The origins of hot plasma in the solar corona

B. De Pontieu; S. W. McIntosh; M. Carlsson; V. H. Hansteen; T. D. Tarbell; P. Boerner; J. Martinez-Sykora; C. J. Schrijver; A. M. Title

doi:10.1126/science.1197738

The origins of hot plasma in the solar corona

B. De Pontieu, S. W. McIntosh, M. Carlsson, V. H. Hansteen, T. D. Tarbell, P. Boerner, J. Martinez-Sykora, C. J. Schrijver, A. M. Title

Research output: Contribution to journal › Article › peer-review

341 Scopus citations

Abstract

The Sun's outer atmosphere, or corona, is heated to millions of degrees, considerably hotter than its surface or photosphere. Explanations for this enigma typically invoke the deposition in the corona of nonthermal energy generated by magnetoconvection. However, the coronal heating mechanism remains unknown. We used observations from the Solar Dynamics Observatory and the Hinode solar physics mission to reveal a ubiquitous coronal mass supply in which chromospheric plasma in fountainlike jets or spicules is accelerated upward into the corona, with much of the plasma heated to temperatures between ∼0.02 and 0.1 million kelvin (MK) and a small but sufficient fraction to temperatures above 1 MK. These observations provide constraints on the coronal heating mechanism(s) and highlight the importance of the interface region between photosphere and corona.

Original language	English
Pages (from-to)	55-58
Number of pages	4
Journal	Science
Volume	331
Issue number	6013
DOIs	https://doi.org/10.1126/science.1197738
State	Published - Jan 7 2011
Externally published	Yes

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title = "The origins of hot plasma in the solar corona",

abstract = "The Sun's outer atmosphere, or corona, is heated to millions of degrees, considerably hotter than its surface or photosphere. Explanations for this enigma typically invoke the deposition in the corona of nonthermal energy generated by magnetoconvection. However, the coronal heating mechanism remains unknown. We used observations from the Solar Dynamics Observatory and the Hinode solar physics mission to reveal a ubiquitous coronal mass supply in which chromospheric plasma in fountainlike jets or spicules is accelerated upward into the corona, with much of the plasma heated to temperatures between ∼0.02 and 0.1 million kelvin (MK) and a small but sufficient fraction to temperatures above 1 MK. These observations provide constraints on the coronal heating mechanism(s) and highlight the importance of the interface region between photosphere and corona.",

author = "\{De Pontieu\}, B. and McIntosh, \{S. W.\} and M. Carlsson and Hansteen, \{V. H.\} and Tarbell, \{T. D.\} and P. Boerner and J. Martinez-Sykora and Schrijver, \{C. J.\} and Title, \{A. M.\}",

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AU - De Pontieu, B.

AU - McIntosh, S. W.

AU - Carlsson, M.

AU - Hansteen, V. H.

AU - Tarbell, T. D.

AU - Boerner, P.

AU - Martinez-Sykora, J.

AU - Schrijver, C. J.

AU - Title, A. M.

PY - 2011/1/7

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N2 - The Sun's outer atmosphere, or corona, is heated to millions of degrees, considerably hotter than its surface or photosphere. Explanations for this enigma typically invoke the deposition in the corona of nonthermal energy generated by magnetoconvection. However, the coronal heating mechanism remains unknown. We used observations from the Solar Dynamics Observatory and the Hinode solar physics mission to reveal a ubiquitous coronal mass supply in which chromospheric plasma in fountainlike jets or spicules is accelerated upward into the corona, with much of the plasma heated to temperatures between ∼0.02 and 0.1 million kelvin (MK) and a small but sufficient fraction to temperatures above 1 MK. These observations provide constraints on the coronal heating mechanism(s) and highlight the importance of the interface region between photosphere and corona.

AB - The Sun's outer atmosphere, or corona, is heated to millions of degrees, considerably hotter than its surface or photosphere. Explanations for this enigma typically invoke the deposition in the corona of nonthermal energy generated by magnetoconvection. However, the coronal heating mechanism remains unknown. We used observations from the Solar Dynamics Observatory and the Hinode solar physics mission to reveal a ubiquitous coronal mass supply in which chromospheric plasma in fountainlike jets or spicules is accelerated upward into the corona, with much of the plasma heated to temperatures between ∼0.02 and 0.1 million kelvin (MK) and a small but sufficient fraction to temperatures above 1 MK. These observations provide constraints on the coronal heating mechanism(s) and highlight the importance of the interface region between photosphere and corona.

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The origins of hot plasma in the solar corona

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