Spelling suggestions: "subject:"ionospheric disturbances"" "subject:"ionospheric isturbances""
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Properties of traveling ionospheric disturbances (TIDs) over the Western Cape, South AfricaTyalimpi, Vumile Mike January 2015 (has links)
Travelling Ionospheric Disturbances (TIDs) are said to be produced by atmospheric gravitational waves propagating through the neutral ionosphere. These are smaller in amplitude and period when compared to most ionospheric disturbances and hence more difficult to measure. Very little is known about the properties of the travelling ionospheric disturbances (TIDs) over the Southern Hemisphere regions since studies have been conducted mostly over the Northern Hemisphere regions. This study presents a framework, using a High Frequency (HF) Doppler radar to investigate the physical properties and the possible driving mechanisms of TIDs. This research focuses on studying the characteristics of the TIDs, such as period, velocity and temporal variations, using HF Doppler measurements taken in South Africa. By making use of a Wavelet Analysis technique, the TIDs’ characteristics were determined. A statistical summary on speed and direction of propagation of the observed TIDs was performed. The winter medium scale travelling ionospheric disturbances (MSTIDs) observed are generally faster than the summer MSTIDs. For all seasons, the MSTIDs had a preferred south-southwest direction of propagation. Most of the large scale travelling ionospheric disturbances (LSTIDs) were observed during the night and of these, the spring LSTIDs were fastest when compared to autumn and summer LSTIDs. The general direction of travel of the observed LSTIDs is south-southeast. Total Electron Content (TEC), derived from Global Positioning System (GPS) measurements, were used to validate some of the TID results obtained from the HF Doppler data. The Horizontal Wind Model (HWM07), magnetic K index, and solar terminators were used to determine the possible sources of the observed TIDs. Only 41% of the observed TIDs were successfully linked to their possible sources of excitation. The information gathered from this study will be valuable in future radio communications and will serve as means to improve the existing ionospheric models over the South African region.
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Multi-instrument observations of ionospheric irregularities over South AfricaAmabayo, Emirant Bertillas January 2012 (has links)
The occurrence of mid-latitude spread F (SF) over South Africa has not been extensively studied since the installation of the DPS-4 digisondes at Madimbo (30.88◦E, 22.38◦S), Grahamstown (33.32◦S, 26.50◦E) and Louisvale (28.51◦S, 21.24◦E). This study is intended to quantify the probability of the occurrence of F region disturbances associated with ionospheric spread F (SF) and L-band scintillation over South Africa. This study used available ionosonde data for 8 years (2000-2008) from the three South African stations. The SF events were identified manually on ionograms and grouped for further statistical analysis into frequency SF (FSF), range SF (RSF) and mixed SF (MSF). The results show that the diurnal pattern of SF occurrence peaks strongly between 23:00 and 00:00 UT. This pattern is true for all seasons and types of SF at Madimbo and Grahamstown during 2001 and 2005, except for RSF which had peaks during autumn and spring during 2001 at Madimbo. The probability of both MSF and FSF tends to increase with decreasing sunspot number (SSN), with a peak in 2005 (a moderate solar activity period). The seasonal peaks of MSF and FSF are more frequent during winter months at both Madimbo and Grahamstown. In this study SF was evident in ∼ 0.03% and ∼ 0.06% of the available ionograms at Madimbo and Grahamstown respectively during the eight year period. The presence of ionospheric irregularities associated with SF and scintillation was investigated using data from selected Global Positioning System (GPS) receiver stations distributed across South Africa. The results, based on GPS total electron content (TEC) and ionosonde measurements, show that SF over this region can most likely be attributed to travelling ionospheric disturbances (TIDs), caused by gravity waves (GWs) and neutral wind composition changes. The GWs were mostly associated with geomagnetic storms and sub-storms that occurred during periods of high and moderate solar activity (2001-2005). SF occurrence during the low solar activity period (2006-2008)can probably be attributed to neutral wind composition changes.
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Statistical analysis of ionospheric total electron contentKatamzi, Zama January 2011 (has links)
Certain modern radio systems that rely on trans-ionospheric propagation require knowledge of changes in total electron content (TEC). Understanding rapidly changing, small amplitude perturbations in the ionosphere is important in order to quantify the accuracy of those systems. The main aim of this thesis is to collect statistical information on the perturbations and wave structures present in the ionosphere, for use in radio astronomy calibrations and future communication systems planning. To gain this information, TEC calculated from instruments measuring Faraday rotation on signals from geostationary satellites were used. These measurements were collected in Italy over the period of 19751982 and 1989-1991 at one minute intervals. An important class of TEC fluctuations is travelling ionospheric disturbances (TIDs). Here, temporal variations of mid-latitude slant TEC measurements during two solar cycle phases, i.e solar minimum in 1975-1976 and solar maximum in 1989-1990, were studied. Direct inspection of Savitzky-Golay filtered TEC data was used to extract the amplitudes of TIDs. Fourier analysis was used to extract the most dominant periods of the TIDs. Discrete Meyer wavelet together with the ANOVA method to determine TID variation changes in different parts of the day. Another class of TEC fluctuations presented in this thesis is diurnal double maxima (DDM) structures. These structures were observed during mid-day in our TEC measurements between 1975 and 1991. Verification of the DDM observations was sought by using foF2 and hmF2 measurements from an ionosonde in RomeA combination of ionospheric 3-D tomographic imaging and ray propagation theory has been used for the first time to demonstrate a method that can show how the new European radio array LOFAR will be affected by the ionosphere. This was achieved from a case study of a geomagnetic quiet day ionosphere by simulating how ray propagations, at different elevations and frequencies, will behave as they traverse the ionosphere. The important result from this study was that continuous monitoring of the telescope will be important during operation of the array if the errors introduced by the ionosphere are to be accurately corrected for. The study of TEC changes over different short time windows demonstrated that the ionosphere vastly varies over short time scales, thus making the monitory non trivial. Statistical analysis of the TEC changes will also be useful to the new European GPS augmentation system EGNOS as an indicator on whether the ionospheric measurements from the system are realistic.
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Dynamics of Equatorial Spread <i>F</i> Using Ground-Based Optical and Radar MeasurementsChapagain, Narayan P. 01 May 2011 (has links)
The Earth's equatorial ionosphere most often shows the occurrence of large plasma density and velocity fluctuations with a broad range of scale sizes and amplitudes. These night time ionospheric irregularities in the F-region are commonly referred to as equatorial spread F (ESF) or plasma bubbles (EPBs). This dissertation focuses on analysis of ground-based optical and radar measurements to investigate the development and dynamics of ESF, which can significantly disrupt radio communication and GPS navigation systems. OI (630.0 nm) airglow image data were obtained by the Utah State University all-sky CCD camera, primarily during the equinox period, from three different longitudinal sectors under similar solar flux conditions: Christmas Island in the Central Pacific Ocean, Ascension Island in South Atlantic, and Brasilia and Cariri in Brazil. Well-defined magnetic field-aligned depletions were observed from each of these sites enabling detailed measurements of their morphology and dynamics. These data have also been used to investigate day-to-day and longitudinal variations in the evolution and distribution of the plasma bubbles, and their nocturnal zonal drift velocities. In particular, comparative optical measurements at different longitudinal sectors illustrated interesting findings. During the post midnight period, the data from Christmas Island consistently showed nearly constant eastward bubble velocity at a much higher value (~80 m/s) than expected, while data from Ascension Island exhibited a most unusual shear motion of the bubble structure, up to 55 m/s, on one occasion with westward drift at low latitude and eastward at higher latitudes, evident within the field of view of the camera.
In addition, long-term radar observations during 1996-2006 from Jicamarca, Peru have been used to study the climatology of post-sunset ESF irregularities. Results showed that the spread F onset times did not change much with solar flux and that their onset heights increased linearly from solar minimum to solar maximum. On average, radar plume onset occurred earlier with increasing solar flux, and plume onset and peak altitudes increased with solar activity. The F-region upward drift velocities that precede spread F onset increased from solar minimum to solar maximum, and were approximately proportional to the maximum prereversal drift peak velocities.
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Comportamiento característico de la estructura vertical de la ionosfera en condiciones de calma y perturbadasBlanch Llosa, Estefania 23 December 2009 (has links)
Aquesta investigació s'ha centrat en profunditzar en el coneixement del comportament de l'estructura vertical de la regió F de la ionosfera, tant en condicions de calma com pertorbades, i en la seva modelització mitjançant funcions analítiques. Les pretensions d'aquesta investigació han estat motivades per les discrepàncies existents entre les prediccions ionosfèriques del gruix i la forma del perfil de densitat de la regió F en condicions de calma i la seva variació característica, i per l'absència d'un model capaç de reproduir la resposta de l'altura del màxim de ionització en condiciones pertorbades. En aquesta investigació s'ha determinat el comportament patró del gruix i la forma del perfil de densitat electrònica de la regió F en condicions de calma (determinats pels paràmetres B0 i B1 del model Internacional de Referència de la Ionosfera, IRI) en un ampli rang de longituds i latituds. Amb això, s'ha desenvolupat un model global per a cada paràmetre mitjançant una formulació analítica simple que simula les variacions temporals d'aquests en condiciones de calma. La simulació d'aquests models millora (en termes de l'error quadràtic mig, RMSE) les prediccions de l'IRI en un 40% per a B0 i en un 20% per a B1. També s'ha caracteritzat la reacció de l'altura del màxim de ionització, hmF2, a latituds mitges i condicions magnèticament pertorbades, i s'ha determinat un comportament sistemàtic d'aquesta pertorbació, ∆hmF2, la morfologia de la qual depèn del camp magnètic interplanetari (IMF), del temps local, de l'estació de l'any i la latitud. Amb això, s'ha desenvolupat un model empíric que simula la pertorbació d'hmF2 resultant durant tempestes geomagnètiques intenses mitjançant funcions analítiques. Aquest model prediu els esdeveniments d'∆hmF2 amb un 86 % d'encert sense generar falses alarmes i amb un RMSE de 40 km respecte els valors experimentals, que és equivalent al rang de variació experimental obtingut en condicions de calma. Finalment, destacar que també han estat objecte d'estudi en aquesta investigació els mecanismes responsables del comportament ionosfèric tant en condiciones de calma com pertorbades i, especialment, el model de tempesta basat en el paper rector de la circulació del vent neutre termosfèric. / Esta investigación se ha centrado en profundizar en el conocimiento del comportamiento de la estructura vertical de la región F de la ionosfera, tanto en condiciones de calma como perturbadas, y en su modelado mediante funciones analíticas. Las pretensiones de esta investigación han estado motivadas por las discrepancias existentes entre las predicciones ionosféricas del espesor y la forma del perfil de densidad de la región F en condiciones de calma y su variación característica, y por la ausencia de un modelo capaz de reproducir la respuesta de la altura del máximo de ionización a condiciones perturbadas. En esta investigación se ha determinado el comportamiento patrón del espesor y la forma del perfil de densidad electrónica de la región F en condiciones de calma (determinados por los parámetros B0 y B1 del modelo Internacional de Referencia de la Ionosfera, IRI) en un amplio rango de longitudes y latitudes. Con esto, se ha desarrollado un modelo global para cada parámetro mediante una formulación analítica simple que simula las variaciones temporales de éstos en condiciones de calma. La simulación de estos modelos mejora (en términos del error cuadrático medio, RMSE) las predicciones del IRI en un 40% para B0 y en un 20% para B1. También se ha caracterizado la reacción de la altura del máximo de ionización, hmF2, en latitudes medias y condiciones magnéticamente perturbadas, y se ha determinado un comportamiento sistemático de dicha perturbación, ∆hmF2, cuya morfología depende del campo magnético interplanetario (IMF), del tiempo local, de la estación del año y de la latitud. Con ello, se ha desarrollado un modelo empírico que simula la perturbación en hmF2 resultante durante tormentas geomagnéticas intensas mediante funciones analíticas. Este modelo predice los eventos de ∆hmF2 con un 86% de acierto sin generar falsas alarmas y con un RMSE de 40 km respecto a los valores experimentales, que es equivalente al rango de variación experimental obtenido en condiciones de calma. Finalmente, resaltar que también han sido objeto de estudio en esta investigación los mecanismos responsables del comportamiento ionosférico tanto en condiciones de calma como perturbadas y, especialmente, el modelo de tormenta basado en el papel rector de la circulación del viento neutro termosférico. / The main objective of this research is to improve the knowledge on the vertical structure of the ionospheric F region during both, quiet and disturbed conditions, and its modelling by analytical functions. The main motivations of this research were the existing discrepancies between the predictions of the F region electron density profile thickness and shape during quiet conditions and their characteristic variation, and the absence of a model capable to reproduce the electron density peak height response to disturbed conditions. In this research, the pattern behaviour for quiet conditions of the F region electron density profile thickness and shape (determined by the International Reference Ionosphere model (IRI) parameters B0 and B1) was determined in a wide range of longitudes and latitudes. Then, a global model was developed for each parameter using a simple analytical formulation that simulates their temporal variations during quiet conditions. These model simulations improve (in terms of the root mean square error, RMSE) the IRI predictions by 40 % for B0 and by 20 % for B1. The reaction of the electron density peak height, hmF2, at mid latitudes and magnetically disturbed conditions, was also characterized and the systematic behaviour of this disturbance, ∆hmF2, was determined. The morphology of this disturbance depends on the interplanetary magnetic field (IMF), local time, season and latitude. Furthermore, an empirical model was developed to simulate the hmF2 disturbance during intense geomagnetic storms using analytical functions. This model predicts the ∆hmF2 events with a success of 86 % without generating false alarms and with a RMSE of 40 km with respect to the experimental values, which is equivalent to the experimental variation range obtained during quiet conditions. Finally, the mechanisms responsible of the ionospheric behaviour during both, quiet and disturbed conditions, were also studied in this research, specially the storm model based on the leading role of the thermospheric neutral wind circulation.
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System Identification With Particular Interest On The High Frequency Radar Under Ionospheric DisturbancesBuyukpapuscu, Suleyman Olcay 01 February 2007 (has links) (PDF)
We have been actively involved in the research and management activities of European Co-Operation in the Field of Scientific and Technical Research (EU COST) actions such as COST 238 Prediction and Retrospective Ionospheric Modeling over Europe (PRIME), COST 251 Improved Quality of Service in Ionospheric Telecommunication System Planning and Operation, COST 271 Effects of the Upper Atmosphere on Terrestrial and Earth-Space Communications, COST 296 Mitigation of Ionospheric Effects on Radio Systems (MIERS) and COST 724 Developing the Scientific Basis for Monitoring, Modeling and Predicting Space Weather.
In this thesis High Frequency (3-30 MHz) (HF) radar system under ionospheric disturbances has been identified globally and some operational suggestions have been presented. The use of HF radar system is considered from the identification of ionospheric propagation medium point of view. Doppler velocity is considered as the characteristic parameter of the propagation medium. ap index is chosen as the parameter for disturbance characterization due to geomagnetic storms in the ionosphere.
The main difficulty is the scarcity of data, which is rare and confidential. Therefore semi-synthetic data are generated.
Dependence of Doppler velocity and group range of the echo signal on ap index is examined and some details of dependence are studied and demonstrated.
Thus, effects of space weather on the ionosphere and as a result on HF radar wave propagation are displayed. These results are examples of system identification. This can be used in communication system planning and operation.
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Investigation of Polar Mesosphere Summer Echoes in Northern ScandinaviaBarabash, Victoria January 2003 (has links)
<p>This PhD thesis deals with phenomena which are closely related to the unique thermal structure of the polar summer mesosphere, namely Polar Mesosphere Summer Echoes (PMSE). PMSE are strong radar echoes commonly observed by VHF MST radars from thin layers in the 80-90 km altitude interval at high latitudes during summer. They follow a seasonal pattern of abrupt appearance in late May and a gradual disappearance in mid-August. This period corresponds roughly to the time between the completion of the summer time cooling of the polar mesopause to the time of reversal of the mesospheric circulation to autumn condition. In this connection, PMSE are associated with the extremely low temperatures, i.e. below 140 K, which are unique to the polar summer mesopause. Traditional theories of radar (partial) reflection and scattering have been unable to explain the PMSE and the exact mechanism for their occurrence remains unclear despite the steadily increasing interest in them over the past 20 years. Currently accepted theories regarding the mechanism giving rise to PMSE agree that one of the conditions needed for enhanced radar echoes is the presence of low-mobility charge carries such as large cluster ions and ice aerosols which capture the ambient electrons. It has been established that the PMSE are in some way associated with noctilucent clouds (NLC), layers of ice crystals, which constitute the highest observed clouds in the earth’s atmosphere. PMSE occurrence and dynamics are also found to be closely connected with the planetary and gravity waves.</p><p>Observations of PMSE presented in this thesis have been carried out by the Esrange MST radar (ESRAD) located at Esrange (67°56’N, 21°04’E) just outside Kiruna in northernmost Sweden. The radar operates at 52 MHz with 72 kW peak power and a maximum duty cycle of 5%. The antenna consists of 12x12 array of 5-element Yagis with a 0.7l spacing. During the PMSE measurements the radar used a 16-bit complementary code having a baud length of 1mS. This corresponds to height resolution of 150 m. The sampling frequency was set at 1450 Hz. The covered height range was 80-90 km. The presence of PMSE was determined on the basis of the radar SNR (signal-to-noise ratio). The PMSE measurements have been made during May-August each year since 1997.</p><p>PMSE seasonal and diurnal occurrence rates as well as dynamics have been studied in connection with tidal winds, planetary waves, temperature and water vapor content in the mesosphere (Papers I, IV and VI). Simultaneous and common-volume observations of PMSE and noctilucent clouds have been performed by radar, lidar and CCD camera (Paper V). Correlation between variations in PMSE and variations in extra ionization added by precipitating energetic electrons or high-energy particles from the Sun has been examined (Papers II and III). Possible influence of transport effects due to the electric field on PMSE appearance has been studied during a solar proton event (Paper III).</p>
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Investigation of Polar Mesosphere Summer Echoes in Northern ScandinaviaBarabash, Victoria January 2003 (has links)
This PhD thesis deals with phenomena which are closely related to the unique thermal structure of the polar summer mesosphere, namely Polar Mesosphere Summer Echoes (PMSE). PMSE are strong radar echoes commonly observed by VHF MST radars from thin layers in the 80-90 km altitude interval at high latitudes during summer. They follow a seasonal pattern of abrupt appearance in late May and a gradual disappearance in mid-August. This period corresponds roughly to the time between the completion of the summer time cooling of the polar mesopause to the time of reversal of the mesospheric circulation to autumn condition. In this connection, PMSE are associated with the extremely low temperatures, i.e. below 140 K, which are unique to the polar summer mesopause. Traditional theories of radar (partial) reflection and scattering have been unable to explain the PMSE and the exact mechanism for their occurrence remains unclear despite the steadily increasing interest in them over the past 20 years. Currently accepted theories regarding the mechanism giving rise to PMSE agree that one of the conditions needed for enhanced radar echoes is the presence of low-mobility charge carries such as large cluster ions and ice aerosols which capture the ambient electrons. It has been established that the PMSE are in some way associated with noctilucent clouds (NLC), layers of ice crystals, which constitute the highest observed clouds in the earth’s atmosphere. PMSE occurrence and dynamics are also found to be closely connected with the planetary and gravity waves. Observations of PMSE presented in this thesis have been carried out by the Esrange MST radar (ESRAD) located at Esrange (67°56’N, 21°04’E) just outside Kiruna in northernmost Sweden. The radar operates at 52 MHz with 72 kW peak power and a maximum duty cycle of 5%. The antenna consists of 12x12 array of 5-element Yagis with a 0.7l spacing. During the PMSE measurements the radar used a 16-bit complementary code having a baud length of 1mS. This corresponds to height resolution of 150 m. The sampling frequency was set at 1450 Hz. The covered height range was 80-90 km. The presence of PMSE was determined on the basis of the radar SNR (signal-to-noise ratio). The PMSE measurements have been made during May-August each year since 1997. PMSE seasonal and diurnal occurrence rates as well as dynamics have been studied in connection with tidal winds, planetary waves, temperature and water vapor content in the mesosphere (Papers I, IV and VI). Simultaneous and common-volume observations of PMSE and noctilucent clouds have been performed by radar, lidar and CCD camera (Paper V). Correlation between variations in PMSE and variations in extra ionization added by precipitating energetic electrons or high-energy particles from the Sun has been examined (Papers II and III). Possible influence of transport effects due to the electric field on PMSE appearance has been studied during a solar proton event (Paper III).
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A New Approach For The Assessment Of Hf Channel Availability Under Ionospheric DisturbancesSari, Murat Ozgur 01 September 2006 (has links) (PDF)
High Frequency (3-30 MHz) (HF) Ionospheric Channel is used for military, civilian and amateur communications. By using Ionosphere, communication for distances beyond the line of sight is achieved. The main advantage of this type of communication is that it does not to require a satellite to communicate with a point beyond the line of sight. Actually the Ionosphere is used instead of a satellite. To use Ionosphere but not a satellite means independent communication for a country.
The disadvantage of HF Ionospheric Communication is that the characteristics of the reflecting media (i.e. channel&rsquo / s transfer function) depends on many variables, e.g. sun spot number, hour of the day, season, solar cycles etc., so that mathematically modeling the channel is very difficult.
Since military standards like STANAG 4538, STANAG 4285, STANAG 4415, MIL-STD-188-110A and MIL-STD-188-141A define the required performance of an HF modem in terms of Signal to Noise Ratio (SNR), Doppler Spread and Delay Spread according to desired conditions, a new approach to characterize the channel in terms of these three parameters is presented.
In this thesis, HF Channel is considered as a system which involves various physical and chemical processes. A new method to characterize the HF channel to be used for modem performance evaluation is presented.
In this study, it is aimed to relate modem/channel availability with the magnetic indices, which may be considered as the disturbances to the system. For this purpose the data taken from an HF communication experiment is used to model the channel to be used for modem availability calculations.
The aim of the study is to asses the HF Channel Availability under Ionospheric Disturbances.
This new technique will be a useful tool for HF Modem operators to select the optimum data rate or modulation method during HF Communication.
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Contribuição ao estudo de distúrbios ionosféricos utilizando a técnica de VLFCruz, Edith Liliana Macotela 09 March 2015 (has links)
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Previous issue date: 2015-03-09 / Conselho Nacional de Desenvolvimento Científico e Tecnológico / The Earth-Low ionosphere system behaves as a waveguide for the propagation of radio waves of very low frequency (VLF). If in this system the electrical conductivity of its boundaries is perturbed, the propagation of the VLF waves will also be perturbed. There is a diversity of transient physical phenomena that are able to alter significantly the electrical conductivity of the lower ionosphere. The disturbance in this region is able to produce phase and amplitude variations with respect to a quiescent level of these waves. The aim of the present work is to study the response of the lower ionosphere to phenomena originated in the Earth, our solar system or even much farther away. For this purpose, VLF data obtained by SAVNET (South American VLF Network) during the solar cycle 24 was used. It was found that the correction by both the length of the path illuminated by the flare and the reference height coefficient allows normalizing the effect of ionospheric disturbances observed in the VLF phase signals that propagated along trajectories with a north-south or west-east direction, separately. The lower limit of detection for disturbances caused by the X-ray radiation excess is 1.8×10−9 Jm-2 and 2.6×10−7 Jm-2 for the nighttime and daytime lower ionosphere, respectively. Changes in the periodicities of the VLF signal, in the infrasonic band, were observed between 6 and 14 days prior to the seismic events, of magnitude 7, occurred in Haiti in 2010 and in Peru in 2011. Increases in the periodicities of the order of few minutes were observed when the shadow of the total solar eclipse of 2010 was moving on the Earth. Due to the solar eclipse the ionospheric reference height increased in ~3 km and the electron density decreased in 60 % of its quiescent level. Finally, it was found that the effective recombination coefficient, for 80 km height, was 1.1×10−5 cm-3s-1 during the time of the eclipse, which is an intermediate value between the diurnal and nocturnal conditions. / O sistema Terra-baixa ionosfera se comporta como um guia de onda para a propagação de ondas de rádio de frequências muito baixa (VLF). Se neste sistema a condutividade elétrica das fronteiras é perturbada, a propagação da onda é também perturbada. Existe uma variedade de fenômenos físicos transientes que alteram significativamente a condutividade elétrica da baixa ionosfera. Essas alterações são observadas como variações da fase e/ou amplitude com respeito ao nível quiescente. O presente trabalho tem como finalidade estudar a resposta da baixa ionosfera a fenômenos que produzidos na Terra, no sistema solar e até aqueles produzidos muito além do sistema solar. Com esse fim foram utilizados dados de VLF de fase e de amplitude fornecidos pela rede SAVNET (South America VLF NETwork) para o ciclo solar 24. Foi encontrado que a correção pelo fator de distância iluminada e o coeficiente de altura de referência permitem normalizar o efeito do distúrbio ionosférico a partir do sinal de VLF propagado em trajetos com direção de propagação norte-sul ou oeste-leste. O limiar de detecção das perturbações causadas pelo excesso na incidência dos raios-X é 1,8×10−9 Jm-2 para a ionosfera noturna e 2,6×10−7 Jm-2 para a ionosfera diurna. Perturbações ionosféricas observadas como alterações nos períodos do sinal de VLF, na faixa de infrassom, foram observadas entre 6 e 14 dias antes dos eventos sísmicos de magnitude 7 acontecidos no Haiti no ano 2010 e no Peru no ano 2011. Alterações nas periodicidades, da ordem de dezenas de minutos, foram observadas quando a sombra do eclipse solar total de 2010 se deslocava sobre a Terra. Devido ao eclipse, a altura de referência da ionosfera aumentou em ~3 km e a densidade eletrônica diminuiu em 60% com respeito do nível quiescente. Finalmente, foi encontrado que o coeficiente de recombinação efetiva, para o tempo do eclipse e para uma altura de 80 km, foi de 1,1×10−5 cm-3s-1, que é um valor intermediário entre as condições diurnas e noturnas.
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