Abstract
KNOWLEDGE of the structure of the Sun's corona is important for our understanding of how this high-temperature plasma is heated, and of the processes involved in the acceleration of the solar wind1,2. The structure can be investigated directly by imaging at optical and shorter wavelengths, or indirectly through the effects of changing electron density on the propagation of radio waves (scattering and scintillation). Radio measurements have established many of the characteristics of the density fluctuations in the corona and solar wind, but the fundamental nature of these structures is not yet fully understood3,4. Two specific features that have proved difficult to explain are an abrupt increase in anisotropy of the irregularities close to the Sun5–7, and a break in the power-law spectrum describing the density fluctuations8,9. Here I argue that these features are the manifestation of a transition from small ray-like or filamentary structures in the corona that rotate with the Sun to turbulent density irregularities convecting with the solar wind. I estimate the size of the smallest filamentary structure within coronal holes to be about 1km at the Sun, approximately three orders of magnitude smaller than the smallest filamentary structures observed in images of different wavelengths2,10–12.
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Woo, R. Kilometre-scale structures in the Sun's corona. Nature 379, 321–322 (1996). https://doi.org/10.1038/379321a0
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DOI: https://doi.org/10.1038/379321a0
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