Your search keyword '"V. F. Andrioli"' showing total 38 results

1. Trends in the high-latitude mesosphere temperature and mesopause revealed by SABER

Author

X. Liu, J. Xu, J. Yue, Y. Liu, and V. F. Andrioli

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

The temperature trend in the mesosphere and lower-thermosphere (MLT) region can be regarded as an indicator of climate change. Using temperature profiles measured by the Sounding of the Atmosphere using Broadband Emission Radiometry (SABER) instrument during 2002–2023 and binning them based on the yaw cycle, we obtain a continuous dataset with a wide local time coverage at 50° S–80° N or 80° S–50° N. The seasonal change in temperature, caused by the forward drift in the SABER yaw cycle, is removed using the climatological temperature of the Naval Research Laboratory's Mass Spectrometer Incoherent Scatter Radar model (MSIS2.0). The corrected temperature without any waves is regarded as the mean temperature. At 50° S–50° N, the cooling trends in the mean temperature are significant in the MLT region and are in agreement with previous studies. The novel finding is that the cooling trends of ≥ l2 K per decade exhibit seasonal symmetry and reach peaks of ≥ 6 K per decade at high latitudes around the summer solstice. Moreover, there are warming trends of 1–2.5 K per decade at an altitude range of 10−2–10−3 hPa, specifically at latitudes higher than 55° N in October and December and at latitudes higher than 55° S in April and August. Over the past 22 years, the mesopause temperature (altitude) in the northern summer polar region has been ∼ 5–11 K (∼ 1 km) colder (lower) than that in the corresponding southern region. The trends in the mesopause temperature are dependent on latitudes and months, but they are negative at most latitudes and reach larger magnitudes at high latitudes. These results indicate that the temperature in the high-latitude MLT region is more sensitive to dynamic changes.

Published

2024

2. Variations in global zonal wind from 18 to 100 km due to solar activity and the quasi-biennial oscillation and El Niño–Southern Oscillation during 2002–2019

Author

X. Liu, J. Xu, J. Yue, and V. F. Andrioli

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

Variations of global wind are important in changing the atmospheric structure and circulation, in coupling of atmospheric layers, and in influencing the wave propagations. Due to the difficulty of directly measuring zonal wind from the stratosphere to the lower thermosphere, we derived a global balance wind (BU) dataset from 50∘ S to 50∘ N and during 2002–2019 using the gradient wind theory and SABER temperatures and modified by meteor radar observations at the Equator. The dataset captures the main feature of global monthly mean zonal wind and can be used to study the variations (i.e., annual, semi-annual, ter-annual, and linear) of zonal wind and the responses of zonal wind to quasi-biennial oscillation (QBO), El Niño–Southern Oscillation (ENSO), and solar activity (F10.7). The same procedure is performed on the MERRA-2 zonal wind (MerU) to validate BU and its responses below 70 km. The annual, semi-annual, and ter-annual oscillations of BU and MerU have similar amplitudes and phases. The semi-annual oscillation of BU has peaks around 80 km, which are stronger in the southern tropical region and coincide with previous satellite observations. As the increasing of the values representing QBO wind, both values of representing BU and MerU (short for BU and MerU) change from increasing to decreasing with the increasing height and extend from the Equator to higher latitudes. Both BU and MerU increase with the increasing of the values of multivariate ENSO index (MEI) and decrease with increasing F10.7​​​​​​​ in the southern stratospheric polar jet region below 70 km. The responses of winds to ENSO and F10.7 exhibit hemispheric asymmetry and are more significant in the southern polar jet region. While above 70 km, BU increases with the increasing of MEI and F10.7. The negative linear changes of BU at 50∘ N are absent in MerU during October–January. The discussions on the possible influences of the temporal intervals and sudden stratospheric warmings (SSWs) on the variations and responses of BU illustrate the following: (1) the seasonal variations and the responses to QBO are almost independent on the temporal intervals selected; (2) the responses to ENSO and F10.7 are robust but slightly depend on the temporal intervals; (3) the linear changes of both BU and MerU depend strongly on the temporal intervals; (4) SSWs affect the magnitudes but do not affect the hemispheric asymmetry of the variations and responses of BU at least in the monthly mean sense. The variations and responses of global zonal wind to various factors are based on BU, which is derived from observations, and thus provide a good complement to model studies and ground-based observations.

Published

2023

3. Climatology of atmospheric solar tidal mode effects on ionospheric F2 parameters over the American sector during solar minimum between cycles #23 and #24

Author

A. M. Santos, G. Yang, A. A. Pimenta, C. G. M. Brum, I. S. Batista, J. H. A. Sobral, V. F. Andrioli, P. P. Batista, M. A. Abdu, J. R. Souza, P. K. Manoharan, C. Wang, H. Li, and Z. Liu

Subjects

ionosphere, F-region peak, solar atmospheric tides, solar minimum, latitudinal dependence, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

This work presents the contribution of solar atmospheric tides (diurnal, semidiurnal, and terdiurnal modes) to the variability of the parameters critical frequency (foF2) and peak height of the F2-layer (hmF2) in the American sector during the transition of solar cycles #23 and #24, a period considered one of the lowest solar activities of the modern era. The Digisonde data available in the GIRO data center were analyzed (12 stations), and the solar tide modes were evaluated regarding their amplitude, latitude, and seasonal dependence. The results showed that the hmF2 and foF2 strongly depend on latitude and seasonality, being more intense in the stations located in the south hemisphere. The same behavior is seen for the tidal amplitude fitted in these parameters, except for hmF2 diurnal tide, which is more intense at latitudes farther from the equator. Moreover, the seasonal variability of the amplitude of hmF2 in most cases presented an annual and semiannual component. A terannual component was also observed in 8 h tide mode in the height and frequency parameters. Likewise, what was observed in foF2, the variability in the mean amplitude and different modes of tides of hmF2 are higher over the sectors located in the southern hemisphere.

Published

2024

4. Effects of the terdiurnal tide on the sporadic E (Es) layer development at low latitudes over the Brazilian sector

Author

P. A. Fontes, M. T. D. A. H. Muella, L. C. A. Resende, V. F. Andrioli, P. R. Fagundes, V. G. Pillat, P. P. Batista, and A. J. Carrasco

Subjects

Science, Physics, QC1-999, Geophysics. Cosmic physics, QC801-809

Abstract

Sporadic E (Es) layers are patches of high ionization observed at around 100–140 km height in the E region. Their formation at low latitudes is primarily associated with the diurnal and semidiurnal components of the tidal winds via the ion convergence driven by the wind shear mechanism. However, recent studies have shown the influence of other tidal modes, such as the terdiurnal tide. Therefore, this work investigates the effect of terdiurnal tide-like oscillations on the occurrence and formation of the Es layers observed over Palmas (10.17∘ S, 48.33∘ W; dip lat. −7.31∘), a low-latitude station in Brazil. The analysis was conducted from December 2008 to November 2009 by using data collected from CADI (Canadian Advanced Digital Ionosonde). Additionally, the E Region Ionospheric Model (MIRE) was used to simulate the terdiurnal tidal component in the Es layer development. The results show modulations of 8 h periods on the occurrence rates of the Es layers during all seasonal periods. In general, we see three well-defined peaks in a superimposed summation of the Es layer types per hour in summer and autumn. We also observed that the amplitude modulation of the terdiurnal tide on the Es occurrence rates minimizes in December in comparison to the other months of the summer season. Other relevant aspects of the observations, with complementary statistical and periodogram analysis, are highlighted and discussed.

Published

2023

5. Why can the auroral-type sporadic E layer be detected over the South America Magnetic Anomaly (SAMA) region? An investigation of a case study under the influence of the high-speed solar wind stream

Author

L. A. Da Silva, J. Shi, L. E. Vieira, O. V. Agapitov, L. C. A. Resende, L. R. Alves, D. Sibeck, V. Deggeroni, J. P. Marchezi, S. Chen, J. Moro, C. Arras, C. Wang, V. F. Andrioli, H. Li, and Z. Liu

Subjects

inner radiation belt, South America Magnetic Anomaly, auroral-type sporadic E-layers, particle precipitation, hiss waves, pitch angle scattering, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

The low-electron flux variability (increase/decrease) in the Earth’s radiation belts could cause low-energy Electron Precipitation (EP) to the atmosphere over auroral and South American Magnetic Anomaly (SAMA) regions. This EP into the atmosphere can cause an extra upper atmosphere’s ionization, forming the auroral-type sporadic E layers (Esa) over these regions. The dynamic mechanisms responsible for developing this Esa layer over the auroral region have been established in the literature since the 1960s. In contrast, there are several open questions over the SAMA region, principally due to the absence (or contamination) of the inner radiation belt and EP parameter measurements over this region. Generally, the Esa layer is detected under the influence of geomagnetic storms during the recovery phase, associated with solar wind structures, in which the time duration over the auroral region is considerably greater than the time duration over the SAMA region. The inner radiation belt’s dynamic is investigated during a High-speed Solar wind Stream (September 24-25, 2017), and the hiss wave-particle interactions are the main dynamic mechanism able to trigger the Esa layer’s generation outside the auroral oval. This result is compared with the dynamic mechanisms that can cause particle precipitation in the auroral region, showing that each region presents different physical mechanisms. Additionally, the difference between the time duration of the hiss wave activities and the Esa layers is discussed, highlighting other ingredients mandatory to generate the Esa layer in the SAMA region.

Published

2023

6. Analysis of the different physical mechanisms in the atypical sporadic E (Es) layer occurrence over a low latitude region in the Brazilian sector

Author

L. C. A. Resende, Y. Zhu, C. M. Denardini, R. A. J. Chagas, L. A. Da Silva, V. F. Andrioli, C. A. O. Figueiredo, J. P. Marchezi, S. S. Chen, J. Moro, R. P. Silva, H. Li, C. Wang, and Z. Liu

Subjects

sporadic E layer, ionosphere, plasma instability, gravity waves, particle precipitation, South American magnetic anomaly, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

We present a study about the atypical and spreading Sporadic E-layers (Es) observed in Digisonde data. We analyzed a set of days around space weather events from 2016 to 2018 over Cachoeira Paulista (CXP, 22.41°S, 45°W, dip ∼35°), a low-latitude Brazilian station. The inhomogeneous Es layer is associated with the auroral-type Es layer (Esa) occurrence in this region due to the presence of South American Magnetic Anomaly (SAMA). However, we also observe that the spreading Es layers occurred days before the magnetic storms or quiet times. Also, this specific type of Es layer has some different characteristics concerning the Esa layer. We used data from the imager, satellite, and meteor radar to understand the dynamic processes acting in this Es layer formation. Our results lead us to believe that other mechanisms affect the Es layer development. We show evidence that the instabilities added to the wind shear mechanism can cause the atypical Es layers, such as Kelvin-Helmholtz instability (KHI). Finally, an important discovery of this work is that the spreading Es layer, mainly during quiet times, is not necessarily due to the particle precipitation due to the SAMA. We found that the wind shear can be turbulent, influencing the Es layer development. Lastly, our analysis better understood the Es layer behavior during quiet and disturbed times.

Published

2023

7. Solar Cycle and Long‐Term Trends in the Observed Peak of the Meteor Altitude Distributions by Meteor Radars

Author

E. C. M. Dawkins, G. Stober, D. Janches, J. D. Carrillo‐Sánchez, R. S. Lieberman, C. Jacobi, T. Moffat‐Griffin, N. J. Mitchell, N. Cobbett, P. P. Batista, V. F. Andrioli, R. A. Buriti, D. J. Murphy, J. Kero, N. Gulbrandsen, M. Tsutsumi, A. Kozlovsky, J. H. Kim, C. Lee, and M. Lester

Subjects

meteor, altitude, mesosphere, meteor radar, climate change, mesopause, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract The mesosphere/lower thermosphere (MLT, 80–100 km) region is an important boundary between Earth's atmosphere below and space above and may act as a sensitive indicator for anthropogenic climate change. Existing observational and modeling studies have shown the middle atmosphere and the MLT is cooling and contracting because of increasing greenhouse gas emissions. However, trend analyses are highly sensitive to the time periods covered, their length, and the measurement type and methodology used. We present for the first time the linear and 11‐year solar cycle responses in the meteor ablation altitude distributions observed by 12 meteor radars at different locations. Decreasing altitudes were seen at all latitudes (linear trends varying from −10.97 to −817.95 m dec−1), and a positive correlation with solar activity was seen for most locations. The divergence of responses at high latitudes indicates an important and complex interplay between atmospheric changes and dynamics at varying time scales.

Published

2023

8. Global balanced wind derived from SABER temperature and pressure observations and its validations

Author

X. Liu, J. Xu, J. Yue, Y. Yu, P. P. Batista, V. F. Andrioli, Z. Liu, T. Yuan, C. Wang, Z. Zou, G. Li, and J. M. Russell III

Subjects

Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

Zonal winds in the stratosphere and mesosphere play important roles in atmospheric dynamics and aeronomy. However, the direct measurement of winds in this height range is difficult. We present a dataset of the monthly mean zonal wind in the height range of 18–100 km and at latitudes of 50∘ S–50∘ N from 2002 to 2019, derived by the gradient balance wind theory and the temperature and pressure observed by the SABER instrument. The tide alias above 80 km at the Equator is replaced by the monthly mean zonal wind measured by a meteor radar at 0.2∘ S. The dataset (named BU) is validated by comparing with the zonal wind from MERRA2 (MerU), UARP (UraU), the HWM14 empirical model (HwmU), meteor radar (MetU), and lidar (LidU) at seven stations from around 50∘ N to 29.7∘ S. At 18–70 km, BU and MerU have (i) nearly identical zero wind lines and (ii) year-to-year variations of the eastward and westward wind jets at middle and high latitudes, and (iii) the quasi-biennial oscillation (QBO) and semi-annual oscillation (SAO) especially the disrupted QBO in early 2016. The comparisons among BU, UraU, and HwmU show good agreement in general below 80 km. Above 80 km, the agreements among BU, UraU, HwmU, MetU, and LidU are good in general, except some discrepancies at limited heights and months. The BU data are archived as netCDF files and are available at https://doi.org/10.12176/01.99.00574 (Liu et al., 2021). The advantages of the global BU dataset are its large vertical extent (from the stratosphere to the lower thermosphere) and 18-year internally consistent time series (2002–2019). The BU data is useful to study the temporal variations with periods ranging from seasons to decades at 50∘ S–50∘ N. It can also be used as the background wind for atmospheric wave propagation.

Published

2021

9. Multi-year observations of gravity wave momentum fluxes at low and middle latitudes inferred by all-sky meteor radar

Author

V. F. Andrioli, P. P. Batista, B. R. Clemesha, N. J. Schuch, and R. A. Buriti

Subjects

Science, Physics, QC1-999, Geophysics. Cosmic physics, QC801-809

Abstract

We have applied a modified composite day analysis to the Hocking (2005) technique to study gravity wave (GW) momentum fluxes in the mesosphere and lower thermosphere (MLT). Wind measurements from almost continuous meteor radar observations during June 2004–December 2008 over São João do Cariri (Cariri; 7° S, 36° W), April 1999–November 2008 over Cachoeira Paulista (CP; 23° S, 45° W), and February 2005–December 2009 over Santa Maria (SM; 30° S, 54° W) were used to estimate the GW momentum fluxes and variances in the MLT region. Our analysis can provide monthly mean altitude profiles of vertical fluxes of horizontal momentum for short-period (less than 2–3 h) GWs. The averages for each month throughout the entire data series have shown different behavior for the momentum fluxes depending on latitude and component. The meridional component has almost the same behavior at the three sites, being positive (northward), for most part of the year. On the other hand, the zonal component shows different behavior at each location: it is positive for almost half the year at Cariri and SM but predominantly negative over CP. Annual variation in the GW momentum fluxes is present at all sites in the zonal component and also in SM at 89 km in the meridional component. The seasonal analysis has also shown a 4-month oscillation at 92.5 km over SM in the zonal component and over CP at the same altitudes but for the meridional component.

Published

2015

10. Diurnal variation in gravity wave activity at low and middle latitudes

Author

V. F. Andrioli, D. C. Fritts, P. P. Batista, B. R. Clemesha, and D. Janches

Subjects

Science, Physics, QC1-999, Geophysics. Cosmic physics, QC801-809

Abstract

We employ a modified composite day extension of the Hocking (2005) analysis method to study gravity wave (GW) activity in the mesosphere and lower thermosphere using 4 meteor radars spanning latitudes from 7° S to 53.6° S. Diurnal and semidiurnal modulations were observed in GW variances over all sites. Semidiurnal modulation with downward phase propagation was observed at lower latitudes mainly near the equinoxes. Diurnal modulations occur mainly near solstice and, except for the zonal component at Cariri (7° S), do not exhibit downward phase propagation. At a higher latitude (SAAMER, 53.6° S) these modulations are only observed in the meridional component where we can observe diurnal variation from March to May, and semidiurnal, during January, February, October (above 88 km) and November. Some of these modulations with downward phase progression correlate well with wind shear. When the wind shear is well correlated with the maximum of the variances the diurnal tide has its largest amplitudes, i.e., near equinox. Correlations exhibiting variations with tidal phases suggest significant GW-tidal interactions that have different characters depending on the tidal components and possible mean wind shears. Modulations that do not exhibit phase variations could be indicative of diurnal variations in GW sources.

Published

2013

11. Improved analysis of all-sky meteor radar measurements of gravity wave variances and momentum fluxes

Author

V. F. Andrioli, D. C. Fritts, P. P. Batista, and B. R. Clemesha

Subjects

Science, Physics, QC1-999, Geophysics. Cosmic physics, QC801-809

Abstract

The advantages of using a composite day analysis for all-sky interferometric meteor radars when measuring mean winds and tides are widely known. On the other hand, problems arise if this technique is applied to Hocking's (2005) gravity wave analysis for all-sky meteor radars. In this paper we describe how a simple change in the procedure makes it possible to use a composite day in Hocking's analysis. Also, we explain how a modified composite day can be constructed to test its ability to measure gravity wave momentum fluxes. Test results for specified mean, tidal, and gravity wave fields, including tidal amplitudes and gravity wave momentum fluxes varying strongly with altitude and/or time, suggest that the modified composite day allows characterization of monthly mean profiles of the gravity wave momentum fluxes, with good accuracy at least at the altitudes where the meteor counts are large (from 89 to 92.5 km). In the present work we also show that the variances measured with Hocking's method are often contaminated by the tidal fields and suggest a method of empirical correction derived from a simple simulation model. The results presented here greatly increase our confidence because they show that our technique is able to remove the tide-induced false variances from Hocking's analysis.

Published

2013

12. Observation of a mesospheric front in a thermal-doppler duct over King George Island, Antarctica

Author

J. V. Bageston, C. M. Wrasse, P. P. Batista, R. E. Hibbins, D. C Fritts, D. Gobbi, and V. F. Andrioli

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

A mesospheric front was observed with an all-sky airglow imager on the night of 9–10 July 2007 at Ferraz Station (62° S, 58° W), located on King George island on the Antarctic Peninsula. The observed wave propagated from southwest to northeast with a well defined wave front and a series of crests behind the main front. The wave parameters were obtained via a 2-D Fourier transform of the imager data providing a horizontal wavelength of 33 km, an observed period of 6 min, and a horizontal phase speed of 92 m s−1. Simultaneous mesospheric winds were measured with a medium frequency (MF) radar at Rothera Station (68° S, 68° W) and temperature profiles were obtained from the SABER instrument on the TIMED satellite. These wind and temperature profiles were used to estimate the propagation environment of the wave event. A wavelet technique was applied to the wind in the plane of wave propagation at the OH emission height spanning three days centered on the front event to define the dominant periodicities. Results revealed a dominance of near-inertial periods, and semi-diurnal and terdiurnal tides suggesting that the ducting structure enabling mesospheric front propagation occurred on large spatial scales. The observed tidal motions were used to reconstruct the winds employing a least-squares method, which were then compared to the observed ducting environment. Results suggest an important contribution of large-scale winds to the ducting structure, but with buoyancy frequency variations in the vertical also expected to be important. These results allow us to conclude that the wave front event was supported by a duct including contributions from both winds and temperature.

Published

2011

13. Case study of a mesospheric wall event over Ferraz station, Antarctica (62° S)

Author

J. V. Bageston, C. M. Wrasse, R. E. Hibbins, P. P. Batista, D. Gobbi, H. Takahashi, V. F. Andrioli, J. Fechine, and C. M. Denardini

Subjects

Science, Physics, QC1-999, Geophysics. Cosmic physics, QC801-809

Abstract

On 16–17 July 2007 during an observational campaign at Comandante Ferraz Antarctic Station (62° S, 58° W), a mesospheric wall was observed with an airglow all-sky imager. The wave appeared like an extensive dark region in the all-sky airglow images, with a large depletion in the OH emission. Simultaneous mesospheric winds measured with a MF radar at Rothera station and temperature profiles from SABER instrument, on board of TIMED satellite, were used to obtain the propagation condition of the wave. Wind measurements during four days, around the time of observation of the wave, are presented in order to discuss the type and consistence of the duct in which this wave was propagating. By using wavelet analysis and tidal amplitude components we found that 12 and 8 h components were the most important periodicities around the time interval of the wave observation. A collocated imaging spectrometer, for mesospheric temperature measurements, has been operated simultaneously with the all-sky imager. Direct effects of the mesospheric front have been seen in the spectrometric measurements, showing an abrupt decrease in both OH intensity and rotational temperature when the wave front passes overhead. The main contribution of the present work is the investigation of the type of duct in which the wall event was propagating. We found evidences for a thermal duct structure to support the mesospheric wall propagation. This result was obtained by two types of analysis: (a) the tidal components analysis and winds filtering (harmonic analysis), and (b) comparison between the terms of the m2 dispersion relation.

Published

2011

14. New Findings Relating Tidal Variability and Solar Activity in the Low Latitude MLT Region

Author

V. F. Andrioli, J. Xu, P. P. Batista, L. C. A. Resende, L. A. Da Silva, J. P. Marchezi, H. Li, C. Wang, Z. Liu, and A. Guharay

Subjects

Geophysics, Space and Planetary Science

Published

2022

15. Simultaneous Observation of Sporadic Potassium and Sodium Layers Over São José dos Campos, Brazil (23.1°S, 45.9°W)

Author

Guotao Yang, Z. Liu, S. Savio, M. P. P. Martins, Jiexin Xu, V. F. Andrioli, A. A. Pimenta, Jiu Jimmy Jiao, Paulo Batista, C. G. Targon, and Cunguo Wang

Subjects

Geophysics, Space and Planetary Science, Chemistry, Potassium, Sodium, Sodium layer, chemistry.chemical_element, Nuclear chemistry

Published

2021

16. The Impact of the Disturbed Electric Field in the Sporadic E (Es) Layer Development Over Brazilian Region

Author

A. J. Carrasco, S. S. Chen, P. A. B. Nogueira, R. C. de Araujo, Ronan Arraes Jardim Chagas, Laysa Cristina Araujo Resende, Junru Shi, R. P. Silva, D. Barros, Z. X. Liu, J. Moro, G. A. S. Picanço, V. F. Andrioli, I. S. Batista, Cunguo Wang, and Clezio Marcos Denardini

Subjects

Geophysics, Space and Planetary Science, Electric field, Ionosphere, Sporadic E propagation, Layer (electronics), Geology

Published

2021

17. The Influence of Disturbance Dynamo Electric Field in the Formation of Strong SporadicELayers Over Boa Vista, a Low‐Latitude Station in the American Sector

Author

V. F. Andrioli, I. S. Batista, Cunguo Wang, Junru Shi, L. A. Da Silva, Clezio Marcos Denardini, J. Moro, Christina Arras, Z. X. Liu, P. A. B. Nogueira, Laysa Cristina Araujo Resende, P. F. Barbosa, and A. J. Carrasco

Subjects

Geophysics, Disturbance (geology), Low latitude, Space and Planetary Science, Electric field, Sporadic E propagation, Geology, Dynamo

Abstract

This study analyzes strong sporadic E layer (Es) formation in Boa Vista (BV, 2.8°N, 60.7°W, dip: 18°), a low‐latitude region in the Brazilian sector, which occurred far after the onset of a magnetic storm recovery phase. Such occurrences were observed during seven magnetic storms with available data for BV. Thus, the ionospheric behavior on days around the magnetic storm that occurred on 20 January 2016 was investigated to search for possible explanations. This analysis indicated that the probable mechanism acting during the Es layer strengthening is the zonal westward electric field caused by a disturbance dynamo. The same evidence was also observed in two other magnetic storms at the same location. Hence, a numerical model of the E region dynamics, called MIRE (Portuguese acronym for E Region Ionospheric Model), was used to confirm whether the disturbance dynamo could cause the Es layer intensification. The inputs for the model were the electric field deduced from the vertical drift and the wind components provided by GSWM‐00 model. The simulations indicate that the Es layer density is significantly enhanced when the zonal electric field is present compared to the reference scenario with only the winds. Therefore, it is concluded that the disturbance dynamo electric field is the likely cause of the strong Es layers in the analyzed cases. Finally, the combined results from the model and observational data seem to contribute significantly to advance our understanding of the role of the electric fields in the Es layer formation at low latitudes.

Published

2020

18. The influence of tidal winds in the formation of blanketing sporadic e-layer over equatorial Brazilian region

Author

J. Moro, Clezio Marcos Denardini, Inez S. Batista, Laysa Cristina Araujo Resende, V. F. Andrioli, Paulo Batista, and A. J. Carrasco

Subjects

Physics, Atmospheric Science, Momentum (technical analysis), Electron density, 010504 meteorology & atmospheric sciences, Blanketing, Geophysics, Atmospheric sciences, Sporadic E propagation, 01 natural sciences, Ion, Trustworthiness, Space and Planetary Science, Mire, Physics::Space Physics, 0103 physical sciences, 010303 astronomy & astrophysics, Layer (electronics), 0105 earth and related environmental sciences

Abstract

This work analysis the blanketing sporadic layers (Es b ) behavior over Sao Luis, Brazil (2° 31′ S, 44° 16′ W, dip: −4.80) which is classified as a transition region between equatorial and low-latitude. Hence, some peculiarities can appear as Es b occurrence instead of the common Es q , which is a non-blanketing irregularity layer. The analysis presented here was obtained using a modified version of a theoretical model for the E region (MIRE), which computes the densities of the metallic ions (Fe + and Mg + ) and the densities of the main molecular ions (NO + , O 2 + , N 2 + ) by solving the continuity and momentum equations for each one of them. In that model, the Es layer physics driven by both diurnal and semidiurnal tidal winds are taken into account and it was extended in height coverage by adding a novel neutral wind model derived from the all-sky meteor radar measurements. Thus, we provide more trustworthy results related to the Es layer formation in the equatorial region. We verified the contribution of each tidal wind component to the Es b layer formation in this equatorial region. Additionally, we compared the Es layer electron density computed by MIRE with the data obtained by using the blanketing frequency parameter ( fb Es) deduced from ionograms. The results show that the diurnal component of the tidal wind is more important in the Es b layer formation whereas the semidiurnal component has a little contribution in our simulations. Finally, it was verified that the modified MIRE presented here can be used to study the Es b layers occurrence over the equatorial region in the Brazilian sector.

Published

2018

19. Simultaneous lidar observation of peculiar sporadic K and Na layers at São José dos Campos (23.1°S, 45.9°W), Brazil

Author

A. A. Pimenta, Clezio Marcos Denardini, Paulo Batista, Chi Wang, Xuewu Cheng, Guotao Yang, Jihong Wang, Z. X. Liu, Jing Jiao, Zhenzhong Yan, and V. F. Andrioli

Subjects

Atmospheric Science, Materials science, 010504 meteorology & atmospheric sciences, Potassium, Sodium, Analytical chemistry, Aerospace Engineering, chemistry.chemical_element, Sodium layer, Astronomy and Astrophysics, 010502 geochemistry & geophysics, Sporadic E propagation, 01 natural sciences, Geophysics, Lidar, chemistry, Space and Planetary Science, Mesopause, General Earth and Planetary Sciences, Layer (electronics), 0105 earth and related environmental sciences, K channels

Abstract

We present the first simultaneous observation of mesopause sodium (Na) and potassium (K) layer by a lidar which has Na and K channel simultaneously at the South Hemisphere site, Sao Jose dos Campos (23.1°S, 45.9°W). Measurements reported here were conducted on two nights with 3.5 and 8 h of observations in November 2016. On 20 November 2016, sporadic layers in both Na and K layer occurred above 100 km, and the higher layers corresponded well with sporadic E (Es) layer. And the density of Na at 100–105 km is higher than that at main layer around 90 km, but K density around 100 km is at least 3 times smaller compared with the K density around 90 km for the similar period. On 21 November 2016, both sporadic layers occurred in main layer height with obvious descending variations with time, which seems like tidal induced. Notably, the peak K/Na ratio slowly increased with time. And Na layer and K layer showed different processes along with time with K density reaching its maximum 1 h later than that of Na. Correlations of Na/K density, Es, and winds were also discussed.

Published

2018

20. Strong temperature gradients and vertical wind shear on MLT region associated to instability source at 23°S

Author

Liu Zhengkuan, Guotao Yang, Wang Chi, V. F. Andrioli, Paulo Batista, and Jiyao Xu

Subjects

Physics, Geophysics, 010504 meteorology & atmospheric sciences, Convective instability, Space and Planetary Science, Wind shear, 0103 physical sciences, Dynamical instability, Mechanics, 01 natural sciences, Instability, 010305 fluids & plasmas, 0105 earth and related environmental sciences

Published

2017

21. Simulations of blanketing sporadic E-layer over the Brazilian sector driven by tidal winds

Author

J. Moro, V. F. Andrioli, Inez S. Batista, Paulo Batista, Laysa Cristina Araujo Resende, Clezio Marcos Denardini, and A. J. Carrasco

Subjects

Atmospheric Science, Momentum (technical analysis), Work (thermodynamics), Electron density, 010504 meteorology & atmospheric sciences, Blanketing, Geophysics, Sporadic E propagation, 01 natural sciences, Computational physics, Space and Planetary Science, Mire, Wind shear, 0103 physical sciences, Ionosphere, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences

Abstract

This work presents new results about simulations of blanketing sporadic E-layers, Esb, using a modified version of a theoretical model for the E region (MIRE) for a Brazilian region: Cachoeira Paulista, a low latitude station. MIRE computes the densities of the metallic ions (Fe+ and Mg+) and of the main molecular ions (NO+, O2+, N2+) by solving the continuity and momentum equations for each one of them. Additionally, this model includes the physics of Es layer development driven by tidal winds. In this study, we extend MIRE adding a novel neutral wind model derived from the all-sky meteor radar measurements, which provides more trustworthy results related to the Es layer formation in the Brazilian sector. Afterwards, this new model is validated comparing the computed electron density for the Es layer with the electron density obtained using the blanketing frequency parameter (fbEs) deduced from ionograms in the analyzed region. The results show that the values computed by the extended MIRE are in good agreement with the observational data for the Es layers formed by the wind shear mechanism. Therefore, the extended MIRE presented in this work is the only available model that allows simulating Esb layers with a much higher confidence level for the low-latitude in the Brazilian sector.

Published

2017

22. The technical optimization of Na-K lidar and to measure mesospheric Na and K over Brazil

Author

V. F. Andrioli, Yuan Xia, Fuju Wu, Jing Jiao, Xuewu Chen, A. A. Pimenta, Paulo Batista, Jihong Wang, Xin Lin, Z. X. Liu, Guotao Yang, Faquan Li, and Lifang Du

Subjects

Physics, Radiation, Photon, business.industry, Laser, Atomic and Molecular Physics, and Optics, law.invention, Telescope, Laser linewidth, Wavelength, Optics, Lidar, law, business, Image resolution, Spectroscopy, Noise (radio)

Abstract

This paper reports that the sodium–potassium (Na–K) lidar was completed in November 2016 at Sao Jose Dos Compose, Brazil (23°S, 45°W), by the joint effort of the National Space Science Center, Chinese Academy of Sciences (NSSC) and Instituto Nacional de Pesquisas Espaciais (INPE). This system realized the Na and K metal layers simultaneously observe in Brazil, and this is the first instance of K layer detection in South America. Some of the key parameters and technologies have been optimized based on the Na and K layer dual-wave lidar in Beijing Yanqing station, such as improve technical parameters for receiving telescope, the narrow linewidth, efficient laser frequency doubling, the wavelength automatic locking techniques. By adopting these technologies, the output were 589 nm and 770 nm lasers, with high emission powers of 75 mJ and 83 mJ, respectively, and backscattered signals of Na and K layers with high signal quality were obtained. Observation data showed that the original echo photon count of the Na layer was approximately 42,486 (time resolution: 200 s, spatial resolution: 96 m) and the number of noise photons was 286 in a single data acquisition. The signal-to-noise ratio was up to 205:1. At the same spatiotemporal resolution, the original echo photon count of the K layer was approximately 1633, the noise photons were 38, and the signal-to-noise ratio was up to 40:1. The initial photocounts received has demonstrated that the Brazil K lidar has produced high quality signal with signal-to-noise level required by intended science studies. Moreover, the simultaneous phenomena of sporadic Na (Nas) and sporadic K (Ks), and the highly concentrated layers of atomic K have been observed, the K density in these narrow layers exceeds 1019 cm−3.

Published

2021

23. Vertical winds and momentum fluxes due to equatorial planetary scale waves using all-sky meteor radar over Brazilian region

Author

Paulo Batista, F. Egito, and V. F. Andrioli

Subjects

Meteor (satellite), Atmospheric Science, Momentum (technical analysis), 010504 meteorology & atmospheric sciences, Equinox, Atmospheric sciences, 01 natural sciences, Atmosphere, Geophysics, Amplitude, Space and Planetary Science, Physics::Space Physics, 0103 physical sciences, Solstice, Mean flow, Astrophysics::Earth and Planetary Astrophysics, Thermosphere, 010303 astronomy & astrophysics, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences

Abstract

In the equatorial region planetary scale waves play an important role transporting significant amount of energy and momentum through atmosphere. Quantifying the momentum transported by these waves and its effects on the mean flow is rather important. Direct estimates of the momentum flux transported by waves require horizontal and vertical wind measurements. Ground-based meteor radars have provided continuous and reliable measurements of the horizontal wind components in the Mesosphere and Lower Thermosphere (MLT) region and have contributed to improve our knowledge of the dynamics of this region. However, instrumental limitations hinder its use for measuring vertical winds and momentum fluxes. On the other hand, according to Babu et al (2012), all- sky meteor radars are able to infer tridimensional winds when using a large number of meteor echoes centered at the meteor ablation peak. Following this approach, we have used measurements performed by a Meteor Radar installed at Sao Joao do Cariri, Brazil (7.4°S; 36.5°W) in order to measure vertical winds and calculate the momentum flux transported by equatorial planetary scale waves. In order to evaluate the accuracy of vertical wind values we have performed several tests based on a simple model considering real meteor distributions and theoretical equations for the MLT winds motion. From our tests, we inferred that Brazilian meteor radar data can be used for this purpose with an accuracy of ~ 1.8 m/s. The results show that the vertical wind presents magnitudes of a few meters per second and occasionally reaches magnitudes around 10 m/s. Below 92 km the vertical wind is predominantly upward during the whole year and above exhibits a semi-annual oscillation with downward phase during the equinoxes. Variations associated to planetary scale waves in the vertical wind are also observed and some of them appear simultaneously in the zonal and meridional wind as well. Largest wave induced amplitudes in the vertical wind are found in the 3–4 d band, reaching up to 4 m/s. From the vertical and zonal wind measurements, we calculated the vertical transport of zonal momentum in the 3–4 d band and found it to be maximum near autumn equinox, when its value reaches almost 20 m2/s2, while minimum momentum flux is observed after the winter solstice.

Published

2016

24. Multi-year observations of gravity wave momentum fluxes at low and middle latitudes inferred by all-sky meteor radar

Author

Barclay Clemesha, V. F. Andrioli, Ricardo Buriti, Nelson Jorge Schuch, and Paulo Batista

Subjects

Atmospheric Science, Momentum (technical analysis), media_common.quotation_subject, lcsh:QC801-809, Geology, Astronomy and Astrophysics, Zonal and meridional, Atmospheric sciences, lcsh:QC1-999, Latitude, lcsh:Geophysics. Cosmic physics, Altitude, Space and Planetary Science, Sky, Middle latitudes, Earth and Planetary Sciences (miscellaneous), lcsh:Q, Gravity wave, Thermosphere, lcsh:Science, lcsh:Physics, media_common

Abstract

We have applied a modified composite day analysis to the Hocking (2005) technique to study gravity wave (GW) momentum fluxes in the mesosphere and lower thermosphere (MLT). Wind measurements from almost continuous meteor radar observations during June 2004–December 2008 over São João do Cariri (Cariri; 7° S, 36° W), April 1999–November 2008 over Cachoeira Paulista (CP; 23° S, 45° W), and February 2005–December 2009 over Santa Maria (SM; 30° S, 54° W) were used to estimate the GW momentum fluxes and variances in the MLT region. Our analysis can provide monthly mean altitude profiles of vertical fluxes of horizontal momentum for short-period (less than 2–3 h) GWs. The averages for each month throughout the entire data series have shown different behavior for the momentum fluxes depending on latitude and component. The meridional component has almost the same behavior at the three sites, being positive (northward), for most part of the year. On the other hand, the zonal component shows different behavior at each location: it is positive for almost half the year at Cariri and SM but predominantly negative over CP. Annual variation in the GW momentum fluxes is present at all sites in the zonal component and also in SM at 89 km in the meridional component. The seasonal analysis has also shown a 4-month oscillation at 92.5 km over SM in the zonal component and over CP at the same altitudes but for the meridional component.

Published

2015

25. Competition between winds and electric fields in the formation of blanketing sporadic E layers at equatorial regions

Author

Clezio Marcos Denardini, Inez S. Batista, J. Moro, A. J. Carrasco, Laysa Cristina Araujo Resende, Paulo Batista, S. S. Chen, and V. F. Andrioli

Subjects

010504 meteorology & atmospheric sciences, Geology, Blanketing, Geophysics, Sporadic E propagation, 01 natural sciences, Momentum, Space and Planetary Science, Electric field, 0103 physical sciences, Ionosphere, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

In the present work, we analyze the competition between tidal winds and electric fields in the formation of blanketing sporadic E layers (Esb) over Sao Luis, Brazil (2° 31′ S, 44° 16′ W), a quasi-equatorial station. To investigate this competition, we have used an ionospheric E region model (MIRE) that is able to model the Esb layers taking into account the E region winds and electric fields. The model calculates the densities for the main molecular and metallic ions by solving the continuity and momentum equations for each of the species. Thus, the main purpose of this analysis is to verify the electric fields role in the occurrence or disruption of Esb layers through simulations. The first results of the simulations show that the Esb layer is usually present when only the tidal winds were considered. In addition, when the zonal component of the electric field is introduced in the simulation, the Esb layers do not show significant changes. However, the simulations show the disruption of the Esb layers when the vertical electric field is included. In this study, we present two specific cases in which Esb layers appear during some hours over Sao Luis. We can see that these layers appear when the vertical electric field was weak, which means that the tidal components were more effective during these hours. Therefore, the vertical component of the electric field is the main agent responsible for the Esb layer disruption.

Published

2016

26. Investigation of solar cycle dependence of the tides in the low latitude MLT using meteor radar observations

Author

Paulo Batista, V. F. Andrioli, and A. Guharay

Subjects

Meteor (satellite), Atmospheric Science, Low latitude, 010504 meteorology & atmospheric sciences, Zonal and meridional, Meteor radar, Atmospheric sciences, 01 natural sciences, Solar cycle, Geophysics, Altitude, Space and Planetary Science, 0103 physical sciences, Environmental science, Thermosphere, Maxima, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

Solar cycle dependence of the dominant tides, i.e. diurnal and semidiurnal components in the mesosphere and lower thermosphere (MLT) is investigated from a Southern hemispheric low-latitude station, Cachoeira Paulista (22.7oS, 45oW) using long-term meteor wind observations (1999–2018). Although the long-term variations of the tides in aggregate do not show any significant relationship with the solar activity, the individual seasonal profiles reveal appreciable correlation in equinoxes with maximum in fall and no evident correlation in summer. The diurnal tide seasonal profiles show negative correlation with the solar activity and the semidiurnal tide exhibits both negative and positive correlations that vary with altitude within the MLT. The zonal diurnal tide shows positive correlation with the solar flux in the upper MLT in solar minima. However, the meridional semidiurnal tide reveals negative correlation in solar minima condition. No evident relationship between the tides and solar flux is found in solar maxima condition. Since the present study points out resemblance as well as dissimilarity with a handful of previous investigations, further long-term and coordinated studies are being sought to obtain critical understanding of the persistent enigmatic features.

Published

2019

27. EquatorialERegion Electric Fields and SporadicELayer Responses to the Recovery Phase of the November 2004 Geomagnetic Storm

Author

Clezio Marcos Denardini, Paulo Batista, Nelson Jorge Schuch, A. J. Carrasco, J. Moro, Laysa Cristina Araujo Resende, Jiexin Xu, V. F. Andrioli, and I. S. Batista

Subjects

Geomagnetic storm, 010504 meteorology & atmospheric sciences, Geophysics, Space weather, Sporadic E propagation, 01 natural sciences, Space and Planetary Science, Electric field, 0103 physical sciences, 010303 astronomy & astrophysics, Layer (electronics), Geology, 0105 earth and related environmental sciences, Recovery phase

Published

2017

28. Diurnal variation in gravity wave activity at low and middle latitudes

Author

Diego Janches, D. C. Fritts, Barclay Clemesha, V. F. Andrioli, and Paulo Batista

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Atmospheric sciences, 01 natural sciences, Mesosphere, Latitude, Wind shear, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Solstice, Gravity wave, lcsh:Science, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Diurnal temperature variation, lcsh:QC801-809, Geology, Astronomy and Astrophysics, lcsh:QC1-999, lcsh:Geophysics. Cosmic physics, 13. Climate action, Space and Planetary Science, Middle latitudes, lcsh:Q, Thermosphere, lcsh:Physics

Abstract

We employ a modified composite day extension of the Hocking (2005) analysis method to study gravity wave (GW) activity in the mesosphere and lower thermosphere using 4 meteor radars spanning latitudes from 7° S to 53.6° S. Diurnal and semidiurnal modulations were observed in GW variances over all sites. Semidiurnal modulation with downward phase propagation was observed at lower latitudes mainly near the equinoxes. Diurnal modulations occur mainly near solstice and, except for the zonal component at Cariri (7° S), do not exhibit downward phase propagation. At a higher latitude (SAAMER, 53.6° S) these modulations are only observed in the meridional component where we can observe diurnal variation from March to May, and semidiurnal, during January, February, October (above 88 km) and November. Some of these modulations with downward phase progression correlate well with wind shear. When the wind shear is well correlated with the maximum of the variances the diurnal tide has its largest amplitudes, i.e., near equinox. Correlations exhibiting variations with tidal phases suggest significant GW-tidal interactions that have different characters depending on the tidal components and possible mean wind shears. Modulations that do not exhibit phase variations could be indicative of diurnal variations in GW sources.

Published

2013

29. Improved analysis of all-sky meteor radar measurements of gravity wave variances and momentum fluxes

Author

D. C. Fritts, Paulo Batista, V. F. Andrioli, and Barclay Clemesha

Subjects

Meteor (satellite), Atmospheric Science, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, 01 natural sciences, Measure (mathematics), Altitude, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Gravity wave, lcsh:Science, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, media_common, Physics, Momentum (technical analysis), lcsh:QC801-809, Geology, Astronomy and Astrophysics, Geophysics, lcsh:QC1-999, Interferometry, lcsh:Geophysics. Cosmic physics, Amplitude, Space and Planetary Science, Sky, lcsh:Q, Astrophysics::Earth and Planetary Astrophysics, lcsh:Physics

Abstract

The advantages of using a composite day analysis for all-sky interferometric meteor radars when measuring mean winds and tides are widely known. On the other hand, problems arise if this technique is applied to Hocking's (2005) gravity wave analysis for all-sky meteor radars. In this paper we describe how a simple change in the procedure makes it possible to use a composite day in Hocking's analysis. Also, we explain how a modified composite day can be constructed to test its ability to measure gravity wave momentum fluxes. Test results for specified mean, tidal, and gravity wave fields, including tidal amplitudes and gravity wave momentum fluxes varying strongly with altitude and/or time, suggest that the modified composite day allows characterization of monthly mean profiles of the gravity wave momentum fluxes, with good accuracy at least at the altitudes where the meteor counts are large (from 89 to 92.5 km). In the present work we also show that the variances measured with Hocking's method are often contaminated by the tidal fields and suggest a method of empirical correction derived from a simple simulation model. The results presented here greatly increase our confidence because they show that our technique is able to remove the tide-induced false variances from Hocking's analysis.

Published

2013

30. Atmospheric tides and mean winds in the meteor region over Santa Maria (29.7°S; 53.8°W)

Author

Paulo Batista, Nelson Jorge Schuch, V. F. Andrioli, and Barclay Clemesha

Subjects

Meteor (satellite), Atmospheric Science, Wave model, Wavelength, Geophysics, Amplitude, Meteoroid, Space and Planetary Science, Atmospheric tide, Annual variation, Meteor radar, Atmospheric sciences, Geology

Abstract

We compare meteor radar measurements of the MLT region winds at Santa Maria, Brazil (29.7°S, 53.8°W) with the Horizontal Neutral Wind Model (HWM-93) and the Global Scale Wave Model (GSWM-00). The observed annual variation of the prevailing zonal wind disagrees in some respects with the HWM-93 model. Also, the zonal diurnal tide amplitude shows an annual variation, whereas that of the GSWM-00 is semiannual, and its vertical wavelength is smaller than that suggested by the model. The observed semidiurnal tide shows seasonal and inter-annual variations and the phase is evanescent during almost the whole year.

Published

2009

31. Positive and negative sudden impulses caused by fast forward and reverse interplanetary shocks

Author

Ezequiel Echer, Nelson Jorge Schuch, Jairo Francisco Savian, and V. F. Andrioli

Subjects

Physics, Solar wind, sudden impulses, Magnetosphere, Geophysics, magnetosfera, interplanetary shock waves, impulsos súbitos, Computational physics, ondas de choque interplanetárias, Earth's magnetic field, Amplitude, Physics::Space Physics, magnetosphere, Jump, Vento solar, Dynamic pressure, Interplanetary magnetic field, Interplanetary spaceflight

Abstract

Fast forward interplanetary shocks (FFS) are characterized by positive jump in all interplanetary plasma parameters (solar wind speed, temperature and density) and interplanetary magnetic field. However the fast reverse interplanetary shocks (FRS) are characterized by negative jump in all mentioned parameters except solar wind speed. Observations show that FFS cause positive sudden impulses (SI) while FRS cause negative SI in the H-component of the geomagnetic field. In this work we investigate the SI caused by interplanetary shocks. We use the observed plasma parameters, upstream and downstream, to calculate the variation of dynamic pressure. We observe that the SI amplitude is larger for positive SI than for negative ones, as a consequence of the fact that FFS have larger dynamic pressure variations as compared to FRS. Choques interplanetários do tipo frontal rápido (FFS) são caracterizados por uma descontinuidade súbita positiva em todos os parâmetros de plasma interplanetário (velocidade, temperatura e densidade do vento solar) e campo magnético interplanetário. Os choques do tipo reverso rápido (FRS) possuem descontinuidade súbita negativa em todos os parâmetros exceto a velocidade do vento solar. Observa-se que os FFS causam impulsos súbitos (SI) positivos e os FRS causam SI negativos na componente H do campo magnético terrestre. Neste trabalho realizou-se um estudo destes impulsos súbitos, causados por choques interplanetários. Utilizaram-se os parâmetros de plasma, antes e depois do choque, para calcular a variação da pressão dinâmica. Observou-se que os SIs são maiores quando causados por FFS que quando formados por FRS, isto porque os FFS possuem maior variação na pressão dinâmica que os FRS.

Published

2007

32. Observation of a mesospheric front in a dual duct over King George Island, Antarctica

Author

José Valentin Bageston, Robert Hibbins, V. F. Andrioli, D. C. Fritts, Paulo Batista, Cristiano Max Wrasse, and Delano Gobbi

Subjects

medicine.anatomical_structure, GEORGE (programming language), Meteorology, Climatology, medicine, Duct (anatomy), Geology, Front (military)

Abstract

A mesospheric bore was observed with an all-sky airglow imager on the night of 9–10 July 2007 at Ferraz Station (62° S, 58° W), located on King George island on the Antarctic Peninsula. The observed bore propagated from southwest to northeast with a well defined wave front and a series of crests behind the main front. There was no evidence of dissipation during its propagation within the field of view. The wave parameters were obtained via a 2-D Fourier transform of the imager data providing a horizontal wavelength of 33 km, an observed period of 6 min, and a horizontal phase speed of 92 m s−1. Simultaneous mesospheric winds were measured with a medium frequency (MF) radar at Rothera Station (68° S, 68° W) and temperature profiles were obtained from the SABER instrument on the TIMED satellite. These wind and temperature profiles were used to estimate the propagation environment of the bore. A wavelet technique was applied to the wind in the plane of bore propagation at the OH emission height spanning three days centered on the bore event to define the dominant periodicities. Results revealed a dominance of near-inertial periods, and semi-diurnal and terdiurnal tides suggesting that the ducting structure enabling bore propagation occurred on large spatial scales. The observed tidal motions were used to reconstruct the winds employing a least-squares method, which were then compared to the observed ducting environment. Results suggest an important contribution of large-scale winds to the ducting structure, but with buoyancy frequency variations in the vertical also expected to be important. These results allow us to conclude that the bore was supported by a duct including contributions from both winds and temperature (or stability). A co-located airglow temperature imager operated simultaneously with the all-sky imager confirmed that the bore event was the dominant small-scale wave event during the analysis interval.

Published

2011

33. Supplementary material to 'Observation of a mesospheric front in a dual duct over King George Island, Antarctica'

Author

J. V. Bageston, C. M. Wrasse, P. P. Batista, R. E. Hibbins, D. C. Fritts, D. Gobbi, and V. F. Andrioli

Published

2011

34. Observation of a mesospheric front in a thermal-doppler duct over King George Island, Antarctica

Author

V. F. Andrioli, Cristiano Max Wrasse, Delano Gobbi, José Valentin Bageston, Paulo Batista, Robert Hibbins, and David C. Fritts

Subjects

Atmospheric Science, Meteorology, Creative commons, lcsh:QC1-999, Physics::Geophysics, lcsh:Chemistry, symbols.namesake, lcsh:QD1-999, Climatology, Physics::Space Physics, symbols, Duct (flow), Doppler effect, Geology, lcsh:Physics, Physics::Atmospheric and Oceanic Physics

Abstract

A mesospheric front was observed with an all-sky airglow imager on the night of 9–10 July 2007 at Ferraz Station (62° S, 58° W), located on King George island on the Antarctic Peninsula. The observed wave propagated from southwest to northeast with a well defined wave front and a series of crests behind the main front. The wave parameters were obtained via a 2-D Fourier transform of the imager data providing a horizontal wavelength of 33 km, an observed period of 6 min, and a horizontal phase speed of 92 m s−1. Simultaneous mesospheric winds were measured with a medium frequency (MF) radar at Rothera Station (68° S, 68° W) and temperature profiles were obtained from the SABER instrument on the TIMED satellite. These wind and temperature profiles were used to estimate the propagation environment of the wave event. A wavelet technique was applied to the wind in the plane of wave propagation at the OH emission height spanning three days centered on the front event to define the dominant periodicities. Results revealed a dominance of near-inertial periods, and semi-diurnal and terdiurnal tides suggesting that the ducting structure enabling mesospheric front propagation occurred on large spatial scales. The observed tidal motions were used to reconstruct the winds employing a least-squares method, which were then compared to the observed ducting environment. Results suggest an important contribution of large-scale winds to the ducting structure, but with buoyancy frequency variations in the vertical also expected to be important. These results allow us to conclude that the wave front event was supported by a duct including contributions from both winds and temperature. © Author(s) 2011. This work is distributed under the Creative Commons Attribution 3.0 License.

Published

2011

35. Case study of a mesospheric wall event over Ferraz station, Antarctica (62 degrees S)

Author

J. V. Bageston, C. M. Wrasse, R. E. Hibbins, P. P. Batista, D. Gobbi, H. Takahashi, V. F. Andrioli, J. Fechine, and C. M. Denardini

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Imaging spectrometer, 01 natural sciences, Temperature measurement, law.invention, law, Dispersion relation, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Duct (flow), Radar, lcsh:Science, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Physics, lcsh:QC801-809, Airglow, Geology, Astronomy and Astrophysics, Rotational temperature, Geophysics, lcsh:QC1-999, lcsh:Geophysics. Cosmic physics, Amplitude, Space and Planetary Science, lcsh:Q, lcsh:Physics

Abstract

On 16–17 July 2007 during an observational campaign at Comandante Ferraz Antarctic Station (62° S, 58° W), a mesospheric wall was observed with an airglow all-sky imager. The wave appeared like an extensive dark region in the all-sky airglow images, with a large depletion in the OH emission. Simultaneous mesospheric winds measured with a MF radar at Rothera station and temperature profiles from SABER instrument, on board of TIMED satellite, were used to obtain the propagation condition of the wave. Wind measurements during four days, around the time of observation of the wave, are presented in order to discuss the type and consistence of the duct in which this wave was propagating. By using wavelet analysis and tidal amplitude components we found that 12 and 8 h components were the most important periodicities around the time interval of the wave observation. A collocated imaging spectrometer, for mesospheric temperature measurements, has been operated simultaneously with the all-sky imager. Direct effects of the mesospheric front have been seen in the spectrometric measurements, showing an abrupt decrease in both OH intensity and rotational temperature when the wave front passes overhead. The main contribution of the present work is the investigation of the type of duct in which the wall event was propagating. We found evidences for a thermal duct structure to support the mesospheric wall propagation. This result was obtained by two types of analysis: (a) the tidal components analysis and winds filtering (harmonic analysis), and (b) comparison between the terms of the m2 dispersion relation. © Author(s) 2011. This work is distributed under the Creative Commons Attribution 3.0 License.

Published

2011

36. Forbush decreases in November 6-20, 2004 observed by the Muon Detector Network

Author

Alisson Dal Lago, John W. Bieber, Nelson Jorge Schuch, Luis Eduardo Antunes Vieira, Ezequiel Echer, Walter Demétrio Gonzalez Alarcon, Marlos Rockenbach da Silva, Kazuoki Munakata, Jairo Francisco Savian, V. F. Andrioli, and G. I. Pugacheva

Subjects

medicine.medical_specialty, Muon, Physics::Instrumentation and Detectors, Detector, Astronomy, Cosmic ray, Space weather, Telmatology, Physics::Space Physics, medicine, Coronal mass ejection, Physics::Accelerator Physics, High Energy Physics::Experiment, Interplanetary spaceflight, Geomorphology, Geology, Muon detector

Abstract

In this paper we study the relationship between Interplanetary Coronal Mass Ejections (ICMEs) and the count rate muon decrease detected by the muon detector network in November 6-20, 2004. The Muon Detector Network is composed by the detectors installed in Nagoya (Japan), Hobart (Australian) and the prototype detector installed in the “Observatorio Espacial do Sul – OES/CRSPE/INPE-MCT”, located in Sao Martinho da Serra, RS, Brazil. With the muons count rate observed by the Muon Detector Network, we will be able to observe, in the future,the direction in which a given ICME moves, and with that, we will be able to calculate the angle which they reach the Earth. Also, with this muon network, we will be able to send alerts of up to 12 hours before the arrival of a shock or an ICME. The Space Weather forecast method using cosmic rays will be a very important tool because it provides a forecast with good antecedence.

Published

2005

37. Um estudo sobre es ondas de choque no meio interplanetário

Author

Nelson Jorge Schuch, V. F. Andrioli, Jairo Francisco Savian, and Ezequiel Echer

Abstract

O meio interplanetario, o espaco entre os planetas e o Sol, esta permeado pelo vento solar que e a propria atmosfera solar se expandindo no espaco interplanetario. Esta atmosfera e composta por um plasma tenue magnetizado o qual favorece a acao das forcas Coulombianas de longo alcance. Estas pela presenca deste campo magnetico, conseguem exercer seu papel que e o de transferencia de momentum e informacao as particulas provenientes do Sol. Qualquer mudanca na atividade solar se reflete no meio interplanetario devido a transferencia de informacoes. A agitacao do Sol, consequencia de sua constante atividade, e transmitida ao vento solar e frequentemente produz Ondas de Choque. E possivel, com o estudo das variacoes dos parâmetros interplanetarios como: densidade, temperatura e velocidade do vento solar e intensidade do campo magnetico interplanetario – CMI, identificar a presenca desses choques e calcular sua velocidade, intensidade e direcao. Neste trabalho utilizamos dados de plasma e CMI fornecidos pelo sistema de dados On-line da sonda ACE – Advanced Composition Explorer, para fazer um estudo acerca de ondas de choque, analisando os graficos de dados destes eventos e classificando-os, segundo os perfis dos choques feitos por E. Echer et al. [2003], em choques frontais, rapidos e lentos; ou reversos, rapidos e lentos. Este estudo deteve-se ao periodo de 2002 – 2003, que corresponde ao declinio do Ciclo Solar 23.

Published

2005

38. Previsão de Tempestades Geomagnéticas Intensas através da observação de raios cósmicos e de componentes do Meio Interplanetário

Author

Luis Eduardo Antunes Vieira, Ezequiel Echer, Alisson Dal Lago, Marlos Rockenbach da Silva, Kazuoki Munakata, Walter Demétrio Gonzalez Alarcon, Nelson Jorge Schuch, Marcos Roberto Signori, Jairo Francisco Savian, and V. F. Andrioli

Abstract

Acredita-se que o mecanismo fisico responsavel pela transferencia de energia do Vento Solar para a Magnetosfera seja a reconexao entre o Campo Magnetico Interplanetario e o Campo Magnetico Terrestre - Tsurutani e Gonzalez, 1997. O criterio necessario para que ocorra uma Tempestade Geomagnetica Intensa, Dst Interplanetario, na direcao do anoitecer, maior que 5mV/m, por um periodo maior que 3 horas. O objetivo do trabalho e comparar a previsao de Tempestades Geomagneticas feita por satelites localizados no ponto Lagrangeano - L1, e a Rede Internacional de Detectores de Muons, mostrando as vantagens e desvantagens de cada um.

Published

2004