An X1.1 flare from Active Region 13664 - May 9, 2024
Solar Dynamics Observatory (SDO) operates in a geosynchronous orbit around Earth to obtain a continuous view of the Sun. The particular instrument in this visualization records imagery in the ultraviolet portion of the spectrum at wavelengths normally absorbed by Earth's atmosphere - so we need to observe them from space.
Active region 13664 (lower right quadrant of solar disk) again launches an X-flare (X1.1) and a stream of plasma. More details on the Space Weather database.
For more information on the classification of solar flares, see Solar Flares: What Does It Take to Be X-Class? or X-Class: A Guide to Solar Flares. The point-spread function correction (PSF) has been applied to all this imagery.
Active Region 13664 (in the lower right quadrant) launches yet another strong flare (X1.1) on May 9, along with a bright stream of plasma in this view through the SDO AIA 131 ångstrom filter.
Active Region 13664 (in the lower right quadrant) launches yet another strong flare (X1.1) on May 9, along with a bright stream of plasma in this view through the SDO AIA 171 ångstrom filter.
Active Region 13664 (in the lower right quadrant) launches yet another strong flare (X1.1) on May 9, along with a bright stream of plasma in this view through the SDO AIA 304 ångstrom filter.
What is the PSF (Point Spread-Function)?
Many telescopes, especially reflecting telescopes such as the ones used on SDO (Wikipedia), have internal structures that support various optical components. These components can result in incoming light being scattered to other parts of the image. This can appear in the image as a faint haze, brightening dark areas and dimming bright areas. The point-spread function (Wikipedia) is a measure of how light that would normally be received by a single camera pixel, gets scattered onto other pixels. This is often seen as the "spikes" seen in images of bright stars. For SDO, it manifests as a double-X shape centered over a bright flare (see Sun Emits Third Solar Flare in Two Days). The effect of this scattered light can be computed, and removed, by a process called deconvolution (Wikipedia). This is often a very compute-intensive process which can be sped up by using a computers graphics-processing unit (GPU) for the computation.Time slates for the multiple movies above, for custom compositing. Make sure to match the event and frame tag for the SDO frames you are using.
Credits
Please give credit for this item to:
NASA's Scientific Visualization Studio
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Visualizer
- Tom Bridgman (Global Science and Technology, Inc.)
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Producer
- Scott Wiessinger (KBR Wyle Services, LLC)
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Technical support
- Laurence Schuler (ADNET Systems, Inc.)
- Ian Jones (ADNET Systems, Inc.)
Release date
This page was originally published on Wednesday, July 3, 2024.
This page was last updated on Wednesday, June 26, 2024 at 11:46 AM EDT.
Missions
This page is related to the following missions:Series
This page can be found in the following series:Datasets used
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AIA 304 (304 Filter) [SDO: AIA]
ID: 677This dataset can be found at: http://jsoc.stanford.edu/
See all pages that use this dataset -
AIA 171 (171 Filter) [SDO: AIA]
ID: 680This dataset can be found at: http://jsoc.stanford.edu/
See all pages that use this dataset -
AIA 131 (131 Filter) [SDO: AIA]
ID: 730This dataset can be found at: http://jsoc.stanford.edu/
See all pages that use this dataset
Note: While we identify the data sets used on this page, we do not store any further details, nor the data sets themselves on our site.