Spelling suggestions: "subject:"airglow"" "subject:"airglows""
41 |
Observação da maré lunar nas medidas de luminescência atmosférica equatorial por fotômetro multicanalKushiator, Bismark Abeku Nyamekye 19 May 2017 (has links)
Submitted by Jean Medeiros (jeanletras@uepb.edu.br) on 2017-11-14T13:00:58Z
No. of bitstreams: 1
PDF - Bismark Abeku Nyamekye Kushiator.pdf: 1029542 bytes, checksum: 85fec38cb146fdae2ce891a5cb865616 (MD5) / Made available in DSpace on 2017-11-14T13:00:58Z (GMT). No. of bitstreams: 1
PDF - Bismark Abeku Nyamekye Kushiator.pdf: 1029542 bytes, checksum: 85fec38cb146fdae2ce891a5cb865616 (MD5)
Previous issue date: 2017-05-19 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / Atmospheric airglow measurements obtained by means of a multichannel photometer
in the equatorial region of São João do Cariri, Brazil (7.4 ºS, 36.5 ºO) was
used to identify and characterize variations associated with lunar tide. The solar
time luminescence data of the three emissions; OH (6, 2), O155577 and 𝑂2(0−1)
were smoothed with an average of three months to represent one month in order to
reduce variability. The three emissions were subjected to spectral analysis using
the Lomb-Scargle peridogram to identify the presence of tidal periodicities of each
emission of airglow. The residual from each emission were obtained as a result of
the subtraction of the reconstructed composite day using the components diurna,
semidiurna and terdiuna of the solar tide, for each three months of measurements
were used. This elimination of solar tide signals produced residual emissions of
each data that are converted to lunar time and subjected to harmonic analysis to
obtain the monthly amplitudes and phases of the lunar semidiurnal component
for each of the three emissions. The time series obtained on a composite lunar
day shows the lunar component. From the analysis of the data it was possible to
identify the signature of the semidiurnal lunar tide in each emission throughout
the year of 2004 in the equatorial region. / Medidas da luminescência atmosférica obtidas através de fotômetro multicanal
na região equatorial em São João do Cariri, Brasil (7,4 ºS; 36,5ºO) são usadas
para identificar e caracterizar variações associadas à maré lunar. Os dados de
luminescência de tempo solar das três emissões; OH (6, 2), OI5577 e 𝑂2 (0-
1) foram suavizados com uma média de três meses para representar um mês,
a fim de reduzir a variabilidade. As três emissões foram submetidas a análise
espectral utilizando o peridograma de Lomb-Scargle para identificar a presença
das periodicidades das marés em cada emissão de luminescência. Os resíduos
de cada emissão foram obtidos como resultado da subtração do dia composto
reconstruído utilizando as componentes diurna, semidiurna e terdiuna da maré
solar. Para isto, foram utilizados três meses de medidas. Esta eliminação de
sinais de maré solar produze emissões residuais de cada dado que são convertidas
para o tempo lunar e submetidas a análises harmônicas para obter as amplitudes e
fases mensais da componente semidiurna lunar para cada uma das três emissões.
As séries temporais obtidas em um dia lunar composto mostra o componente
lunar. A partir da análise dos dados foi possível identificar a assinatura da maré
lunar semidiurna em cada emissão ao longo do ano de 2004 na região equatorial.
|
42 |
Investigating UV nightglow within the framework of the JEM-EUSO ExperimentsEmmoth, Frej-Eric January 2020 (has links)
The main mission of the JEM-EUSO (Extreme Universe Space Observatory) Collaborationis to observe Cosmic Rays. These high energy particles come from a variety of sources and bombard the Earth all the time. However, the higher the energy, the lower the flux, and particles with an energy above 1018eV (called Ultra High Energy Cosmic Rays or UHECRs) are so sparse that just a few might hit the atmosphere in a year. When CRs, and UHECRs, hit the atmosphere they cause what is called Extensive Air Showers, EAS, a cascade of secondary particles. This limits the effectiveness of ground based observatories, and that is where theJEM-EUSO Collaboration comes in. The goal is to measure UHECRs, by observing the fluorescence of the EAS from space. This way huge areas of the atmosphere can be covered and both galactic hemispheres can be studied. Since the JEM-EUSO instruments are telescopes measuring in the near UV range, a lot of other phenomena can be observed. One of these applications is UV nightglow. Airglow in general are lights in the sky which are emitted from the atmosphere itself, while nightglow is simply the nighttime airglow. There are many uses of airglow, and one of these is as a medium to observe atmospheric gravity waves. The aim of this thesis is to investigate how a space-based photon counting telescope, such as those of the JEM-EUSO Collaboration, can be used to measure disturbances in the terrestrial nightglow, to identify atmospheric gravity waves. To accomplish this, a theoretical basis for these interactions was explored and a simple scenario was built to explore the plausibility of measuring UV nightglow modulations. The aim was to see what variables would affect a measurement, and how important they were. Along side this, a calibration was conducted on one of the JEM-EUSO Collaborations instruments, the EUSO-TA (EUSO-Telescope Array). The goal in the end was to try and measurethe night sky, to complement the calculations. The investigation showed that the conditions during the measurement are very important to the measurement. This includes things like background intensity, nightglow activity, and magnitude/shape of the modulations. Of more importance though are the parameters which can be actively changed to improve the measurement, the most important of which is measurement time. It was concluded that a measurement of the nightglow modulation should be, under the right conditions, possible to do with a currently operating instrument, the Mini-EUSO, or similar instrument. The calibration of the EUSO-TA involved a series of repairs and tests, which highlighted some strengths and weaknesses of the instrument. However, the calibration itself produced few workable results that in the best case scenario reduced the focal surface to an unevenly biased 2-by-2 Elementary Cell square. Unfortunately this would not be sufficient to do proper measurements with, but the process did point out shortcomings with the then involved sensors, as well as some problematic aspects of the software operating the instrument.
|
43 |
Visible and near-infrared airglow structures in the mesosphere and the lower thermosphere observed by space-borne instruments / 宇宙空間からの観測による中間圏および下部熱圏における可視近赤外域大気光の構造についての研究Akiya, Yusuke 23 March 2015 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18798号 / 理博第4056号 / 新制||理||1583(附属図書館) / 31749 / 京都大学大学院理学研究科地球惑星科学専攻 / (主査)准教授 齊藤 昭則, 教授 田口 聡, 教授 余田 成男 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
|
44 |
The Response of O(1S) and OH Emission Brightness to Gravity Wave PerturbationsZhao, Zhiling 11 October 2001 (has links)
No description available.
|
45 |
The Auroral Large Imaging System : design, operation and scientific resultsBrändström, Urban January 2003 (has links)
The Auroral Large Imaging System (ALIS) was proposed in 1989 by Åke Steen as a joint Scandinavian ground-based nework of automated auroral imaging stations. The primary scientic objective was in the field of auroral physics, but it was soon realised that ALIS could be used in other fields, for example, studies of Polar Stratospheric Clouds (PSC), meteors, as well as other atmospheric phenomena. This report describes the design, operation and scientic results from a Swedish prototype of ALIS consisting of six unmanned remote-controlled stations located in a grid of about 50 km in northern Sweden. Each station is equipped with a sensitive high-resolution (1024 x 1024 pixels) unintensified monochromatic CCDimager. A six-position filter-wheel for narrow-band interference filters facilitates absolute spectroscopic measurements of, for example, auroral and airglow emissions. Overlapping fields-of-view resulting from the station baseline of about 50 km combined with the station field-of-view of 50° to 60°, enable triangulation as well as tomographic methods to be employed for obtaining altitude information of the observed phenomena. ALIS was probably one of the first instruments to take advantage of unintensi- fied (i.e. no image-intensifier) scientific-grade CCDs as detectors for spectroscopic imaging studies with multiple stations of faint phenomena such as aurora, airglow, etc. This makes absolute calibration a task that is as important as it is dificult. Although ALIS was primarily designed for auroral studies, the majority of the scientific results so far have, quite unexpectedly, been obtained from observations of HF pump-enhanced airglow (recently renamed Radio-Induced Aurora). ALIS made the first unambiguous observation of this phenomena at high-latitudes and the first tomography-like inversion of height profiles of the airglow regions. The scientific results so far include tomographic estimates of the auroral electron spectra, coordinated observations with satellite and radar, as well as studies of polar stratospheric clouds. An ALIS imager also participated in a joint project that produced the first ground-based daytime auroral images. Recently ALIS made spectroscopic observations of a Leonid meteor-trail and preliminary analysis indicates the possible detection of water in the Leonid.
|
46 |
Automated Detection and Analysis of Low Latitude Nightside Equatorial Plasma BubblesAdkins, Vincent James 21 June 2024 (has links)
Equatorial plasma bubbles (EPBs) are large structures consisting of depleted plasma that generally form on the nightside of Earth's ionosphere along magnetic field lines in the upper thermosphere/ionosphere.
While referred to as `bubbles', EPBs tend to be longer along magnetic latitudes and narrower along magnetic longitudes which are on the order of thousands and hundreds of kilometers, respectively.
EPBs are a well documented occurrence with observations spanning many decades.
As such, much is known about their general behavior, seasonal variation of occurrences, increasing/decreasing occurrences with increasing/decreasing solar activity, and their ability to interact and interfere with radio waves such as GPS.
This dissertation expands on this understanding by focusing on the detection and tracking of EPBs in the upper thermosphere/ionosphere along equatorial to low latitudes.
To do this, far ultraviolet (FUV) emission observations of the recombination of O$^+$ with electrons via the Global-Scale Observations of the Limb and Disk (GOLD) mission are analyzed.
GOLD provides consistent data from geostationary orbit with the eastern region of the Americas, Atlantic, and western Africa.
The optical data can be used to pick out gradients in brightness along the 135.6 nm wavelength which correlate with the location of EPBs in the nightside ionosphere.
The dissertation provides a novel method to look at and analyze 2-dimensional data with inconsistent time-steps for EPB detection and tracking.
During development, preprocessing of large scale (multiple years) data proved to be the largest time sync.
To that end, this dissertation tests the possibility of using convolution neural networks for detection of EPBs with the end goal of reducing the amount of preprocessing necessary.
Further, data from the Ionospheric Connection Explorer's (ICON's) ion velocity meter (IVM) are compared to EPBs detected via GOLD to understand how the ambient plasma around the EPBs behave.
Along with the ambient plasma, zonal and meridional thermospheric winds observed by ICON's Michelson Interferometer for Global High-resolution Thermospheric Imaging (MIGHTI) instrument are analyzed in conjunction with the same EPBs to understand how winds coincident with EPBs behave.
An analysis of winds before EPBs form is also done to observe the potential for both zonal and meridional winds' ability to suppress and amplify EPB formation. / Doctor of Philosophy / Equatorial plasma bubbles (EPBs) are large structures that generally form during post- sunset along Earth's magnetic equator.
While referred to as `bubbles', EPBs tend to be thousands of kilometers from north to south and hundreds of kilometers from east to west and well over a thousands kilometers in altitude.
EPBs are a well documented occurrence with observations spanning many decades.
This includes their ability to interfere with radar and GPS.
This dissertation expands on the scientific community's understanding by focusing on the detection and tracking of EPBs along the magnetic equator.
To do this, observations from the NASA Global-Scale Observations of the Limb and Disk (GOLD) mission are analyzed.
GOLD provides consistent observations looking over the eastern region of the Americas, Atlantic, and western Africa.
A unique method to look at and analyze this data for EPB detection and tracking is developed.
This dissertation also tests the possibility of using machine learning for detection of EPBs.
Further, data from the NASA Ionospheric Connection Explorer (ICON) mission is compared to EPBs detected via GOLD to understand how the behavior of the upper atmosphere and the conductive region therein, known as the ionosphere, interact with the EBPs themselves.
|
47 |
Analysis of Particle Precipitation and Development of the Atmospheric Ionization Module OSnabrück - AIMOSWissing, Jan Maik 31 August 2011 (has links)
The goal of this thesis is to improve our knowledge on energetic particle precipitation into the Earth’s atmosphere from the thermosphere to the surface. The particles origin from the Sun or from temporarily trapped populations inside the magnetosphere.
The best documented influence of solar (high-) energetic particles on the atmosphere is the Ozone depletion in high latitudes, attributed to the generation of HOx and NOx by precipitating particles (Crutzen et al., 1975; Solomon et al., 1981; Reid et al., 1991). In addition Callis et al. (1996b, 2001) and Randall et al. (2005, 2006) point out the importance of low-energetic precipitating particles of magnetospheric origin, creating NOx in the lower thermosphere, which may be transported downwards where it also contributes to Ozone depletion.
The incoming particle flux is dramatically changing as a function of auroral/geomagnetical activity and in particular during solar particle events. As a result, the degree of ionization and the chemical composition of the atmosphere are substantially affected by the state of the Sun. Therefore the direct energetic or dynamical influences of ions on the upper atmosphere depend on solar variability at different time scales.
Influences on chemistry have been considered so far with simplified precipitation patterns, limited energy range and restrictions to certain particle species, see e.g. Jackman et al. (2000); Sinnhuber et al. (2003b, for solar energetic protons and no spatial differentiation), and Callis et al. (1996b, 2001, for magnetospheric electrons only). A comprehensive atmospheric ionization model with spatially resolved particle precipitation including a wide energy range and all main particle species as well as a dynamic magnetosphere was missing.
In the scope of this work, a 3-D precipitation model of solar and magnetospheric particles has been developed. Temporal as well as spatial ionization patterns will be discussed. Apart from that, the ionization data are used in different climate models, allowing (a) simulations of NOx and HOx formation and transport, (b) comparisons to incoherent scatter radar measurements and (c) inter-comparison of the chemistry part in different models and comparison of model results to MIPAS observations. In a bigger scope the ionization data may be used to better constrain the natural sources of climate change or consequences for atmospheric dynamics due to local temperature changes by precipitating particles and
their implications for chemistry. Thus the influence of precipitating energetic particles on the composition and dynamics of the atmosphere is a challenging issue in climate modeling. The ionization data is available online and can be adopted automatically to any user specific model grid.
|
Page generated in 0.0372 seconds