Navegando por Assunto "Eletrojato equatorial"

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Acesso aberto (Open Access)
Avaliação da influência do eletrojato equatorial na interpretação de dados magnetotelúrico bidimensionais
(Universidade Federal do Pará, 1991-02-19) MOTA, Joaquim Perminio de Oliveira; RIJO, Luiz; http://lattes.cnpq.br/3148365912720676
The magnetotelluric field in equatorial regions violates the plane wave condition due to a strongly concentrated electrical source of current in the ionosphere, called equatorial electrojet. In this thesis, it is analized the magnetotelluric reponses of electrical sources in order to simulates the effects of the equatorial electrojet. There were used two types of sources: an infinite current line and a gaussian distribuition of current density along one the horizontal cartisian coordenates. The apparent resistivities were computed using the Cagniard relationship and compared with the plane wave results. It was also carried out a comparison of the phase of the surface impedance for all three types of sources (plane wave, gaussian electrojet an line source). The differential equation of the models with lateral inhomogeneities were solved by the secundary field technique using the finite element method. The results show that the electrojet has minor influence in the MT responces (apparent resistivity and phase) of shallow geological structure. However, the effect can be very large in the case of deep strutures (more than 5000 m), mainly if their resistivities are larger than 100 Ωm. Therefore, the influence of the equatorial electrojet must be taken in consideration in the interpretation of the magnetotelluric data from sedimentary basins and from crustal studies.
Acesso aberto (Open Access)
Comparação dos efeitos do eletrojato equatorial nos dados magnetotelúricos bi e tridimensionais
(Universidade Federal do Pará, 1995-11-01) PONTES, Altem Nascimento; RIJO, Luiz; http://lattes.cnpq.br/3148365912720676
This work deals with the comparison between the effects of the equatorial electrojet in two and three-dimensional magnetotelluric data. It is composed of two parts: in the first part, which consists in comparing the effects of two-dimensional with three-dimensional models (current line and gaussian electrojet), we determine the dimensions that a three-dimensional structure should have so that the MT response of that structure, in YX and XY polarizations, can be replaced by the MT response of a 2D structure in TE and TM modes, for apparent resistivity and phase. The results show that the dimension of the 3D structure in the main direction must be over 16 times its length in the initial dimension, so that the MT response of that structure in YX polarization can be replaced by the MT response at a 2D structure in TE mode. If the polarization is XY the main dimension must be 26 times the initial dimension. In the second part, which consists in determining the effects of the Onwumechillian equatorial electrojet, we placed the 3D structure at 10 km, 100 km, 300 km, 500 km, 1000 km and 1500 km, from the electrojet. In this way we determine the distance at which the effects of the Onwumechillian equatorial electrojet on the MT soundings are practically negligible. We observe that, for a conductive basement, the equatorial electrojet does not affect the MT soundings if the 3D structure is placed at 1500 km from the source. When the basement is resistive, the electrojet affects the MT soundings even if the structure is at 1500 km away from the source. We verified that the equatorial electrojet affects the MT soundings in frequencies under 10-2Hz, in both resistivity and phase and in both polarizations. We also observed that the galvanic effect is stronger on the YX than on the XY polarization.
Acesso aberto (Open Access)
Influência de estruturas geológicas bidimensionais no campo geoeletromagnético na presença do eletrojato equatorial
(Universidade Federal do Pará, 2005) SILVA, Marcos Welby Correa; RIJO, Luiz; http://lattes.cnpq.br/3148365912720676
The Earth acts as a large magnet, whose field resembles one that is generated by a magnetic dipole. This field presents intensity changes that vary with observation location and the local time. The main part of the geomagnetic field is created within the Earth by electromagnetic processes. Extensive studies showed that there are also contributions from outside the Earth, mainly from solar origin. Among these outside sources there are anomalies of the magnetic field that arise from an diurnal increase of the electric current in a narrow strip located in the ionosphere, with east-west direction, centered above the magnetic equator and denominated Equatorial Electrojet (EEJ). Occasionally these currents present flow reversions, therefore denominated Counter-Electrojet (CEJ). Several authors have been studying the effects of the EEJ on the geomagnetic observations. They are interested in the combined effect of the equatorial electrojet and the 1-D e 2-D conductive geological structure underneath. In these works the 2-D structure is always considered parallel to the electrojet, which is a quite restrictive hypotheses in view to realistic geological situation, in that two-dimensional structures can have any direction in relation to the electrojet. We present in this work the solution of this problem without this restriction. Thus, here we present the geomagnetic fields due to a two-dimensional structure that possess oblique strike in relation to Equatorial Electrojet, through profiles of the electric and magnetic fields, calculated on the surface and forming arbitrary direction to the 2-D conductive heterogeneity. Further, we also evaluate the influence of an arbitrarily oriented two-dimensional structure would cause on the Magnetotelluric data, under the quatorial Electrojet. In the development of this work, we applied the method of finite elements with the EEJ and CEJ as electromagnetic source, that was represented by a sum of gaussians distributions of current density. This source was decomposed in the parallel and the perpendicular directions to the 2-D structure, resulting in the mode TE1 and the coupled mode TE2 and TM, respectively. We solved the coupled mode applying a Fourier Transform in the Maxwell equations and one Inverse Fourier Transform in the transformed-domain solution. According to the numerical experiments on a interpretative model of Parnaíba Basin Conductivity Anomaly, formed by a large 3000 ohm-m body inside a very conductive (1ohm-m) external structure, we conclude that the presence of the CEJ causes an inversion in the anomaly. We also conclude that at high frequencies the components of the electric field present smaller influence of the internal part of the 2-D body than the external part. Otherwise, we observed this behavior in the magnetic field at low frequencies. Varying the frequencies, we saw the effects of the “skin-depth” mainly in the magnetic field. Besides, there are situations where electric field is insensitive to the internal structure of the model for all values of the frequency used. With regard to the angle θh between the strike of the conductive heterogeneity and the EEJ direction, we observe the TM mode naturally when θh is different from 0°. In this case, the TE mode is composed of two components, one decomposition of the EEJ parallel to the heterogeneity and the other perpendicular to it. As consequence, the E and B fields have all their three components. When we analyzed the influence of the angle between the direction of the profile of fields and the strike of the 2-D heterogeneity, we conclude that its variation causes an asymmetry on the anomalies, which give an idea about the profile’s direction. Finally, we conclude that one of the influences that the distance between the center of the electrojet and center of the 2-D structure causes on the fields is related to the reverse currents, because at 500 km from the EEJ’s center, these currents have their maximum intensity. In the MT soundings, we also used the EEJ and CEJ as primary source and we compared our results with the plane wave response. We noted that the components of the geomagnetic field, used to evaluate the impedance, have an influence from the coupling factor between the TE2 and TM modes. Moreover, this influence become greater with decreasing of the frequency and for resistive host. However, the coupling factor do not affects the MT response at frequencies higher than 10-2 Hz. For lower frequencies, about 10-4 Hz, we detect two kinds of pertubations on the MT data with respect to the plane-wave one: the first is due the presence of the 2-D electromagnetic source (EEJ and CEJ) as primary field, which violates the plane wave hypothesis; and the second is caused by the coupled TE and TM modes because additional electric currents arise in the heterogeneity’s direction when it is oblique to EEJ. These efects increase with the resistivity of the environment. In conclusion, the strike of a large conductive 2-D structure relative to the direction of the EEJ or CEJ do have influence on the geomagnetic field. On the other hand, for shallow magnetotelluric studies (frequencies higher than 10-3 Hz) the effect of angle between the strike of the 2-D geological structure and the direction of the EEJ is not so important. However, for litospheric studies (frequencies lower than 10-3 Hz) the coupling between the two modes can not be ignored.
Acesso aberto (Open Access)
Modelagem numérica da influência do eletrojato equatorial em dados magnetotelúricos produzidos por estruturas tridimensionais
(Universidade Federal do Pará, 1993-02-05) GONZÁLEZ CARRASQUILLA, Antonio Abel; RIJO, Luiz; http://lattes.cnpq.br/3148365912720676
South America presents several unique geomagnetic features, one of which is the Equatorial Electrojet, a current system which extends east - west in Northern Brazil, for almost 3500 km. Considering the fact that the influence of the Equatorial Electrojet can be detected at great distances from its central axis, it is important to understand its effects on magnetotelluric exploration in Brazil. In magnetotelluric prospecting, the influence of the equatorial electrojet has been modelled for both one and two - dimensional geological media, employing both analytical and numerical techniques solutions such as finite element and finite difference. Three-dimensional geological media have been modeled by "thin – layers "using a "thin sheet" algorithm. Lines of current, gaussian electrojets and undulatory electrojets have been used as induction sources to simulate the equatorial electrojet in these algorithms. In this thesis the principal objective is to model the effects of the equatorial electrojet on three - dimensional structures commonly found in geophysical prospecting. To accomplish this, we have computed numerical solutions of the integral equation for three - dimensional media using the inductive sources mentioned before. As previous works have indicated, our results also show that the influence of the equatorial electrojet is prominant only for frequencies lower than 10-1 Hz. This influence decreases with distance but is detectable up to as far as 3000 km from the center of the electrojet. Thus, the presence of peaks in the apparent resistivity profiles over a homogeneous half - space indicates that the influence of the electrojet is more noticeable for this kind of medium. These peaks display different amplitudes for each type of simulated electrojet, and the peak locations also change from one electrojet to the other. However, when we use more geologically realistic one - dimensional models such as a stratified media, the effect of the electrojet source diminishes considerably and the results do not vary greatly for the different kinds of electrojet employed in the model. This effect is caused by the electromagnetic energy dissipation due to the presence of stratified conductive layers within the media. Within the 3000 km region, the three - dimensional electromagnetic response can be larger or smaller than the plane wave response, depending on location body, frequency, kind of the electrojet and geology. When the apparent resistivity is larger than the plane wave response, there is a spread between the one and the three-dimensional sounding curves caused by the electrojet, as well as a widening of the profile anomaly caused by the three - dimensional inhomogeneities relative to the one due to a plane wave. When the apparent resistivity is less the two kinds of sources yield anomalies approximately equal as well as a shortening of the profile anomaly. On the other hand, the phase usually shows an inverted way related to the apparent resistivity. This means that when one phase goes up the apparent resistivity goes down, and vice - versa. Similarily at high frequencies, the one and three - dimensional phases are offset, while at low frequencies they are the same, except for the undulating electrojet with undulation factor α = -2 and -3. Our results also show that the geometric characteristics of three-dimensional structures, such as their orientation relative to the direction of the electrojet and the dimensions of their principal direction, change the response due to the electrojet source as compared to a plane wave source. For example, when the three - dimensional structure is rotated 90 degrees, relative to the direction of the electrojet, there is a change in polarization (of the electric and magnetic fields) but there are no changes in the values of apparent resistivity at the center of symmetry of the structure. When the measurements are taken away from the center of symmetry changes in the apparent resistivity are shown when compared with the unrotated structure. This is due to the persistente of the galvanic effects at the center of the structure and the presence of inductive effects at the periphery of the three - dimensional body. When we elongate the principal direction of the three - dimensional structure, the magnetotelluric soundings start to approach those of two-dimensional structures. This is more noticiable in the XY polarization. Even so, the responses of the models tested are still quite different from the responses of the quasi two - dimensional structures. Nevertheless, the effects of the electrojet in structures with elongated principal direction are very similar to those present in smaller structures, considering the differences between the soundings of both kinds of structures. On the other hand, the apparent resistivities of this kind of elongated structures show a great increase at the edges of these structures, both for the plane wave or electrojet sources. This effect is caused by the chanelling of the current along the main direction of the structure. The modelling of gelogical structures in the Marajó Basin, confirms that the effects of the electrojet can be detected even in small horst and graben structures located at great distances from electrojet center. Electrojet effects are noticeable in both one and three - dimensional media for two frequency bands, one near 10-1 Hz and another band, between 10-3 Hz to DC. This possibly reflects the influence of a resistive geological basement and a resistive lower crust, respectively. The results of the analysis, using the electrojet as an inductive source show that at low frequencies the computed responses from the magnetotelluric soundings can be strongly distorted, both by galvanic effects in the three - dimensional structure as well as the presence of the electrojet. Therefore, if the equatorial electrojet effects are not accounted for, a misleading interpretation magnetotelluric data will result. Similarily, a three - dimensional model should be used to interpret the data, instead of one-dimensional Tikhonov-Cagniard model.