Heliophysics Events Knowledgebase Coverage Registry (HCR)
Observation Details
Overview Where Groups: Mode, FOV, # spectra in map Data Links
2016-09-01 21:25:05-21:58:56
HOP324 (filaments) w/BBSO+IRIS
Fine Structure and Dynamics of Solar Filaments/Prominences
x,y:-881",180"
Max FOV:141"x81"
Target:Filament
Nearby Events
6302A Continuum Intensity141"x81"445 spectra
6302A Longitudinal Flux Density141"x81"445 spectra
6302A Transverse Flux Density141"x81"445 spectra
6302A Velocity 6301.5A141"x81"445 spectra

Level 1 Summary
Level 2 Summary
Level 1 Monthly
Level 2 Monthly
SP Cubes 1 MB
SOTSP: HOP324 (filaments) w/BBSO+IRIS
2016-09-01T21:25:05 to 2016-09-01T21:58:56
Science Goal: Fine Structure and Dynamics of Solar Filaments/Prominences
Program: Fast map, 164"x82", Q65, 1-side CCD
Target: Filament
xcen=-881 ycen=180
Instrument: SOTSP
HOP/JOP: 324
Description: The solar corona contains sheared or twisted magnetic fields overlying polarity inversion lines on the photosphere. The sheared/twisted fields can be observed as filament channels on the disk and as coronal cavities in limb observations
solar prominences are located within these regions. These structures warrant investigation because of their role in prominence eruptions, coronal mass ejections (CMEs), and solar flares. Understanding the topology and evolution of the prominence/cavity magnetic field structure prior to the eruption is key to understanding the onset of solar eruptions. To understand how filaments are supported, we will study the fine structure and dynamics of the observed filament as well as its relation with the corresponding photospheric magnetic fields, and the corresponding structure of the coronal magnetic fields will be reconstructed using photospheric magnetic field observations. Tornado-like prominences were first described by Pettit (1932) but have not been paid much attention thereafter. Recently, several groups (e.g., Su et al. 2012
Wedemeyer-Boehm et al. 2012) observed ?magnetic tornadoes? with the AIA instrument onboard SDO, and pointed at possible connections among vortex motion on the surface, filament barbs, and solar tornadoes. However, whether these magnetic structures are indeed rotating, is a key question to be answered. Through cooperative observations between BBSO/NST, Hinode, and IRIS, and SDO we aim to address the following questions: what is the nature of the plasma dynamics in prominence barbs or tornado-like prominence? Do these motions play an important role in the formation and evolution of prominences? What is the relation between prominence barbs and tornado-like prominences? What is the magnetic structure supporting this type of prominence/filament? Our primary target will be an active region with filaments which is most likely to erupt. If there is no eruptive active region filament, our secondary target will be a quiescent filament/prominence with barbs and/or tornado-like features. In the ideal case, we propose to track the filament from disk to west limb.

The solar corona contains sheared or twisted magnetic fields overlying polarity inversion lines on the photosphere. The sheared/twisted fields can be observed as filament channels on the disk and as coronal cavities in limb observations
solar prominences are located within these regions. These structures warrant investigation because of their role in prominence eruptions, coronal mass ejections (CMEs), and solar flares. Understanding the topology and evolution of the prominence/cavity magnetic field structure prior to the eruption is key to understanding the onset of solar eruptions. To understand how filaments are supported, we will study the fine structure and dynamics of the observed filament as well as its relation with the corresponding photospheric magnetic fields, and the corresponding structure of the coronal magnetic fields will be reconstructed using photospheric magnetic field observations. Tornado-like prominences were first described by Pettit (1932) but have not been paid much attention thereafter. Recently, several groups (e.g., Su et al. 2012
Wedemeyer-Boehm et al. 2012) observed ?magnetic tornadoes? with the AIA instrument onboard SDO, and pointed at possible connections among vortex motion on the surface, filament barbs, and solar tornadoes. However, whether these magnetic structures are indeed rotating, is a key question to be answered. Through cooperative observations between BBSO/NST, Hinode, and IRIS, and SDO we aim to address the following questions: what is the nature of the plasma dynamics in prominence barbs or tornado-like prominence? Do these motions play an important role in the formation and evolution of prominences? What is the relation between prominence barbs and tornado-like prominences? What is the magnetic structure supporting this type of prominence/filament? Our primary target will be an active region with filaments which is most likely to erupt. If there is no eruptive active region filament, our secondary target will be a quiescent filament/prominence with barbs and/or tornado-like features. In the ideal case, we propose to track the filament from disk to west limb.

Annotations:
Hits: 46
Chief Observer
DeRosa (RCO) -> Shine (RCO)
Related Links
Cites: HOP324 (filaments) w/BBSO+IRIS     
Timeline: gif use
See also
Datasets
Get All Data
saaIntervals hiIntervals

wavelength: 6302A Continuum Intensity cadence: 0 min fov: 141,81 images: 445 JavaScript Landing Page
wavelength: 6302A Velocity 6301.5A cadence: 0 min fov: 141,81 images: 445 JavaScript Landing Page
wavelength: 6302A Transverse Flux Density cadence: 0 min fov: 141,81 images: 445 JavaScript Landing Page
wavelength: 6302A Longitudinal Flux Density cadence: 0 min fov: 141,81 images: 445 JavaScript Landing Page
Time Series (SP Datacubes)