A tale of two spicules: The impact of spicules on the magnetic chromosphere

Bart De Pontieu; Scott McIntosh; Viggo H. Hansteen; Mats Carlsson; Carolus J. Schrijver; Theodore D. Tarbell; Alan M. Title; Richard A. Shine; Yoshinori Suematsu; Saku Tsuneta; Yukio Katsukawa; Kiyoshi Ichimoto; Toshifumi Shimizu; Shin'ichi Nagata

doi:10.1093/pasj/59.sp3.s655

A tale of two spicules: The impact of spicules on the magnetic chromosphere

Bart De Pontieu, Scott McIntosh, Viggo H. Hansteen, Mats Carlsson, Carolus J. Schrijver, Theodore D. Tarbell, Alan M. Title, Richard A. Shine, Yoshinori Suematsu, Saku Tsuneta, Yukio Katsukawa, Kiyoshi Ichimoto, Toshifumi Shimizu, Shin'ichi Nagata

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382 Scopus citations

Abstract

We use high-resolution observations of the Sun in Ca II H (3968 Å) from the Solar Optical Telescope on Hinode to show that there are at least two types of spicules that dominate the structure of the magnetic solar chromosphere. Both types are tied to the relentless magnetoconvective driving in the photosphere, but have very different dynamic properties. "Type-I" spicules are driven by shock waves that form when global oscillations and convective flows leak into the upper atmosphere along magnetic field lines on 3-7 minute timescales. "Type-II" spicules are much more dynamic: they form rapidly (in ∼ 10s), are very thin (≤ 200 km wide), have lifetimes of 10-150s (at any one height), and seem to be rapidly heated to (at least) transition region temperatures, sending material through the chromosphere at speeds of order 50-150 km s^-1. The properties of Type II spicules suggest a formation process that is a consequence of magnetic reconnection, typically in the vicinity of magnetic flux concentrations in plage and network. Both types of spicules are observed to carry Alfvén waves with significant amplitudes of order 20km s^-1.

Original language	English
Pages (from-to)	S655-S662
Journal	Publications of the Astronomical Society of Japan
Volume	59
Issue number	SPEC. ISS. 3
DOIs	https://doi.org/10.1093/pasj/59.sp3.s655
State	Published - 2007
Externally published	Yes

Keywords

Sun: chromosphere
Sun: transition region

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10.1093/pasj/59.sp3.s655

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De Pontieu, B., McIntosh, S., Hansteen, V. H., Carlsson, M., Schrijver, C. J., Tarbell, T. D., Title, A. M., Shine, R. A., Suematsu, Y., Tsuneta, S., Katsukawa, Y., Ichimoto, K., Shimizu, T., & Nagata, S. (2007). A tale of two spicules: The impact of spicules on the magnetic chromosphere. Publications of the Astronomical Society of Japan, 59(SPEC. ISS. 3), S655-S662. https://doi.org/10.1093/pasj/59.sp3.s655

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title = "A tale of two spicules: The impact of spicules on the magnetic chromosphere",

abstract = "We use high-resolution observations of the Sun in Ca II H (3968 {\AA}) from the Solar Optical Telescope on Hinode to show that there are at least two types of spicules that dominate the structure of the magnetic solar chromosphere. Both types are tied to the relentless magnetoconvective driving in the photosphere, but have very different dynamic properties. {"}Type-I{"} spicules are driven by shock waves that form when global oscillations and convective flows leak into the upper atmosphere along magnetic field lines on 3-7 minute timescales. {"}Type-II{"} spicules are much more dynamic: they form rapidly (in ∼ 10s), are very thin (≤ 200 km wide), have lifetimes of 10-150s (at any one height), and seem to be rapidly heated to (at least) transition region temperatures, sending material through the chromosphere at speeds of order 50-150 km s-1. The properties of Type II spicules suggest a formation process that is a consequence of magnetic reconnection, typically in the vicinity of magnetic flux concentrations in plage and network. Both types of spicules are observed to carry Alfv{\'e}n waves with significant amplitudes of order 20km s-1.",

keywords = "Sun: chromosphere, Sun: transition region",

author = "\{De Pontieu\}, Bart and Scott McIntosh and Hansteen, \{Viggo H.\} and Mats Carlsson and Schrijver, \{Carolus J.\} and Tarbell, \{Theodore D.\} and Title, \{Alan M.\} and Shine, \{Richard A.\} and Yoshinori Suematsu and Saku Tsuneta and Yukio Katsukawa and Kiyoshi Ichimoto and Toshifumi Shimizu and Shin'ichi Nagata",

year = "2007",

doi = "10.1093/pasj/59.sp3.s655",

language = "English",

volume = "59",

pages = "S655--S662",

journal = "Publications of the Astronomical Society of Japan",

issn = "0004-6264",

publisher = "Oxford University Press",

number = "SPEC. ISS. 3",

}

De Pontieu, B, McIntosh, S, Hansteen, VH, Carlsson, M, Schrijver, CJ, Tarbell, TD, Title, AM, Shine, RA, Suematsu, Y, Tsuneta, S, Katsukawa, Y, Ichimoto, K, Shimizu, T & Nagata, S 2007, 'A tale of two spicules: The impact of spicules on the magnetic chromosphere', Publications of the Astronomical Society of Japan, vol. 59, no. SPEC. ISS. 3, pp. S655-S662. https://doi.org/10.1093/pasj/59.sp3.s655

TY - JOUR

T1 - A tale of two spicules

T2 - The impact of spicules on the magnetic chromosphere

AU - De Pontieu, Bart

AU - McIntosh, Scott

AU - Hansteen, Viggo H.

AU - Carlsson, Mats

AU - Schrijver, Carolus J.

AU - Tarbell, Theodore D.

AU - Title, Alan M.

AU - Shine, Richard A.

AU - Suematsu, Yoshinori

AU - Tsuneta, Saku

AU - Katsukawa, Yukio

AU - Ichimoto, Kiyoshi

AU - Shimizu, Toshifumi

AU - Nagata, Shin'ichi

PY - 2007

Y1 - 2007

N2 - We use high-resolution observations of the Sun in Ca II H (3968 Å) from the Solar Optical Telescope on Hinode to show that there are at least two types of spicules that dominate the structure of the magnetic solar chromosphere. Both types are tied to the relentless magnetoconvective driving in the photosphere, but have very different dynamic properties. "Type-I" spicules are driven by shock waves that form when global oscillations and convective flows leak into the upper atmosphere along magnetic field lines on 3-7 minute timescales. "Type-II" spicules are much more dynamic: they form rapidly (in ∼ 10s), are very thin (≤ 200 km wide), have lifetimes of 10-150s (at any one height), and seem to be rapidly heated to (at least) transition region temperatures, sending material through the chromosphere at speeds of order 50-150 km s-1. The properties of Type II spicules suggest a formation process that is a consequence of magnetic reconnection, typically in the vicinity of magnetic flux concentrations in plage and network. Both types of spicules are observed to carry Alfvén waves with significant amplitudes of order 20km s-1.

AB - We use high-resolution observations of the Sun in Ca II H (3968 Å) from the Solar Optical Telescope on Hinode to show that there are at least two types of spicules that dominate the structure of the magnetic solar chromosphere. Both types are tied to the relentless magnetoconvective driving in the photosphere, but have very different dynamic properties. "Type-I" spicules are driven by shock waves that form when global oscillations and convective flows leak into the upper atmosphere along magnetic field lines on 3-7 minute timescales. "Type-II" spicules are much more dynamic: they form rapidly (in ∼ 10s), are very thin (≤ 200 km wide), have lifetimes of 10-150s (at any one height), and seem to be rapidly heated to (at least) transition region temperatures, sending material through the chromosphere at speeds of order 50-150 km s-1. The properties of Type II spicules suggest a formation process that is a consequence of magnetic reconnection, typically in the vicinity of magnetic flux concentrations in plage and network. Both types of spicules are observed to carry Alfvén waves with significant amplitudes of order 20km s-1.

KW - Sun: chromosphere

KW - Sun: transition region

UR - https://www.scopus.com/pages/publications/36849037320

U2 - 10.1093/pasj/59.sp3.s655

DO - 10.1093/pasj/59.sp3.s655

M3 - Article

AN - SCOPUS:36849037320

SN - 0004-6264

VL - 59

SP - S655-S662

JO - Publications of the Astronomical Society of Japan

JF - Publications of the Astronomical Society of Japan

IS - SPEC. ISS. 3

ER -

A tale of two spicules: The impact of spicules on the magnetic chromosphere

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Keywords

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