Global ETD Search

71	The Atmospheric Gravity Wave Transfer Function above Scott Base Geldenhuis, Andre January 2008 (has links) Gravity waves have a significant dynamic effect in the mesosphere. In particular, they drive the mesospheric circulation and are the reason that the summer polar mesosphere is cooler than the winter polar mesosphere. This thesis examines whether the effects of gravity waves are largely determined by filtering effects which allow only gravity waves with certain properties to propagate into the atmosphere. The filtering of gravity waves above Scott Base, Antarctica is examined using a radiosonde derived gravity wave source function, an MF-radar derived mesospheric gravity wave climatology, and a model derived filtering function. Least squares fitting of the source function and filtering function to the observed mesospheric gravity wave climatology allows us to determine which gravity wave phase velocities and propagation direction are likely to be present in the mesosphere and the relative importance of filtering and sources in this region. It is concluded the blocking of eastward gravity waves is important in winter and westward waves in summer. Gravity waves buoyancy waves Antarctica Scott Base Mesosphere wave blocking wave filtering MF-radar radiosonde wave propagation
72	Gravity waves and vertical shear of zonal wind in the summer mesosphere-lower thermosphere Jacobi, Christoph, Ern, Manfred 29 September 2017 (has links) Gravity wave amplitudes and momentum fluxes derived from SABER temperature measurements are analysed together with Collm meteor radar zonal winds. The momentum flux (MF) divergence derived from the SABER temperatures shows a maximum that is found at greater altitudes during solar minimum than during solar maximum. Therefore, the zonal mean wind and wind shear profiles are shifted upwards then, leading to a modulation of the otherwise negative correlation between solar cycle and mesosphere/lower thermosphere winds. / Amplituden von Schwerewellen und zugehörigen Impulsflüsse werden zusammen mit Windmessungen des Meteorradars Collm analysiert. Die Impulsflussdivergenz, abgeleitet aus SABER-Temperaturprofilen, hat ein Maximum welches im solaren Minimum nach oben verschoben ist. Dadurch werden auch die Vertikalprofile des Zonalwindes und der Windscherung nach oben verschoben, wodurch die ansonsten negative Sonnenfleckenzyklusabhängigkeit des zonalen Windes in der Mesosphäre/unteren Thermosphäre im solaren Minimum umgekehrt wird. info:eu-repo/classification/ddc/551 ddc:551
73	Die Entwicklung des Arbeitsgebietes Physik der Hochatmosphäre am Geophysikalischen Observatorium Collm Schminder, Rudolf 24 October 2016 (has links) Am Geophysikalischen Observatorium Collm, das 1932 als experimentelle Basis des Geophysikalischen Institutes der Universität Leipzig für meteorologische, seismologische und geomagnetische Messungen von Professor LUDWIG WEICKMANN errichtet worden war, wurde 1956 in Vorbereitung des Internationalen Geophysikalischen Jahres (International Geophysical Year [IGY]) mit hochattnosphärischen Messungen begonnen. Seit 1959 liegt der Schwerpunkt auf Windmessungen im Höhenbereich der oberen Mesosphäre / unteren Thermosphäre (80 - 110 km). Die Meß- und Auswertemethode wurde in den vergangenen Jahrzehnten aus sehr bescheidenen Anfängen heraus theoretisch und experimentell so entwickelt, daß derzeit eine vollautomatische komplexe Apparatur zur quasi-kontinuierlichen Windmessung in drei Referenzpunkten über Mitteleuropa (gegenseitige Entfernung 200 km) zur Verfügung steht, die die Momentanwerte des Windes nach Richtung und Geschwindigkeit mißt, die zugehörige Höhe feststellt, Mittelwerte bildet, Grund- und Gezeitenwind voneinander trennt und Höhen-Wind-Profile über vorgebbare Zeitabschnitte rechnet, aus denen letztendlich Höhen-Zeit-Schnitte der Windfeldparameter konstruiert werden können. Die vorliegende Arbeit skizziert die einzelnen Etappen dieser Entwicklung, berichtet von Problemen und ihrer Lösung und gibt Beispiele von Windfeldanalysen aus dem Jahre 1992. / The Collm Geophysical Observatory was founded by Professor L. WEICKMANN in 1932 as an experimental base of Leipzig University''s Geophysical Institute for meteorological, seismological and geomagnetic observations. In 1956 as a preparation for the Internal Geophysical Year (IGY) we began with high-atmosphere measurements, and since 1959 wind measurements in the height range of the upper mesosphere / lower thennosphere (80 - 110 km) have been emphasized. During the past decades the method of measuring and analysing was developped theoretically and experimentally from primitive Starts so far, that at present a fully automatic and complex equipment with quasi-continuous measurements of the wind at three reference points within Central Europe (mutual distance 200 km) is available. These devices measure the instantaneous data of the wind according to direction and velocity, ascertain the corresponding height, calculate averages, separate the tidal wind components from the prevailing wind, and compute height wind-profiles for adjustable periods of time, from which height-time cross section of the wind field parameters can be finally constructed. The following paper outlines the particular stages of this development, informs about problems and their solution, and offers examples of wind field analyses for 1992. info:eu-repo/classification/ddc/551 ddc:551
74	Variações nas marés atmosféricas e nos ventos meteóricos observados em São João Do Cariri-PB e em Cachoeira Paulista-SP. / Variations in atmospheric tides and winds meteoric observed in São João do Cariri-PB and Cachoeira Paulista-SP Borges, Fabricio Batista 04 April 2010 (has links) Made available in DSpace on 2015-09-25T12:23:41Z (GMT). No. of bitstreams: 1 Fabricio Batista Borges.pdf: 1546340 bytes, checksum: 1d8be2583a092a34d256d749548325ef (MD5) Previous issue date: 2010-04-04 / Meteor wind measurements obtained from São João do Cariri B and Cachoeira Paulista SP, Brazil, obtained during the period from August 2004 to July 2006 were used to examine Variations in atmospheric tides and winds in the mesopause region of the equatorial and low Latitudes in the southern hemisphere. The results for the mean wind were compared with the HWM 93 and HWM 07 models (Horizontal neutral wind model) and the results of Atmospheric tides with GSWM 02 model (Global Scale Wave Model). From the analysis of These data it was observed that the mean wind, as well as diurnal fluctuations, showed Temporal and in altitude variations for both the zonal and to the south for both the localities investigated. Mean zonal winds for the region of the S. J. do Cariri show a structure that is characterized by a semi annual oscillation, with a flow westward most of the time, in accordance with HWM 07 model. The mean zonal wind at C. Paulista is eastward in the most time and presents a semi annual variation in the 80 90 km altitude range and an annual variation in the altitudes above, in which some aspects are in accordance with HWM 93 and 07 models. The amplitudes of the mean meridional winds were weaker than zonal and present An annual variation for both sites, which are in accordance with HWM 93 model, however the HWM 07 do not reproduce the observed behavior. The meridional diurnal tide amplitudes Showed semi annual variation with maximum of the up to 65 m/s during February April and August September. The vertical wavelength estimated reached values between 21.2 and 27.5 Km at S. J. do Cariri, smaller than the GSWM 02, whereas to C. Paulista the vertical Wavelength were determined between 24 and 31.9 km, near of the GSWM 02 model, but More than the diurnal tide meridional wavelength for Cariri. / Medidas de vento meteóricos obtidos em São João do Cairi-PB e Cachoeira Paulista-SP Brasil, realizadas durante o período compreendido entre agosto de 2004 a julho de 2006, foram usadas para investigar as variações nas marés atmosféricas e nos ventos meteóricos na região da mesopausa equatorial e de baixas latitudes do hemisfério sul. Os resultados obtidos para os ventos médios foram comparados com os modelos HWM 93 e HWM 07 (Horizontal Neutral Wind Model) e os resultados das marés atmosféricas com GSWM 02 (Global Scale Wave Model). A partir da análise destes dados, foi possível observar que os ventos médios, Assim como as oscilações diurnas, apresentaram variação temporal e em função da altura, tanto para a componente zonal como para a meridional para ambas as localidades investigadas. Os ventos médios na direção zonal para região de S. J. do Cariri mostram uma estrutura que é Caracterizada por uma oscilação semi anual, apresentando um escoamento para oeste na maior Parte do tempo, semelhante com o modelo HWM 07. Já o vento médio zonal verificado na Região de C. Paulista é predominante para leste com variação semi anual entre 80 e 90 km e Anual nas altitudes acima, semelhante em alguns aspectos com os modelos HWM 93 e 07. O Escoamento médio na direção meridional apresenta amplitudes menores do que as do zonal e Oscilação anual para ambas as localidades, a qual é semelhante com o modelo HWM 93, Porém o modelo HWM 07 não reproduz o comportamento observado. As amplitudes da maré Diurna para a componente meridional mostraram variação semi anual com máximos de até 65 m/s em fevereiro abril e agosto setembro. Comprimentos de onda vertical para a componente meridional foram estimados entre 21,2 e 27,5 km para S. J. do Cariri, menores do que as observadas pelo modelo GSWM 02, enquanto que para C. Paulista os comprimentos de onda assumiram valores entre 24 e 31,9 km, próximos aos previstos, porém maiores do que os de Cariri. Marés atmosféricas Ventos Radar Meteórico Mesosfera Superior Dinâmica da Alta Atmosfera Atmospheric tides winds meteor radar Superior Mesosphere Upper Atmosphere Dynamics
75	Investigation of Polar Mesosphere Summer Echoes in Northern Scandinavia Barabash, 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> Physics Polar Mesosphere Summer Echoes middle atmospheric dynamics ionospheric disturbances solar radiation aerosol MST radar planetary waves noctilucent clouds Fysik Physics Fysik
76	Investigation of Polar Mesosphere Summer Echoes in Northern Scandinavia Barabash, 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). Physics Polar Mesosphere Summer Echoes middle atmospheric dynamics ionospheric disturbances solar radiation aerosol MST radar planetary waves noctilucent clouds Fysik Physics Fysik
77	Gravity wave coupling of the lower and middle atmosphere. Love, Peter Thomas January 2009 (has links) A method of inferring tropospheric gravity wave source characteristics from middle atmosphere observations has been adapted from previous studies for use with MF radar observations of the equatorial mesosphere-lower thermosphere at Christmas Island in the central Pacific. The nature of the techniques applied also permitted an analysis of the momentum flux associated with the characterised sources and its effects on the equatorial mean flow and diurnal solar thermal tide. An anisotropic function of gravity wave horizontal phase speed was identified as being characteristic of convectively generated source spectra. This was applied stochastically to a ray-tracing model to isolate numerical estimates of the function parameters. The inferred spectral characteristics were found to be consistent with current theories relating convective gravity wave spectra to tropospheric conditions and parameters characterising tropical deep convection. The results obtained provide observational constraints on the model spectra used in gravity wave parameterisations in numerical weather prediction and general circulation models. The interaction of gravity waves with the diurnal solar thermal tide was found to cause an amplification of the tide in the vicinity of the mesopause. The gravity wave-tidal interactions were highly sensitive to spectral width and amplitude. Estimates were made of the high frequency gravity wave contribution to forcing the MSAO with variable results. The data used in the analysis are part of a large archive which now has the potential to provide tighter constraints on wave spectra through the use of the methods developed here. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1352362 / Thesis (Ph.D.) -- University of Adelaide, School of Chemistry and Physics, 2009 Gravity waves
78	Modélisation du rayonnement proche infrarouge émis par la haute atmosphère : étude théorique et observationnelle / Nightglow modelling at high altitude : theoretical and observational study Bellisario, Christophe 10 December 2015 (has links) Le rayonnement atmosphérique appelé nightglow est un phénomène se produisant à haute altitude (environ 90 km). Il consiste en l’émission d’un rayonnement suite à la désexcitation de certaines molécules et atomes (OH, Na, O2 et O). Il se répartit sur une large gamme spectrale, en particulier dans l’infrarouge et se propage jusqu’au niveau du sol. Le rayonnement nightglow constitue un marqueur important pour la haute atmosphère, permettant de remonter à la température, mais également à de nombreux phénomènes dynamiques comme les marées atmosphériques ou les ondes de gravité. Sa propagation au niveau du sol permet l’éclairage de scène terrestre et ainsi la vision nocturne à l’aide de caméras proche infrarouge. Afin de mieux connaître les fluctuations de ces émissions en fonction du temps à différentes échelles et en différents lieux sur la planète, la thèse s’est axée sur une étude observationnelle et une étude théorique. L’étude observationnelle a produit une climatologie à grande échelle par l’extraction du rayonnement issu des données de l’instrument GOMOS. Les campagnes de mesures réalisées au sol ont quant à elles mis en avant certains aspects dynamiques importants comme les marées et les ondes de gravité. Pour reproduire le rayonnement nightglow, il a été nécessaire de modéliser les réactions chimiques des nombreuses espèces présentes à haute altitude, le chauffage, la photodissociation de certaines molécules par le rayonnement solaire et la propagation du rayonnement vers le sol. Certains processus dynamiques ont été inclus comme la diffusion moléculaire, la diffusion turbulente et une paramétrisation des marées. Enfin, les résultats du modèle sont comparés aux observations satellitaires ainsi qu’au niveau du sol et des tests de sensibilité sont effectués pour estimer la réponse du rayonnement aux différents modules du modèle. / The nightglow is an atmospheric radiation which occurs at high altitude (around 90 km). It comes from the desexcitation of specific molecules and atoms (OH, Na, O2 and O). It spreads over a wide spectral band, especially in the infrared and propagates to the ground level. The nightglow emission is an important mark for the high atmosphere, as it allows the retrieval of the temperature and many dynamic processes such as atmospheric tides or gravity waves. Its propagation to the ground level allows the illumination of terrestrial scene and therefore the night vision with the use of near infrared cameras. In order to have a better knowledge of the emission fluctuations as a function of time for various scales and at various locations, the work is focused on an observational and theoretical study. The observational study produced large scale climatology with the extraction of nightglow emission from GOMOS data. On the other hand, ground measurements highlighted some dynamical aspects such as tides and gravity waves. To model the nightglow emission, it has been necessary to take into account the chemical reactions of the species available at high altitude, the heating, the photodissociation process and the propagation of the emission to the ground. Selected dynamical processes have been included, such as the molecular and turbulent diffusion, and a tide parameterization. Finally, the results of the model are compared to the satellite and ground observations and sensitivity tests are run to estimate the response of the emission to the various modules of the model. Nightglow Mésosphère Rayonnement Modélisation Photochimie Dynamique GOMOS Ondes de gravité Marées atmosphériques Nightglow Mesosphere Emission Model Photochemistry Dynamic GOMOS Gravity waves Atmospheric tides 551.5
79	Long-term changes and trends of mesosphere/lower thermosphere winds over Collm, Germany Jacobi, Ch., Karami, K. 08 December 2023 (has links) We analyse 43 years of mesosphere/lower thermosphere (MLT) horizontal winds obtained from a joint analysis of low frequency (LF) spaced receiver lower ionospheric drift measurements from 1979 through 2006 and very high frequency (VHF) meteor radar wind observations since 2004 at Collm (51°N, 13°E). Due to limitations of the earlier LF measurements, we restrict ourselves to the analysis of monthly mean winds near 90 km, which represents the height of maximum meteor activity as well as LF reflections in the MLT. In the 1980s and 1990s, we observe mainly positive trends of the zonal prevailing wind throughout the year, while the meridional winds tend to decrease in magnitude in both summer and winter. We also analyse interannual variability, in particular with respect to a possible signature of NAO and ENSO. These signals, however, are relatively weak and not stable throughout the time of observations. / Wir analysieren 43 Jahre Messungen horizontaler Winde in der Mesosphäre/unteren Thermosphäre (MLT) über Collm (51°N, 13°E), die aus einer gemeinsamen Analyse von Langwellen (LF) -Driftmessungen in der unteren Ionosphäre von 1979 bis 2006 und VHF-Meteorradar-Windbeobachtungen seit 2004 gewonnen wurden. Aufgrund der Einschränkungen der früheren LF-Messungen beschränken wir uns auf die Analyse der mittleren monatlichen Windgeschwindigkeiten bei 90 km, welches die Höhe maximaler Meteorraten sowie die mittleren nächtlichen LF-Reflexionshöhen in der MLT darstellt. In den 1980er und 1990er Jahren beobachten wir das ganze Jahr über hauptsächlich positive Trends des zonalen mittleren Windes, während die Stärke des meridionalen Windes sowohl im Sommer als auch im Winter tendenziell abnimmt. Wir analysieren auch die Variabilität von Jahr zu Jahr, insbesondere im Hinblick auf eine mögliche Signatur von NAO und ENSO. Diese Signale sind jedoch relativ schwach und nicht über die gesamte Beobachtungszeit stabil nachweisbar. info:eu-repo/classification/ddc/551 ddc:551
80	Studies of the PMWE : Polar Mesosphere Winter Echoes Persson, Simon January 2022 (has links) This Master thesis examines a phenomenon that occurs in the upper polar atmosphere, namely, Polar Mesospheric Winter Echoes, or PMWEs. PMWEs are radar echoes observed by Very High Frequency Mesosphere Stratosphere Troposphere (VHF MST) radar, from altitudes of 60 to 76 km at 7 to 15 UT, in the winter months from the middle of September to the beginning of May. The aforementioned specifications are the partial results of this thesis.PMWEs are generally understood to be caused by turbulence; however, radar data indicate some rare cases where PMWEs can be created with velocities exceeding the speed of sound, which is not possible with current turbulence theory. Kirkwood et al., 2006 and Belova, Kirkwood, and Sergienko, 2013 hypothesised that infrasound could generate the necessary conditions for PMWEs with velocities equal to or exceeding the speed of sound. Observations of PMWEs presented in this thesis have been carried out by the MST radar ESRAD, located at Esrange (67 56’N, 21 04’E) near Kiruna in northern Sweden. The radar operates at 52 MHz and has been performing continuous radar observations since Dec 1996. Observations of the infrasounds presented in this thesis were carried out by a microbarometer located close to Rymdcampus in Kiruna. Access to the data is restricted, but through university administration, this master’s thesis has been granted permission to use the data for the study of PMWEs. The instrument performed continuous infrasound measurements from the 24th of May 2016 and forward. This thesis will perform a full analysis of all radar data from the 17th of Dec 1996 until the 31st of Jan 2021 to assess the altitude interval, diurnal interval and yearly interval. The data given in the first section are a result of this work. Additionally, space weather parameters relation with the occurrence of PMWEs is analysed. Space weather parameters are very important for the chemistry and conditions present in the mesosphere. It is shown thatt here is a strong relation between solar wind and PMWE occurrence, decent relation with Kp index and no to weak relation with solar particle event (SPE). Correlating space weather and PMWEs in greater detail could be the subject of other studies. Last but most interesting, microbarometer data will be analysed for days where high-speed PMWEs are detected. Because of the rarity of these high-speed PMWEs, only seven total cases were found from 24 May 2016 onward, making the analysis of the infrasound measurements very limited, and no connection was found. However, it was found that days with high-speed PMWEs had an abnormally low amount of infrasound detections, further making analysis difficult but raising questions of why. This could mean that infrasound signals might be hindered from reaching the ground on days where we have high-speed PMWEs. No further conclusions can be made, as this indicates relation but not causation. Airborne infrasound instruments could be used to detect weaker infrasound signals due to being unaffected by wind disturbance at the ground. Polar Mesosphere Winter Echoes ESRAD Infrasound PMWE PMSE Summer Radar VHF MST MLT SPE HSS Solar Wind evanescent viscosity FCA 42 Meteorology and Atmospheric Sciences Meteorologi och atmosfärforskning

Search results