Solar Physics

, Volume 135, Issue 1, pp 179–191 | Cite as

An electrograph for measurement of macroscopic electric fields in prominences and flares

  • T. Moran
  • P. Foukal
Article
Received:

Abstract

We describe an ‘electrograph’ instrument designed for measurement of macroscopic electric fields in solar plasmas, using the polarization dependence of line width in Stark-broadened hydrogen Paschen emission lines. Observations of quiescent prominences and limb chromosphere with our electrograph at the NSO/Sac Peak Evans Coronal Facility provide upper limits of 5–10 V cm−1 for transverse macroscopic electric fields in these structures, averaged over an area of about 5 × 7 arc sec. Random thermal motions of hydrogen ions across magnetic field lines generate a quasi-static electric field, which should be distinguishable from pressure broadening in the intensely magnetized chromosphere over a sunspot, given an electrograph sensitivity a factor 2–3 better than that achieved here. Future electrograph measurements of limb flares, post-flare loops and eruptive prominences, even at 5 V cm−1 sensitivity, could provide a useful new test of reconnection and discharge effects in such dynamic structures.

Keywords

Flare Line Width Emission Line Field Line Dynamic Structure 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
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Copyright information

© Kluwer Academic Publishers 1991

Authors and Affiliations

  • T. Moran
    • 1
  • P. Foukal
    • 1
  1. 1.Cambridge Research and Instrumentation, Inc.CambridgeU.S.A.

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