{ "count": 14, "next": null, "previous": null, "results": [ { "id": 4496, "url": "https://svs.gsfc.nasa.gov/4496/", "result_type": "Visualization", "release_date": "2016-10-25T10:00:00-04:00", "title": "STEREO in stereo: Spring 2007 at 171 Ångstroms", "description": "Red/Cyan stereo glasses are required to view it properly. || 2007stereo_STEREO_RedCyan_010_EUVI171A_UHD3840.02000_print.jpg (1024x576) [69.0 KB] || 2007stereo_RedCyan_010_EUVI171A_2160p30.mp4 (3840x2160) [451.0 MB] || RedCyan (3840x2160) [512.0 KB] || 2007stereo_RedCyan_010_EUVI171A_2160p30.webm (3840x2160) [13.7 MB] || ", "hits": 28 }, { "id": 4500, "url": "https://svs.gsfc.nasa.gov/4500/", "result_type": "Visualization", "release_date": "2016-10-25T10:00:00-04:00", "title": "STEREO in stereo: Spring 2007 at 195 Ångstroms", "description": "Red/Cyan stereo glasses are required to view it properly. || 2007stereo_STEREO_RedCyan_010_EUVI195A_UHD3840.02000_print.jpg (1024x576) [51.7 KB] || 2007stereo_RedCyan_010_EUVI195A_2160p30.mp4 (3840x2160) [287.8 MB] || RedCyan (3840x2160) [512.0 KB] || 2007stereo_RedCyan_010_EUVI195A_2160p30.webm (3840x2160) [12.6 MB] || ", "hits": 37 }, { "id": 4501, "url": "https://svs.gsfc.nasa.gov/4501/", "result_type": "Visualization", "release_date": "2016-10-25T10:00:00-04:00", "title": "STEREO in stereo: Spring 2007 at 284 Ångstroms", "description": "Red/Cyan stereo glasses are required to view it properly. || 2007stereo_STEREO_RedCyan_010_EUVI284A_UHD3840.02000_print.jpg (1024x576) [59.2 KB] || RedCyan (3840x2160) [512.0 KB] || 2007stereo_RedCyan_010_EUVI284A_2160p30.mp4 (3840x2160) [506.4 MB] || 2007stereo_RedCyan_010_EUVI284A_2160p30.webm (3840x2160) [12.7 MB] || ", "hits": 29 }, { "id": 4502, "url": "https://svs.gsfc.nasa.gov/4502/", "result_type": "Visualization", "release_date": "2016-10-25T10:00:00-04:00", "title": "STEREO in stereo: Spring 2007 at 304 Ångstroms", "description": "Red/Cyan stereo glasses are required to view it properly. || 2007stereo_STEREO_RedCyan_010_EUVI304A_UHD3840.02000_print.jpg (1024x576) [80.1 KB] || 2007stereo_RedCyan_010_EUVI304A_2160p30.mp4 (3840x2160) [710.3 MB] || RedCyan (3840x2160) [512.0 KB] || 2007stereo_RedCyan_010_EUVI304A_2160p30.webm (3840x2160) [15.7 MB] || ", "hits": 33 }, { "id": 4461, "url": "https://svs.gsfc.nasa.gov/4461/", "result_type": "Visualization", "release_date": "2016-06-01T10:00:00-04:00", "title": "Mercury Transit 2016 from SDO/HMI", "description": "Full-Disk imagery sampled at 3 second cadence. || HMIMercuryComposite_stand.4Kx4K.04000_print.jpg (1024x1024) [141.4 KB] || HMIMercuryComposite_stand.4Kx4K.04000_searchweb.png (320x180) [50.3 KB] || HMIMercuryComposite_stand.4Kx4K.04000_thm.png (80x40) [3.9 KB] || HMIMercuryComposite_stand.2Kx2Kp30.webm (2048x2048) [30.4 MB] || HMIMercuryComposite_stand.2Kx2Kp30.mp4 (2048x2048) [637.1 MB] || 4096x4096_1x1_30p (4096x4096) [0 Item(s)] || ", "hits": 41 }, { "id": 4462, "url": "https://svs.gsfc.nasa.gov/4462/", "result_type": "Visualization", "release_date": "2016-06-01T10:00:00-04:00", "title": "Mercury Transit 2016 from SDO/AIA at 171 Ångstroms", "description": "Composited full-disk imagery sampled at 12 second intervals. || AIA171MercuryComposite.01500_print.jpg (1024x1024) [187.2 KB] || AIA171MercuryComposite.01500_searchweb.png (320x180) [82.8 KB] || AIA171MercuryComposite.01500_thm.png (80x40) [6.3 KB] || aia171mercurycomposite_2048p30.webm (720x720) [6.6 MB] || AIA171MercuryComposite_2048p30.mp4 (2048x2048) [297.0 MB] || 171A-Frames (4096x4096) [0 Item(s)] || 171A-Time (4096x4096) [0 Item(s)] || ", "hits": 54 }, { "id": 4463, "url": "https://svs.gsfc.nasa.gov/4463/", "result_type": "Visualization", "release_date": "2016-06-01T10:00:00-04:00", "title": "Mercury Transit 2016 from SDO/AIA at 304 Ångstroms", "description": "Composited full-disk imagery sampled at 12 second intervals. || AIA304MercuryComposite.01500_print.jpg (1024x1024) [195.3 KB] || AIA304MercuryComposite.01500_searchweb.png (320x180) [69.7 KB] || AIA304MercuryComposite.01500_thm.png (80x40) [4.7 KB] || AIA304MercuryComposite_2048p30.webm (720x720) [9.5 MB] || AIA304MercuryComposite_2048p30.mp4 (2048x2048) [597.8 MB] || 304A-Frames (4096x4096) [0 Item(s)] || 304A-Time (4096x4096) [0 Item(s)] || ", "hits": 39 }, { "id": 12245, "url": "https://svs.gsfc.nasa.gov/12245/", "result_type": "Produced Video", "release_date": "2016-05-12T11:00:00-04:00", "title": "Mercury In Motion", "description": "Mercury appears as a black dot while crossing the face of the sun during a rare transit. || c-1024.jpg (1024x576) [177.9 KB] || c-1280.jpg (1280x720) [203.3 KB] || c-1024_print.jpg (1024x576) [189.3 KB] || c-1024_searchweb.png (320x180) [84.2 KB] || c-1024_web.png (320x180) [84.2 KB] || c-1024_thm.png (80x40) [12.2 KB] || ", "hits": 138 }, { "id": 12235, "url": "https://svs.gsfc.nasa.gov/12235/", "result_type": "Produced Video", "release_date": "2016-05-09T20:00:00-04:00", "title": "2016 Mercury Transit Timelapse", "description": "Complete transcript available.Watch this video on the NASA Goddard YouTube channel.Music: Encompass by Mark Petrie || 2016mercurytransitthumb.jpg (1280x720) [99.4 KB] || 2016mercurytransitthumb_searchweb.png (320x180) [99.9 KB] || 2016mercurytransitthumb_thm.png (80x40) [15.6 KB] || 12235_Mercury_Transit_2016_1080_appletv.m4v (1280x720) [77.4 MB] || 12235_Mercury_Transit_2016_1080_youtube_hq.webm (1920x1080) [16.1 MB] || 12235_Mercury_Transit_2016_1080_appletv_subtitles.m4v (1280x720) [77.5 MB] || 12235_Mercury_Transit_transcriptPH.en_US.srt [1.2 KB] || 12235_Mercury_Transit_transcriptPH.en_US.vtt [1.2 KB] || PRORES_B-ROLL_12235_Mercury_Transit_2016_1080_prores.mov (1280x720) [1.0 GB] || 12235_Mercury_Transit_2016_1080_youtube_hq.mov (1920x1080) [975.3 MB] || 12235_Mercury_Transit_2016_1080.mov (1920x1080) [1.9 GB] || 12235_Mercury_Transit_2016_1080_ipod_sm.mp4 (320x240) [25.6 MB] || ", "hits": 108 }, { "id": 11418, "url": "https://svs.gsfc.nasa.gov/11418/", "result_type": "Produced Video", "release_date": "2014-01-02T00:00:00-05:00", "title": "Solar Continuum", "description": "Many of the sun's features are invisible to the naked eye. To paint a full picture of our constantly changing star, scientists use telescopes launched into space. Each telescope is outfitted with special filters that can see the sun in different wavelengths of light. To track how material and heat of different temperature moves through the sun's atmosphere, scientists only need to select the specific wavelength with which a feature can best be seen. Watch the video for a tour of the wide range of wavelengths that NASA's Solar Dynamics Observatory spacecraft uses to observe the sun. || ", "hits": 99 }, { "id": 4128, "url": "https://svs.gsfc.nasa.gov/4128/", "result_type": "Visualization", "release_date": "2013-12-24T00:00:00-05:00", "title": "Solar Dynamics Observatory - Argo view - Slices of SDO", "description": "Argos (or Argus Panoptes) was the 100-eyed giant in Greek mythology (wikipedia).While the Solar Dynamics Observatory (SDO) has significantly less than 100 eyes, (see \"SDO Jewelbox: The Many Eyes of SDO\"), seeing connections in the solar atmosphere through the many filters of SDO presents a number of interesting challenges. This visualization experiment illustrates a mechanism for highlighting these connections. This visualization is a variation of the original Solar Dynamics Observatory - Argo view. In this case, the different wavelength filters are presented in three sets around the Sun at full 4Kx4K resolution. This enables monitoring of changes in time over all wavelengths at any location around the limb of the Sun. The wavelengths presented are: 617.3nm optical light from SDO/HMI. From SDO/AIA we have 170nm (pink), then 160nm (green), 33.5nm (blue), 30.4nm (orange), 21.1nm (violet), 19.3nm (bronze), 17.1nm (gold), 13.1nm (aqua) and 9.4nm (green).We've locked the camera to rotate the view of the Sun so each wedge-shaped wavelength filter passes over a region of the Sun. As the features pass from one wavelength to the next, we can see dramatic differences in solar structures that appear in different wavelengths.Filaments extending off the limb of the Sun which are bright in 30.4 nanometers, appear dark in many other wavelengths.Sunspots which appear dark in optical wavelengths, are festooned with glowing ribbons in ultraviolet wavelengths.small flares, invisible in optical wavelengths, are bright ribbons in ultraviolet wavelengths.if we compare the visible light limb of the Sun with the 170 nanometer filter on the left, with the visible light limb and the 9.4 nanometer filter on the right, we see that the 'edge' is at different heights. This effect is due to the different amounts of absorption, and emission, of the solar atmosphere in ultraviolet light.in far ultraviolet light, the photosphere is dark since the black-body spectrum at a temperature of 5700 Kelvin emits very little light in this wavelength. || ", "hits": 54 }, { "id": 4117, "url": "https://svs.gsfc.nasa.gov/4117/", "result_type": "Visualization", "release_date": "2013-12-17T10:00:00-05:00", "title": "Solar Dynamics Observatory - Argo view", "description": "Argos (or Argus Panoptes) was the 100-eyed giant in Greek mythology (wikipedia).While the Solar Dynamics Observatory (SDO) has significantly less than 100 eyes, (see \"SDO Jewelbox: The Many Eyes of SDO\"), seeing connections in the solar atmosphere through the many filters of SDO presents a number of interesting challenges. This visualization experiment illustrates a mechanism for highlighting these connections.The wavelengths presented are: 617.3nm optical light from SDO/HMI. From SDO/AIA we have 170nm (pink), then 160nm (green), 33.5nm (blue), 30.4nm (orange), 21.1nm (violet), 19.3nm (bronze), 17.1nm (gold), 13.1nm (aqua) and 9.4nm (green).We've locked the camera to rotate the view of the Sun so each wedge-shaped wavelength filter passes over a region of the Sun. As the features pass from one wavelength to the next, we can see dramatic differences in solar structures that appear in different wavelengths.Filaments extending off the limb of the Sun which are bright in 30.4 nanometers, appear dark in many other wavelengths.Sunspots which appear dark in optical wavelengths, are festooned with glowing ribbons in ultraviolet wavelengths.Small flares, invisible in optical wavelengths, are bright ribbons in ultraviolet wavelengths.If we compare the visible light limb of the Sun with the 170 nanometer filter on the left, with the visible light limb and the 9.4 nanometer filter on the right, we see that the 'edge' is at different heights. This effect is due to the different amounts of absorption, and emission, of the solar atmosphere in ultraviolet light.In far ultraviolet light, the photosphere is dark since the black-body spectrum at a temperature of 5700 Kelvin emits very little light in this wavelength. || ", "hits": 72 }, { "id": 11385, "url": "https://svs.gsfc.nasa.gov/11385/", "result_type": "Produced Video", "release_date": "2013-12-17T10:00:00-05:00", "title": "Jewel Box Sun", "description": "Telescopes help distant objects appear bigger, but this is only one of their advantages. Telescopes can also collect light in ranges that our eyes alone cannot see, providing scientists ways of observing a whole host of material and processes that would otherwise be inaccessible. A new NASA movie of the sun based on data from NASA's Solar Dynamics Observatory, or SDO, shows the wide range of wavelengths – invisible to the naked eye – that the telescope can view. SDO converts the wavelengths into an image humans can see, and the light is colorized into a rainbow of colors. As the colors sweep around the sun in the movie, viewers should note how different the same area of the sun appears. This happens because each wavelength of light represents solar material at specific temperatures. Different wavelengths convey information about different components of the sun's surface and atmosphere, so scientists use them to paint a full picture of our constantly changing and varying star.Yellow light of 5800 angstroms, for example, generally emanates from material of about 10,000 degrees F (5700 degrees C), which represents the surface of the sun. Extreme ultraviolet light of 94 angstroms, which is typically colorized in green in SDO images, comes from atoms that are about 11 million degrees F (6,300,000 degrees C) and is a good wavelength for looking at solar flares, which can reach such high temperatures. By examining pictures of the sun in a variety of wavelengths – as is done not only by SDO, but also by NASA's Interface Region Imaging Spectrograph, NASA's Solar Terrestrial Relations Observatory and the European Space Agency/NASA Solar and Heliospheric Observatory — scientists can track how particles and heat move through the sun's atmosphere. || ", "hits": 63 }, { "id": 10748, "url": "https://svs.gsfc.nasa.gov/10748/", "result_type": "Produced Video", "release_date": "2011-04-21T09:00:00-04:00", "title": "SDO: Year One", "description": "April 21, 2011 marks the one-year anniversary of the Solar Dynamics Observatory (SDO) First Light press conference, where NASA revealed the first images taken by the spacecraft.In the last year, the sun has gone from its quietest period in years to the activity marking the beginning of solar cycle 24. SDO has captured every moment with a level of detail never-before possible. The mission has returned unprecedented images of solar flares, eruptions of prominences, and the early stages of coronal mass ejections (CMEs). In this video are some of the most beautiful, interesting, and mesmerizing events seen by SDO during its first year.In the order they appear in the video the events are:1. Prominence Eruption from AIA in 304 Ångstroms on March 30, 20102. Cusp Flow from AIA in 171 Ångstroms on February 14, 20113. Prominence Eruption from AIA in 304 Ångstroms on February 25, 20114. Cusp Flow from AIA in 304 Ångstroms on February 14, 20115. Merging Sunspots from HMI in Continuum on October 24-28, 20106. Prominence Eruption and active region from AIA in 304 Ångstroms on April 30, 20107. Solar activity and plasma loops from AIA in 171 Ångstroms on March 4-8, 20118. Flowing plasma from AIA in 304 Ångstroms on April 19, 20109. Active regions from HMI in Magnetogram on March 10, 201110. Filament eruption from AIA in 304 Ångstroms on December 6, 201011. CME start from AIA in 211 Ångstroms on March 8, 201112. X2 flare from AIA in 304 Ångstroms on February 15, 2011 || ", "hits": 90 } ] }