91 research outputs found
MLT gravity wave climatology in the South America equatorial region observed by airglow imager
International audienceAn all-sky CCD imager for OH, O2 and OI (557.7 nm) airglow emission measurements was operated at São João do Cariri (Cariri), Brazil (7° S, 36° W), from October 2000 to December 2004. A large amount of image data, more than 3000 h of observation and around 1000 wave events, makes it possible to classify the gravity wave characteristics, which are statistically significant. The observed waves show a typically short horizontal wavelength (5?45 km) and a short period (5?35 min), and horizontal phase speeds of 1 to 80 m/s. In most cases band-type waves (horizontal wavelength between 10 and 60 km) showed a clear preference for the horizontal propagation direction from the South American continent to the Atlantic Ocean. Ripples also have similar features but with different anisotropy. In this paper we focus our discussion on the wave characteristics of the bands and ripples and a comparison between them
Espécies de Anastrepha Schiner (Diptera: Tephritidae), seus hospedeiros e parasitóides nos Estados do Acre e Rondônia, Brasil.
Durante o mês de março de 2009 foram realizadas amostragens de frutos carnosos nos Estados do Acre (municípios de Brasiléia, Bujari, Capixaba, Epitaciolândia, Rio Branco, Sena Madureira, Senador Guiomard e Xapuri) e Rondônia (Ariquemes, Candeias do Jamari, Itapuã do Oeste, Ouro Preto do Oeste e Porto Velho) visando ampliar o conhecimento sobre a diversidade de moscas-das-frutas (Diptera: Tephritidae), seus hospedeiros e parasitóides. Este trabalho constitui o primeiro registro de Anastrepha coronilli Carrejo & González (Tephritidae) para o Estado do Acre, e das espécies A. coronilli, A. distincta Greene (Tephritidae), e dos himenópteros Doryctobracon areolatus (Szépligeti) e Opius bellus Gahan (Braconidae) para Rondônia. Palavras-chave: Amazônia, Braconidae, Hymenoptera, moscas-das-frutas, Tephritoidea
Characteristics of Mesospheric Gravity Waves Near the Magnetic Equator, Brazil, During the SpreadFEx Campaign
As part of the SpreadFEx campaign, coordinated optical and radio measurements were made from Brazil to investigate the occurrence and properties of equatorial Spread F, and to characterize the regional mesospheric gravity wave field. All-sky image measurements were made from two sites: Brasilia and Cariri located ~10° S of the magnetic equator and separated by ~1500 km. In particular, the observations from Brasilia provided key data in relatively close proximity to expected convective sources of the gravity waves. High-quality image measurements of the mesospheric OH emission and the thermospheric OI (630 nm) emission were made during two consecutive new moon periods (22 September to 9 November 2005) providing extensive data on the occurrence and properties of F-region depletions and regional measurements of the dominant gravity wave characteristics at each site
Mesospheric Gravity Waves Observed Near Equatorial and Low-Middle Latitude Stations: Wave Characteristics and Reverse Ray Tracing Results
Gravity wave signatures were extracted from OH airglow observations using all-sky CCD imagers at four different stations: Cachoeira Paulista (CP) (22.7° S, 45° W) and São João do Cariri (7.4° S, 36.5° W), Brazil; Tanjungsari (TJS) (6.9° S, 107.9° E), Indonesia and Shigaraki (34.9° N, 136° E), Japan. The gravity wave parameters are used as an input in a reverse ray tracing model to study the gravity wave vertical propagation trajectory and to estimate the wave source region. Gravity waves observed near the equator showed a shorter period and a larger phase velocity than those waves observed at low-middle latitudes. The waves ray traced down into the troposphere showed the largest horizontal wavelength and phase speed. The ray tracing results also showed that at CP, Cariri and Shigaraki the majority of the ray paths stopped in the mesosphere due to the condition of m2\u3c0, while at TJS most of the waves are traced back into the troposphere. In summer time, most of the back traced waves have their final position stopped in the mesosphere due to m2\u3c0 or critical level interactions (|m|→∞), which suggests the presence of ducting waves and/or waves generated in-situ. In the troposphere, the possible gravity wave sources are related to meteorological front activities and cloud convections at CP, while at Cariri and TJS tropical cloud convections near the equator are the most probable gravity wave sources. The tropospheric jet stream and the orography are thought to be the major responsible sources for the waves observed at Shigaraki
Produção de novo ingrediente fonte de fibra alimentar à base de Galactomanana parcialmente hidrolisada de Caesalpinia pulcherrima (Flamboyanzinho).
bitstream/item/76732/1/Cot-128-31jan2013.pd
Seasonal characteristics of small- and medium-scale gravity waves in the mesosphere and lower thermosphere over the Brazilian equatorial region
The present work reports seasonal characteristics of small- and medium-scale
gravity waves in the mesosphere and lower thermosphere (MLT) region. All-sky
images of the hydroxyl (NIR-OH) airglow emission layer over São João do
Cariri (7.4° S, 36.5° W; hereafter Cariri) were obtained
from September 2000 to December 2010, during a total of 1496 nights. For
investigation of the characteristics of small-scale gravity waves (SSGWs) and
medium-scale gravity waves (MSGWs), we employed the Fourier two-dimensional
(2-D) spectrum and keogram fast Fourier transform (FFT) techniques,
respectively. From the 11 years of data, we could observe 2343 SSGW and 537
MSGW events. The horizontal wavelengths of the SSGWs were concentrated
between 10 and 35 km, while those of the MSGWs ranged from 50 to 200 km. The
observed periods for SSGWs were concentrated around 5 to 20 min, whereas the
MSGWs ranged from 20 to 60 min. The observed horizontal phase speeds of SSGWs
were distributed around 10 to 60 m s−1, and the corresponding
MSGWs were around 20 to 120 m s−1. In summer, autumn, and winter
both SSGWs and MSGWs propagated preferentially northeastward and
southeastward, while in spring the waves propagated in all directions. The
critical level theory of atmospheric gravity waves (AGWs) was applied to
study the effects of wind filtering on SSGW and MSGW propagation
directions. The SSGWs were more susceptible to wind filtering effects than
MSGWs. The average of daily mean outgoing longwave radiation (OLR) was also
used to investigate the possible wave source region in the troposphere. The
results showed that in summer and autumn, deep convective regions were the
possible source mechanism of the AGWs. However, in spring and winter the deep
convective regions did not play an important role in the waves observed at
Cariri, because they were too far away from the observatory. Therefore, we
concluded that the horizontal propagation directions of SSGWs and MSGWs show
clear seasonal variations based on the influence of the wind filtering
process and wave source location
The spread-F Experiment (SpreadFEx): Program overview and first results
We performed an extensive experimental campaign (the spread F Experiment, or SpreadFEx) from September to November 2005 to attempt to define the role of neutral atmosphere dynamics, specifically wave motions propagating upward from the lower atmosphere, in seeding equatorial spread F and plasma bubbles extending to higher altitudes. Campaign measurements focused on the Brazilian sector and included ground-based optical, radar, digisonde, and GPS measurements at a number of fixed and temporary sites. Related data on convection and plasma bubble structures were also collected by GOES 12 and the GUVI instrument aboard the TIMED satellite. Initial results of our analyses of SpreadFEx and related data indicate 1) extensive gravity wave (GW) activity apparently linked to deep convection predominantly to the west of our measurement sites, 2) the presence of small-scale GWactivity confined to lower altitudes, 3) larger-scaleGWactivity apparently penetrating to much higher altitudes suggested by electron density and TEC fluctuations in the E and F regions, 4) substantial GW amplitudes implied by digisonde electron densities, and 5) apparent direct links of these perturbations in the lower F region to spread F and plasma bubbles extending to much higher altitudes. Related efforts with correlative data are defining 6) the occurrence and locations of deep convection, 7) the spatial and temporal evolutions of plasma bubbles, the 8) 2D (height-resolved) structures of plasma bubbles, and 9) the expected propagation of GWs and tides from the lower atmosphere into the thermosphere and ionosphere
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