Properties of solar wind turbulence from radio occultation experiments with the NOZOMI spacecraft

Radio-sounding experiments using signals from the Japanese NOZOMI spacecraft to probe the circum solar plasma were performed from December 2000 through January 2001. They can be used to obtain information about the properties of the solar wind plasma in the region where it is accelerated at heliocen...

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Bibliographic Details
Published in:Astronomy reports 2010-11, Vol.54 (11), p.1032-1041
Main Authors: Efimov, A. I., Imamura, T., Oyama, K. -I., Noguchi, K., Samoznaev, L. N., Nabatov, A. S., Bird, M. K., Chashei, I. V.
Format: Article
Language:English
Subjects:
Anisotropy
Astronomy
Fluctuations
Fluid dynamics
Fluid flow
Inhomogeneities
Observations and Techniques
Physics
Physics and Astronomy
Plasma
Radio astronomy
Solar physics
Spacecraft
Sun
Turbulence
Turbulent flow
Wind speed
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Summary:Radio-sounding experiments using signals from the Japanese NOZOMI spacecraft to probe the circum solar plasma were performed from December 2000 through January 2001. They can be used to obtain information about the properties of the solar wind plasma in the region where it is accelerated at heliocentric distances of 12.8–36.9 R s (where R s is the radius of the Sun). Measurements of the intensity and frequency of the received signals were carried out with high time resolution (∼0.05 s for the frequency and ∼0.0064 s for the intensity), making it possible to investigate the anisotropy of inhomogeneities and the spatial spectrum of the turbulence of the circum solar plasma. Analysis of these radio-sounding data has shown that the scintillation index and intensity of the frequency fluctuations decrease approximately according to a power law with increasing distance of the line of sight from the Sun. Measurements of the amplitude fluctuations and estimates of the solar wind velocity derived from spatially separated observations indicate the presence of small-scale inhomogeneities with sizes of the order of 50 km at heliocentric distances less than 25 R s , which are elongated in the radial direction with anisotropy coefficients from 2.3 to 3.0. The inhomogeneities at heliocentric distances exceeding 30 R s become close to isotropic.
ISSN:1063-7729
1562-6881
DOI:10.1134/S1063772910110089