Observação da temperatura da alta atmosfera através de aeroluminescência

Abstract: Este trabalho tem por objetivo estudar a dinâmica caótica das ondas de Alfvén no vento solar. Este estudo é realizado em duas partes. Na primeira, motivado pelas observações simultâneas de ondas de Langmuir e ondas eletromagnéticas de baixa freqüência em buracos magnéticos no vento solar, propomos uma teoria baseada no processo de interação não-linear que envolve três ondas. Usamos o método de Poincaré para caraterizar a intermitência Pomeau-Manneville e mostrar dois exemplos de crise interior produzidos pela … Show more

“…The schematic optics diagram of FotAntar-1 and more information on the calibration process performed in this instrument can be found in Wrasse (2000) and Wrasse et al (2004).…”

“…In order to obtain the temperature and OH (8-3) band intensity, the photometer measures the spectrum of the P branch of OH (8-3), and by tilting the filter it can scan the wavelengths from 732 to 742 nm, solving the spectral lines P 1 (3) at 734 nm, P 1 (4) at 736.9 nm and P 1 (5) at 740.2 nm. The background position was chosen to be at 738.2 nm (Wrasse, 2000), and the time resolution of the temperature and intensities measurements was about 3.5 minutes. The intensity ratio between P 1 (5) and P 1 (3) was used to calculate the rotational temperature (associated to the rotational emission lines), or just temperature / kinetic temperature, which was obtained with a systematic error, due to the filter transmittance and PMT sensitivity, of ±2.5 K and an error in the OH (8-3) band intensity less than ± 6% (Wrasse 2000).…”

Historical line of airglow observations at Comandante Ferraz Brazilian Station: measurements of temperature and studies on gravity waves

“…The schematic optics diagram of FotAntar-1 and more information on the calibration process performed in this instrument can be found in Wrasse (2000) and Wrasse et al (2004).…”

“…In order to obtain the temperature and OH (8-3) band intensity, the photometer measures the spectrum of the P branch of OH (8-3), and by tilting the filter it can scan the wavelengths from 732 to 742 nm, solving the spectral lines P 1 (3) at 734 nm, P 1 (4) at 736.9 nm and P 1 (5) at 740.2 nm. The background position was chosen to be at 738.2 nm (Wrasse, 2000), and the time resolution of the temperature and intensities measurements was about 3.5 minutes. The intensity ratio between P 1 (5) and P 1 (3) was used to calculate the rotational temperature (associated to the rotational emission lines), or just temperature / kinetic temperature, which was obtained with a systematic error, due to the filter transmittance and PMT sensitivity, of ±2.5 K and an error in the OH (8-3) band intensity less than ± 6% (Wrasse 2000).…”

Historical line of airglow observations at Comandante Ferraz Brazilian Station: measurements of temperature and studies on gravity waves