki et al., 1990).

In fig. 1b shows the mechanism of moving younger sediments into older ones: the oldest SOP-1 is accreted first, then younger than SOP-2 and even younger than the previous SOP-3

In fig. 2 shows a stratigraphy diagram of an oceanic SOP plate.

In fig. Figure 3 shows a section of the Inuyama Mino accretion complex, Japan (Fujisaki et al., 2013). This figure shows that the oldest horse-1, which was accreted before the others, was at the top of the section, and the youngest horse-6 was at the very bottom.

The implementation of the method

The inventive method of mapping with the selection of "Chors" is as follows:

1. Ensure the presence of any of the four main types of rocks: basalt-silicon-silicilastic-sandstone (composition of SOP).

2. Define the boundaries of the "horse". The borders of the "chors" are determined by the zones of deformation in the field and by faults on the geological map. Usually they have the form of duplex structures (“S” -shaped bending limited by “upper” and “lower” faults), as well as a similar lithological composition and age. If there are no boundaries in the field, then the boundaries can be reconstructed by the repeatability of two or more layers of SOP rocks (basalt-silicon-siliciclastic-sandstone).

3. Careful mapping in the field, measuring the elements of occurrence and drawing the structure of each layer of rocks.

4. Determine the lithological composition of each layer from the "Chors".

5. Determine the age (fauna, isotopic dating) of each layer.

6. If the same ages of each lithologically identical layer from different repeating packs are confirmed, then it is concluded that this is a “chorus” formed during SOP accretion. Consequently, the initial stratigraphic sequence of layers should not be reconstructed according to the Steno law, but based on the SOP model. The direction of subduction of the oceanic plate can be reconstructed from the age sequence of the chors, which is extremely important for constructing tectonic maps. Also, all this confirms the presence of a convergent margin of the Pacific type in the region.

Claims (1)

 A method of geological mapping of accretionary complexes, including determining the lithological composition of rocks, their age and elements of their occurrence, characterized in that they distinguish bundles of rocks (chors) limited by 2 thrust systems - roof and sole thrusts and their thrusts connected, characterized by the presence of identical repeatability associations of rocks, including in different combinations of basalt-silicon-siliciclastic-sandstone, and the same age of the rocks within each chorus, reconstruct the true stratigraphic sequence the layers according to the model of the stratigraphic oceanic plate, determine the direction of subduction of the oceanic plate and make up the correct geological map.

Images