scholarly journals On the volumes of deep carbon — the initial donor of hydrocarbons on the Earth

2021 ◽  
Vol 43 (1) ◽  
pp. 251-265
Author(s):  
A.I. Timursiev
Keyword(s):  
Carbon Content ◽  
Upper Mantle ◽  
Unit Volume ◽  
Oil And Gas ◽  
Iron Carbides ◽  
Crust And Upper Mantle ◽  
Melted Zone ◽  
The Earth ◽  
Weight Content ◽  
Carbon Reservoir

Existing notions on the distribution of carbon on the Earth have been considered in the article. By the example of the data on carbon content in the upper mantle of the Earth obtained in the west of the USA by deep seismic tomography method the appraisal of the resource potential of the interior has been made within the limits of the theory of the deep abiogenous-mantle origin of oil and gas. According to the given appraisal, the partly melted zone (reservoir) contains not less than 1.2·1017 kg of volatiles (Q, kg), such as H or C. Calculation by carbon (С) taking into account the initial data demonstrated that the weight content (concentration) of carbon per unit volume of the Earth crust and upper mantle for which the appraisals of carbon content were completed will be 1 333.3 kg/m3 or 1.3 t/m3 (1.3 g/cm3). With average amount of melt of the rocks of the upper mantle 0.5±0.2 % (per volume), the volume of the area of melting of the Earth crust (deep carbon reservoir), containing the appraised volume of volatiles, will be: 4.5·1011 m3. In such a notion the weight content (concentration) of carbon per unit volume of partly melted zone of deep carbon reservoir will be: 2.67·105 kg/m3 or 266.67 t/m3 (266.67 g/cm3). These are very high figures if not to say fantastically high, characterizing not only high content of carbon and hydrogen as the main donors of hydrocarbons but also characterizing concentration of these elements within definite zones of the upper mantle of the Earth (asthenospheric layer) by all components (composition, concentration, phase state, PT-conditions), which is referred by our opinion to the sources of deep oil and gas formation. The data presented allow us to affirm that the problem of donors of HC of deep, abiogenous-mantle genesis has been resolved in our concept, and the source has been determined with high probability of the primary donors of HC in the section of the mantle and iron-carbon core of the Earth having inexhaustible resources of primary carbon, with its phase composition depending on PT conditions of the terrestrial envelopes might be crystalline (diamond phase, iron and nickel compounds (Fen+Nin)+Cn, iron carbides, for example — FeC, Fe2C, Fe3C (cementite) et al.), liquid (for example, the melt with admixture of sulfur and other volatiles H-N-F-O-Cl) and gaseous (СО2 gaseous only in the mantle, higher than D″ layer). In this case HC synthesis in industrial volumes is realized in the process of hydrogenation of deep carbon on the ascending hydrogen streams within the limits of asthenospheric lenses favoured by the presence of reaction volume here, catalysts and the necessary PT-conditions for polymerization of hydrocarbon radicals.

Reflections from discontinuities beneath antarctica

1971 ◽  
Vol 61 (5) ◽  
pp. 1441-1451
Author(s):  
R. D. Adams
Keyword(s):  
North American ◽  
Upper Mantle ◽  
Deep Structure ◽  
Low Velocity ◽  
Crust And Upper Mantle ◽  
Nuclear Explosions ◽  
Novaya Zemlya ◽  
The Earth ◽  
Velocity Channel ◽  
Upper Boundary

abstract Early reflections of the phase P′P′ recorded at North American seismograph stations from nuclear explosions in Novaya Zemlya are used to examine the crust and upper mantle beneath a region of eastern Antarctica. Many reflections are observed from depths less than 120 km, indicating considerable inhomogeneity at these depths in the Earth. No regular horizons were found throughout the area, but some correlation was observed among reflections at closely-spaced stations, and, at many stations, reflections were observed from depths of between 60 and 80 km, corresponding to a likely upper boundary of the low-velocity channel. Deeper reflections were found at depths of near 420 and 650 km. The latter boundary was particularly well-observed and appears to be sharply defined at a depth that is constant to within a few kilometers. The boundary at 420 km is not so well defined by reflections of P′P′, but reflects well longer-period PP waves, arriving at wider angles of incidence. This boundary appears to be at least as pronounced, but not so sharp as that near 650 km. The deep structure beneath Antarctica presents no obvious difference from that beneath other continental areas.

scholarly journals Earth as a Gravitational-Wave Interferometr

2019 ◽  
Vol 224 ◽  
pp. 03012
Author(s):  
Vadim Il’chenko
Keyword(s):  
Gravitational Wave ◽  
Upper Mantle ◽  
Oscillatory System ◽  
Average Depth ◽  
Lunar Tide ◽  
Crust And Upper Mantle ◽  
The Earth ◽  
Order Of Magnitude ◽  
Gravitational Wave Interferometer ◽  
Gravitational Influence

Based on the principle of Equivalence of Gravitating Masses (EGM) and tectonostratigraphic model of the Earth outer shell structure (the Earth crust and upper mantle), the average depth of the lunar mass gravitational influence on the Earth was calculated as ~1600 km. The developed model is based on the mechanism of rocks tectonic layering of the Earth crust-mantle shell as an oscillatory system with dynamic conditions of a standing wave, regularly excited by the lunar tide and immediately passing into the damping mode. After comparing the average depth of solid lunar tide impact of ~1600 km with the height of the solid lunar tide “hump” on the Earth surface of 0.5 m, a “tensile strain” was calculated with an amplitude only one order of magnitude larger than the amplitude of the gravitational wave recorded by the Advanced LIGO interferometer: A≈10-18 m (the merger result of a black holes pair ca 1.3 Ga ago). The results of the present study suggest that the crust-mantle shell of the Earth may be used as a gravitational-wave interferometer.

scholarly journals Symposium on the Crust and Upper Mantle of the Earth

1964 ◽  
Vol 73 (3) ◽  
pp. 137-138
Author(s):  
Hisashi KUNO ◽  
Hitoshi TAKEUCHI ◽  
Seiya UEDA
Keyword(s):  
Upper Mantle ◽  
Crust And Upper Mantle ◽  
The Earth

Electrical properties of the lithosphere in the western desert, Egypt, using magnetotelluric sounding

2021 ◽  
Author(s):  
Hossam Marzouk ◽  
Tarek Arafa-Hamed ◽  
Michael Becken ◽  
Mohamed Abdel Zaher ◽  
Matthew Comeau
Keyword(s):  
Upper Mantle ◽  
Seismic Velocity ◽  
Western Desert ◽  
Velocity Data ◽  
Profile Data ◽  
Crust And Upper Mantle ◽  
Near Surface ◽  
The Earth ◽  
Nubian Aquifer ◽  
Dakhla Oasis

<p>We present electrical resistivity models of the crust and upper mantle estimated from 2D inversions of broadband magnetotellurics (MT) data acquired from two profiles in the western desert of Egypt, which can contribute to the understanding of the structural setup of this region. The first profile data are collected from 14 stations along a 250 km profile, in EW direction profile runs along latitude ~25.5°N from Kharga oasis to Dakhla oasis. The second profile comprises 19 stations measured along a 130 km profile in NS direction centered at longitude 28°E and crossing the Farafra. The acquisition for both profiles continued for 1 to 3 days at each station, which allowed for the calculation of impedances for periods from 0.01 sec up to  4096 sec at some sites. The wide frequency band corresponds to a maximal skin depths of up to 150 km that can provide penetration to the top of the asthenosphere. The inversion models display high-conductivity sediments cover at the near surface (<1-2 km), which can be associated with the Nubian aquifer. Along the EW-profile from Kaharge to Dhakla, the crustal basement is overly highly resistive and homogeneous und underlain by a more conductive lithospheric mantle below depths of 30-40 km. Along the N-S profile across Farafra, only the southern portion exhibits a highly resistive crust, whereas beneath Farafra northwards, moderate crustal conductivities are encountered. A comparison has been made between the resultant resistivity models with the 1° tessellated updated crust and lithospheric model of the Earth (LITHO1.0) which was developed by <em>Pasyanos, 2014</em> on the basis of seismic velocity data. The obtained results show a remarkable consistency between the resistivity models and the calculated crustal boundaries. Especially at the Kharga-Dakhla profile a clear matching can be noticed at the upper and lower boundaries of a characteristic anomaly with the Moho and LAB boundaries respectively.</p>

1. The mineral world

2014 ◽  
Author(s):  
David Vaughan
Keyword(s):  
Crystal Structure ◽  
Chemical Composition ◽  
Upper Mantle ◽  
Earth’S Crust ◽  
Crust And Upper Mantle ◽  
Big Ten ◽  
The Earth ◽  
Earth's Crust

Minerals are the fundamental components of the Earth. ‘The mineral world’ describes the fields of mineralogy and crystallography that study them. There are approximately 4,400 known minerals, but the ‘big ten’ minerals that are most abundant in the rocks of the Earth’s crust and Upper Mantle are calcite, quartz, olivines, pyroxenes, amphiboles, muscovite, biotite, orthoclase, albite, and anorthite. The two essential characteristics of any mineral are its chemical composition and its crystal structure. Minerals can be assigned to one of seven crystal classes depending on their elements of symmetry. There is further subdivision into 32 crystal classes. Minerals are classified by chemical composition into mineral groups such as silicates, and carbonates.

scholarly journals Formation of iron hydride and iron carbide from hydrocarbon systems at ultra high thermobaric conditions

2019 ◽  
Vol 64 (9) ◽  
pp. 995-1002
Author(s):  
A. Yu. Serovaiskii ◽  
A. Yu. Kolesnikov ◽  
V. G. Kutcherov
Keyword(s):  
Upper Mantle ◽  
Laser Heating ◽  
Chemical Interaction ◽  
Iron Carbide ◽  
Iron Carbides ◽  
The Earth ◽  
Iron Hydride ◽  
Thermobaric Conditions ◽  
Diamond Anvils ◽  
Iron Bearing

The chemical interaction of hydrocarbon systems and iron-bearing minerals was investigated under extreme thermobaric conditions, corresponding to the Earth upper mantle. As a result of the reaction, the formation of iron carbide and iron hydride was detected. The experiments were carried out in diamond anvils cells with laser heating. Natural petroleum from the Korchaginskoe deposit and a synthetic mixture of paraffin hydrocarbons were used as hydrocarbon systems, and pyroxene-like glass and ferropericlase (57Fe enriched) as iron bearing minerals. The experiments were carried out in the pressure range of 26–95 kbar and temperature range of 1000–1500°C (±100°C). As a result of the experiments, the formation of iron hydride was detected at pressure of 26–69 kbar (corresponds to a depth of 100–200 km), and a mixture of iron carbide and iron hydride at pressure of 75–95 kbar (corresponds to a depth of 210–290 km). The formation of hydrides and iron carbides as a results of the interaction of hydrocarbon systems with iron-bearing minerals may indicate the possible existence of these compounds in the upper mantle.

scholarly journals The response of the local geomagnetic field to geodynamic processes during the preparation of the 1988 Spitak earthquake

2020 ◽  
Author(s):  
А.Г. Григорян ◽  
Д.А. Лиходеев
Keyword(s):  
Electrical Conductivity ◽  
Physical Properties ◽  
Upper Mantle ◽  
Geomagnetic Field ◽  
Power Plants ◽  
External Source ◽  
Crust And Upper Mantle ◽  
Strong Earthquakes ◽  
The Earth ◽  
Geodynamic Processes

Актуальность работы. Изучение изменений локального геомагнитного поля с целью выявления предвестников сильных землетрясений, особенно в сейсмоактивных регионах, где расположены большие города и объекты особо важного значения (АЭС, водохранилище и т.п.) остается одной из главных задач современной науки. В разных странах мира, используя магнитометрические методы, проводятся исследования по поиску предвестников сильных землетрясений. Цель. Однако, за первую половину XX века, несмотря на отдельные попытки ученых Японии и других стран, серьезных результатов достичь не удалось. Установлено, что с развитием геодинамических процессов в земной коре, особенно при подготовке сильных землетрясений, происходят изменения в магнитных свойствах горных пород (электропроводности, диэлектрической и магнитной проницаемости). Геомагнитные вариации, создаваемые внешним источником, несут в себе важную информацию об изменениях в физических свойствах в земной коры и верхней мантии, а так же позволяют оценить эти изменения. Методы. Представлена методика, которая позволяет с помощью изучения вариаций локального геомагнитного поля, создаваемых внешним источником, выявить изменения в электропроводности на разных глубинах земной коры и верхней мантии, связанные с развитием геодинамических процессов. С этой целью использован расчетный параметр N(A), который является отношением амплитуд вариаций геомагнитного поля внешнего происхождения, измеренных синхронно на разных парах станций. Изучены вариации с периодами 1025, 3060 минут и Sq-вариации. Метод применяется в низкоширотных областях Земли, где вариации переменного геомагнитного поля хорошо выделяются. Результаты. Используя предлагаемую методику, на территории Армении были выявлены аномальные изменения локального отклика геомагнитного поля перед Парванийским 1986 г. (М5,4) и Спитакским 1988 г. (М7,0) землетрясениями. Предполагается, что причинами изменений в физических свойств геологической среды в частности электропроводности, являются дегазация Земли и вертикальная фильтрация флюидов в верхние слои земной коры Relevance. The study of local geomagnetic field changes in order to identify harbingers of strong earthquakes, especially in seismically active regions where large cities and especially important objects (nuclear power plants, a storage reservoir, etc.) are located remains one of the main tasks of modern science. In different countries studies are being conducted to search for precursors of strong earthquakes, using magnetometric methods. Aim. However, for the first half of the 20th century, despite some attempts by scientists from Japan and other countries, no serious results were obtained. It has been established that with the progress of geodynamic processes in the earths crust, especially during the preparation of strong earthquakes, changes in the magnetic properties of rocks (electrical conductivity, dielectric and magnetic permeability) occur. However, geomagnetic variations created by an external source carry important information about changes in physical properties, in particular, electrical conductivity in the earths crust to the upper mantle, and make it possible to evaluate these changes. Methods. A technique that allows to identify changes in electrical conductivity at different depths of the earths crust and upper mantle associated with the development of the geodynamic process, using the study of local geomagnetic field variations created by an external source, is presented. For this purpose, parameter N(A), which is the ratio of the amplitudes of variations of the geomagnetic field of external origin, measured synchronously at different pairs of stations, was used. Variations with periods of 10-25, 30-60 minutes and Sq-variations were studied. The method is used in low latitude areas of the Earth, where variations of the variable geomagnetic field stand out well. Results. Anomalous changes in the local geomagnetic field were revealed in Armenia before the Parvania 1986 (M 5.4) and Spitak 1988 (M 7.0) earthquakes, using the proposed methodology. It is assumed that the causes of changes in the physical properties of the geological environment, in particular, electrical conductivity, are most likely to be the degassing of the Earth and the vertical filtration of fluids into the upper layers of the earths crust

scholarly journals Structure of the Earth crust and upper mantle along seismological profile Mezen–Timan–Pechora (MEZTIMPECH)

LITOSFERA ◽  
2020 ◽  
Vol 20 (4) ◽  
pp. 517-527
Author(s):  
V. V. Udoratin
Keyword(s):  
Upper Mantle ◽  
Deep Structure ◽  
Structural Features ◽  
Earth’S Crust ◽  
Seismic Section ◽  
Crust And Upper Mantle ◽  
Research Results ◽  
The Earth ◽  
Geophysical Surveys ◽  
Earth's Crust

Object of study. The article was devoted to investigation of the depth structure of the Earth’s crust and upper mantle along the Mezen–Timan–Pechora seismic profile (MEZTIMPECH), crossing the southern parts of the Mezen syneclise, the Timan ridge and the Pechora syneclise. Total profile length was 525 km. Materials and methods. In the course of writing the article, the data obtained by performing seismic surveys using the earthquake exchange wave method were used. The processing involved seismic data using the methods of deep seismic sounding, reflected waves, a common depth point, a correlated method of refracted waves, and materials from well geophysical surveys. In interpreting the research results, generalizing models of the deep structure of the territory were employed. Research results. As a result of the interpretation of the records of the method of exchange waves of earthquakes and the subsequent mathematical modeling, a geological and geophysical section was constructed to a depth of about 100 km and a number of seismic boundaries were identified. The pivotal boundaries of the exchange were: Ф0 – the surface of the Riphean folded basement, Ф – the surface of the pre-Riphean crystalline basement, M – the surface of Mohorovich, identified with the roof of the upper mantle. Additionally, horizons K1–K4 – in the crust of the Earth, M1, M2 – in the upper mantle were traced. Four regional geoblocks were distinguished in the seismic section, differing in depth of the basement surface, the Moho sectionand the underlying structural features of the consolidated crust: the Kirov-Kazhim aulacogen, the Vychegda depression, the Timan ridge and the Pre-Ural downfold. Conclusions. The results of deep seismic studies reflected regional features of the structure of the Earth’s crust and were the basis for the construction of tectonic models of large geological objects.

Sign in / Sign up

Export Citation Format

Share Document