Visualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \r
Credit: ESA/ATG medialab", "items": [ { "id": 232659, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388659, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_01.gif", "filename": "20191129_Solo_Sequences_01.gif", "media_type": "Image", "alt_text": "Spacecraft separation - GIF \rVisualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \rCredit: ESA/ATG medialab", "width": 960, "height": 540, "pixels": 518400 } } ], "extra_data": {} }, { "id": 321500, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321500", "widget": "Video player", "title": "", "caption": "", "description": "Spacecraft separation - Video \r
Visualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \r
Credit: ESA/ATG medialab", "items": [ { "id": 232661, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388662, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_01.00001_print.jpg", "filename": "20191129_Solo_Sequences_01.00001_print.jpg", "media_type": "Image", "alt_text": "Spacecraft separation - Video \rVisualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \rCredit: ESA/ATG medialab", "width": 1024, "height": 576, "pixels": 589824 } }, { "id": 232662, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388660, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_01.00001_searchweb.png", "filename": "20191129_Solo_Sequences_01.00001_searchweb.png", "media_type": "Image", "alt_text": "Spacecraft separation - Video \rVisualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \rCredit: ESA/ATG medialab", "width": 320, "height": 180, "pixels": 57600 } }, { "id": 232663, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388661, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_01.00001_thm.png", "filename": "20191129_Solo_Sequences_01.00001_thm.png", "media_type": "Image", "alt_text": "Spacecraft separation - Video \rVisualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \rCredit: ESA/ATG medialab", "width": 80, "height": 40, "pixels": 3200 } }, { "id": 232660, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388663, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_01.mp4", "filename": "20191129_Solo_Sequences_01.mp4", "media_type": "Movie", "alt_text": "Spacecraft separation - Video \rVisualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \rCredit: ESA/ATG medialab", "width": 1920, "height": 1080, "pixels": 2073600 } }, { "id": 232664, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388664, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_01.webm", "filename": "20191129_Solo_Sequences_01.webm", "media_type": "Movie", "alt_text": "Spacecraft separation - Video \rVisualization of the separation of Solar Orbiter from the Atlas V upper stage about 53 minutes after launch. \rCredit: ESA/ATG medialab", "width": 1920, "height": 1080, "pixels": 2073600 } } ], "extra_data": {} }, { "id": 321501, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321501", "widget": "Single image", "title": "", "caption": "", "description": "Thrusters & Solar Array Deployment - GIF \r
Visualization showing the thrusters adjust the attitude of the spacecraft before the solar arrays are deployed. The deployment happens in two stages: the first part takes place about five minutes after separation and is spring-driven, unfolding the solar arrays to about 40% within four minutes. The second part is motorised, and will fully extend the solar arrays. This part takes about ten minutes. The solar arrays will be fully deployed by about 40 minutes after spacecraft separation. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232665, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388665, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_02.gif", "filename": "20191129_Solo_Sequences_02.gif", "media_type": "Image", "alt_text": "Thrusters & Solar Array Deployment - GIF \rVisualization showing the thrusters adjust the attitude of the spacecraft before the solar arrays are deployed. The deployment happens in two stages: the first part takes place about five minutes after separation and is spring-driven, unfolding the solar arrays to about 40% within four minutes. The second part is motorised, and will fully extend the solar arrays. This part takes about ten minutes. The solar arrays will be fully deployed by about 40 minutes after spacecraft separation. Credit: ESA/ATG medialab\r", "width": 960, "height": 540, "pixels": 518400 } } ], "extra_data": {} }, { "id": 321502, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321502", "widget": "Video player", "title": "", "caption": "", "description": "Thrusters & Solar Array Deployment - Video \r
Visualization showing the thrusters adjust the attitude of the spacecraft before the solar arrays are deployed. The deployment happens in two stages: the first part takes place about five minutes after separation and is spring-driven, unfolding the solar arrays to about 40% within four minutes. The second part is motorised, and will fully extend the solar arrays. This part takes about ten minutes. The solar arrays will be fully deployed by about 40 minutes after spacecraft separation. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232667, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388666, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_02.00001_print.jpg", "filename": "20191129_Solo_Sequences_02.00001_print.jpg", "media_type": "Image", "alt_text": "Thrusters & Solar Array Deployment - Video \rVisualization showing the thrusters adjust the attitude of the spacecraft before the solar arrays are deployed. The deployment happens in two stages: the first part takes place about five minutes after separation and is spring-driven, unfolding the solar arrays to about 40% within four minutes. The second part is motorised, and will fully extend the solar arrays. This part takes about ten minutes. The solar arrays will be fully deployed by about 40 minutes after spacecraft separation. Credit: ESA/ATG medialab\r", "width": 1024, "height": 576, "pixels": 589824 } }, { "id": 232666, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388667, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_02.mp4", "filename": "20191129_Solo_Sequences_02.mp4", "media_type": "Movie", "alt_text": "Thrusters & Solar Array Deployment - Video \rVisualization showing the thrusters adjust the attitude of the spacecraft before the solar arrays are deployed. The deployment happens in two stages: the first part takes place about five minutes after separation and is spring-driven, unfolding the solar arrays to about 40% within four minutes. The second part is motorised, and will fully extend the solar arrays. This part takes about ten minutes. The solar arrays will be fully deployed by about 40 minutes after spacecraft separation. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } }, { "id": 232668, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388668, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_02.webm", "filename": "20191129_Solo_Sequences_02.webm", "media_type": "Movie", "alt_text": "Thrusters & Solar Array Deployment - Video \rVisualization showing the thrusters adjust the attitude of the spacecraft before the solar arrays are deployed. The deployment happens in two stages: the first part takes place about five minutes after separation and is spring-driven, unfolding the solar arrays to about 40% within four minutes. The second part is motorised, and will fully extend the solar arrays. This part takes about ten minutes. The solar arrays will be fully deployed by about 40 minutes after spacecraft separation. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } } ], "extra_data": {} }, { "id": 321503, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321503", "widget": "Single image", "title": "", "caption": "", "description": "Boom / antenna deployments - GIF\r
Visualization showing the deployment of various boom/antennas. In the beginning, the first Radio and Plasma Waves (RPW) antenna is deployed. Then the boom hosting a suite of scientific instruments is deployed (MAG, RPW, and SWA to measure the magnetic and electric fields, and solar wind around the spacecraft). Subsequently, the remaining two RPW antennas are deployed. Finally, the high gain antenna dish is unfurled. In reality this sequence is spaced out over a 24 hour period. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232669, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388669, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_03.gif", "filename": "20191129_Solo_Sequences_03.gif", "media_type": "Image", "alt_text": "Boom / antenna deployments - GIF\rVisualization showing the deployment of various boom/antennas. In the beginning, the first Radio and Plasma Waves (RPW) antenna is deployed. Then the boom hosting a suite of scientific instruments is deployed (MAG, RPW, and SWA to measure the magnetic and electric fields, and solar wind around the spacecraft). Subsequently, the remaining two RPW antennas are deployed. Finally, the high gain antenna dish is unfurled. In reality this sequence is spaced out over a 24 hour period. Credit: ESA/ATG medialab\r", "width": 960, "height": 540, "pixels": 518400 } } ], "extra_data": {} }, { "id": 321504, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321504", "widget": "Video player", "title": "", "caption": "", "description": "Boom / antenna deployments - Video\r
Visualization showing the deployment of various boom/antennas. In the beginning, the first Radio and Plasma Waves (RPW) antenna is deployed. Then the boom hosting a suite of scientific instruments is deployed (MAG, RPW, and SWA to measure the magnetic and electric fields, and solar wind around the spacecraft). Subsequently, the remaining two RPW antennas are deployed. Finally, the high gain antenna dish is unfurled. In reality this sequence is spaced out over a 24 hour period. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232671, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388670, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_03.00001_print.jpg", "filename": "20191129_Solo_Sequences_03.00001_print.jpg", "media_type": "Image", "alt_text": "Boom / antenna deployments - Video\rVisualization showing the deployment of various boom/antennas. In the beginning, the first Radio and Plasma Waves (RPW) antenna is deployed. Then the boom hosting a suite of scientific instruments is deployed (MAG, RPW, and SWA to measure the magnetic and electric fields, and solar wind around the spacecraft). Subsequently, the remaining two RPW antennas are deployed. Finally, the high gain antenna dish is unfurled. In reality this sequence is spaced out over a 24 hour period. Credit: ESA/ATG medialab\r", "width": 1024, "height": 576, "pixels": 589824 } }, { "id": 232670, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388671, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_03.mp4", "filename": "20191129_Solo_Sequences_03.mp4", "media_type": "Movie", "alt_text": "Boom / antenna deployments - Video\rVisualization showing the deployment of various boom/antennas. In the beginning, the first Radio and Plasma Waves (RPW) antenna is deployed. Then the boom hosting a suite of scientific instruments is deployed (MAG, RPW, and SWA to measure the magnetic and electric fields, and solar wind around the spacecraft). Subsequently, the remaining two RPW antennas are deployed. Finally, the high gain antenna dish is unfurled. In reality this sequence is spaced out over a 24 hour period. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } }, { "id": 232672, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388672, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_03.webm", "filename": "20191129_Solo_Sequences_03.webm", "media_type": "Movie", "alt_text": "Boom / antenna deployments - Video\rVisualization showing the deployment of various boom/antennas. In the beginning, the first Radio and Plasma Waves (RPW) antenna is deployed. Then the boom hosting a suite of scientific instruments is deployed (MAG, RPW, and SWA to measure the magnetic and electric fields, and solar wind around the spacecraft). Subsequently, the remaining two RPW antennas are deployed. Finally, the high gain antenna dish is unfurled. In reality this sequence is spaced out over a 24 hour period. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } } ], "extra_data": {} }, { "id": 321505, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321505", "widget": "Single image", "title": "", "caption": "", "description": "Venus Flyby - GIF\r
Visualization of a Venus gravity flyby. Solar Orbiter will make numerous gravity assist flybys of Venus (and one of Earth) over the course of its mission to adjust its orbit, bringing it closer to the Sun and also out of the plane of the Solar System to observe the Sun from progressively higher inclinations. This will result in the spacecraft being able to take the first ever images of the Sun’s polar regions, crucial for understanding how the Sun ‘works’. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232673, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388673, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_04.gif", "filename": "20191129_Solo_Sequences_04.gif", "media_type": "Image", "alt_text": "Venus Flyby - GIF\rVisualization of a Venus gravity flyby. Solar Orbiter will make numerous gravity assist flybys of Venus (and one of Earth) over the course of its mission to adjust its orbit, bringing it closer to the Sun and also out of the plane of the Solar System to observe the Sun from progressively higher inclinations. This will result in the spacecraft being able to take the first ever images of the Sun’s polar regions, crucial for understanding how the Sun ‘works’. Credit: ESA/ATG medialab\r", "width": 960, "height": 540, "pixels": 518400 } } ], "extra_data": {} }, { "id": 321506, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321506", "widget": "Video player", "title": "", "caption": "", "description": "Venus Flyby - Video\r
Visualization of a Venus gravity flyby. Solar Orbiter will make numerous gravity assist flybys of Venus (and one of Earth) over the course of its mission to adjust its orbit, bringing it closer to the Sun and also out of the plane of the Solar System to observe the Sun from progressively higher inclinations. This will result in the spacecraft being able to take the first ever images of the Sun’s polar regions, crucial for understanding how the Sun ‘works’. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232676, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388675, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_04.00020_print.jpg", "filename": "20191129_Solo_Sequences_04.00020_print.jpg", "media_type": "Image", "alt_text": "Venus Flyby - Video\rVisualization of a Venus gravity flyby. Solar Orbiter will make numerous gravity assist flybys of Venus (and one of Earth) over the course of its mission to adjust its orbit, bringing it closer to the Sun and also out of the plane of the Solar System to observe the Sun from progressively higher inclinations. This will result in the spacecraft being able to take the first ever images of the Sun’s polar regions, crucial for understanding how the Sun ‘works’. Credit: ESA/ATG medialab\r", "width": 1024, "height": 576, "pixels": 589824 } }, { "id": 232674, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388676, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_04.mp4", "filename": "20191129_Solo_Sequences_04.mp4", "media_type": "Movie", "alt_text": "Venus Flyby - Video\rVisualization of a Venus gravity flyby. Solar Orbiter will make numerous gravity assist flybys of Venus (and one of Earth) over the course of its mission to adjust its orbit, bringing it closer to the Sun and also out of the plane of the Solar System to observe the Sun from progressively higher inclinations. This will result in the spacecraft being able to take the first ever images of the Sun’s polar regions, crucial for understanding how the Sun ‘works’. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } }, { "id": 232675, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388674, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_04.webm", "filename": "20191129_Solo_Sequences_04.webm", "media_type": "Movie", "alt_text": "Venus Flyby - Video\rVisualization of a Venus gravity flyby. Solar Orbiter will make numerous gravity assist flybys of Venus (and one of Earth) over the course of its mission to adjust its orbit, bringing it closer to the Sun and also out of the plane of the Solar System to observe the Sun from progressively higher inclinations. This will result in the spacecraft being able to take the first ever images of the Sun’s polar regions, crucial for understanding how the Sun ‘works’. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } } ], "extra_data": {} }, { "id": 321507, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321507", "widget": "Single image", "title": "", "caption": "", "description": "Facing the Sun Part 1 - GIF\r
This visualization begins by showing small sliding doors in the heatshield open to allow the internally-mounted remote-sensing instruments to observe the Sun. Special windows block out heat to protect the instruments during operations. The doors are closed when the instruments are not observing. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232677, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388677, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_05.gif", "filename": "20191129_Solo_Sequences_05.gif", "media_type": "Image", "alt_text": "Facing the Sun Part 1 - GIF\rThis visualization begins by showing small sliding doors in the heatshield open to allow the internally-mounted remote-sensing instruments to observe the Sun. Special windows block out heat to protect the instruments during operations. The doors are closed when the instruments are not observing. Credit: ESA/ATG medialab\r", "width": 960, "height": 540, "pixels": 518400 } } ], "extra_data": {} }, { "id": 321508, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321508", "widget": "Video player", "title": "", "caption": "", "description": "Facing the Sun Part 1 - Video\r
This visualization begins by showing small sliding doors in the heatshield open to allow the internally-mounted remote-sensing instruments to observe the Sun. Special windows block out heat to protect the instruments during operations. The doors are closed when the instruments are not observing. Credit: ESA/ATG medialab\r
", "items": [ { "id": 232679, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388678, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_05.00001_print.jpg", "filename": "20191129_Solo_Sequences_05.00001_print.jpg", "media_type": "Image", "alt_text": "Facing the Sun Part 1 - Video\rThis visualization begins by showing small sliding doors in the heatshield open to allow the internally-mounted remote-sensing instruments to observe the Sun. Special windows block out heat to protect the instruments during operations. The doors are closed when the instruments are not observing. Credit: ESA/ATG medialab\r", "width": 1024, "height": 576, "pixels": 589824 } }, { "id": 232678, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388679, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_05.mp4", "filename": "20191129_Solo_Sequences_05.mp4", "media_type": "Movie", "alt_text": "Facing the Sun Part 1 - Video\rThis visualization begins by showing small sliding doors in the heatshield open to allow the internally-mounted remote-sensing instruments to observe the Sun. Special windows block out heat to protect the instruments during operations. The doors are closed when the instruments are not observing. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } }, { "id": 232680, "type": "media", "extra_data": null, "title": null, "caption": null, "instance": { "id": 388680, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013505/20191129_Solo_Sequences_05.webm", "filename": "20191129_Solo_Sequences_05.webm", "media_type": "Movie", "alt_text": "Facing the Sun Part 1 - Video\rThis visualization begins by showing small sliding doors in the heatshield open to allow the internally-mounted remote-sensing instruments to observe the Sun. Special windows block out heat to protect the instruments during operations. The doors are closed when the instruments are not observing. Credit: ESA/ATG medialab\r", "width": 1920, "height": 1080, "pixels": 2073600 } } ], "extra_data": {} }, { "id": 321509, "url": "https://svs.gsfc.nasa.gov/13505/#media_group_321509", "widget": "Single image", "title": "", "caption": "", "description": "Facing the Sun Part 2 - GIF\r
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During its closest approaches of the Sun, Solar Orbiter will be travelling fast enough to study how magnetically active regions evolve for up to four weeks at a time. Credit: ESA/ATG medialab\r
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At the same time, Solar Orbiter will acquire in situ data and characterise and calibrate its remote-sensing instruments. The first close solar pass will take place in 2022 at around a third of Earth’s distance from the Sun.The spacecraft’s orbit has been chosen to be ‘in resonance’ with Venus, which means that it will return to the planet’s vicinity every few orbits and can again use the planet’s gravity to alter or tilt its orbit. Initially Solar Orbiter will be confined to the same plane as the planets, but each encounter of Venus will increase its orbital inclination. For example, after the 2025 Venus encounter it will make its first solar pass at 17º inclination, increasing to 33º during a proposed mission extension phase, bringing even more of the polar regions into direct view. || ", "release_date": "2020-01-27T16:00:00-05:00", "update_date": "2023-05-03T13:45:14.733133-04:00", "main_image": { "id": 387661, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013532/ESA_Solo_orbit_key_milestones_short.00001_print.jpg", "filename": "ESA_Solo_orbit_key_milestones_short.00001_print.jpg", "media_type": "Image", "alt_text": "AnimationCredit: ESA/ATG medialab", "width": 1024, "height": 576, "pixels": 589824 } }, { "id": 13528, "url": "https://svs.gsfc.nasa.gov/13528/", "page_type": "Produced Video", "title": "Solar Orbiter Media Telecon", "description": "NASA and ESA scientists will present Solar Orbiter, the ESA/NASA collaboration soon to start its journey to the Sun, during a media teleconference on Monday, Jan. 27, 2020 at 2 p.m. EST. Mission experts will discuss Solar Obiter’s uniquely tilted orbit, how the mission will capture the first images of the Sun’s North and South poles, and its ability to tackle major solar mysteries with its comprehensive suite of ten different instruments. The teleconference audio will stream live at:https://www.nasa.gov/liveParticipants include:•Nicola Fox, director of the Heliophysics Division in the Science Mission Directorate at NASA Headquarters in Washington•Chris St. Cyr, former NASA project scientist for the mission at NASA Goddard•Yannis Zouganelis, ESA deputy project scientist for Solar Orbiter at the European Space Astronomy Centre in Madrid, Spain•Anne Pacros, ESA Mission and Payload Manager || ", "release_date": "2020-01-27T13:50:00-05:00", "update_date": "2023-05-03T13:45:14.997577-04:00", "main_image": { "id": 387826, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013528/HPD_Fleet_Charts_12.30.2019.jpg", "filename": "HPD_Fleet_Charts_12.30.2019.jpg", "media_type": "Image", "alt_text": "NASA’s fleet of heliophysics missions studies the Sun, its effects on Earth and the solar system and the nature of space itself. Credit: NASA/Mary Pat Hrybyk-Keith", "width": 720, "height": 405, "pixels": 291600 } }, { "id": 13529, "url": "https://svs.gsfc.nasa.gov/13529/", "page_type": "Produced Video", "title": "NASA y ESA presentarán la última misión al Sol en una teleconferencia de prensa", "description": "Científicos de la NASA y la Agencia Espacial Europea (ESA, por sus siglas en inglés) presentarán la misión Solar Orbiter, una colaboración de la ESA/NASA que está a punto de iniciar su viaje hacia el Sol, durante una teleconferencia de prensa en español el lunes 27 de enero de 2020 a las 11 am EST. Tres expertos de la misión describirán la órbita inclinada única del Solar Orbiter, cómo la misión capturará las primeras imágenes de los polos norte y sur del Sol, y la capacidad de la nave para abordar los principales misterios solares con su completo conjunto de diez instrumentos. El audio de la teleconferencia se retransmitirá en vivo por: https://www.nasa.gov/live· Teresa Nieves-Chinchilla, científica adjunta de proyecto por parte de la NASA para el Solar Orbiter, Centro de Vuelo Espacial Goddard de la NASA en Greenbelt, Maryland, EE.UU.· Luís Sanchez, jefe de desarrollo de operaciones científicas para el Solar Orbiter, Centro Europeo de Astronomía Espacial de la ESA en Madrid, España.· Yaireska Collado-Vega, líder del equipo de pronóstico de la meteorología espacial en el Centro de Modelos Coordinado por la Comunidad, Centro de Vuelo Espacial Goddard de la NASA en Greenbelt, Maryland, EE.UU. || ", "release_date": "2020-01-27T10:45:00-05:00", "update_date": "2023-05-03T13:45:15.276520-04:00", "main_image": { "id": 387849, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013529/Solar_Orbiter_artist_impression_searchweb.png", "filename": "Solar_Orbiter_artist_impression_searchweb.png", "media_type": "Image", "alt_text": "Concepto artístico de la nave espacial Solar Orbiter de la ESA. La misión Solar Orbiter de la ESA observará el Sol desde la órbita de Mercurio en su aproximación más cercana.Créditos: ESA/ATG medialab", "width": 320, "height": 180, "pixels": 57600 } } ], "sources": [], "products": [ { "id": 13539, "url": "https://svs.gsfc.nasa.gov/13539/", "page_type": "Produced Video", "title": "Solar Orbiter and the Solar Cycle", "description": "No description available.", "release_date": "2020-02-14T00:00:00-05:00", "update_date": "2020-02-05T11:50:51.239658-05:00", "main_image": { "id": 1, "url": "https://svs.gsfc.nasa.gov/images/no_preview_web_black.png", "filename": "no_preview_web_black.png", "media_type": "Image", "alt_text": "Current Airborne Fleet", "width": 320, "height": 180, "pixels": 57600 } }, { "id": 13527, "url": "https://svs.gsfc.nasa.gov/13527/", "page_type": "Produced Video", "title": "New Mission Will Take First Peek at Sun’s Poles", "description": "A new spacecraft is journeying to the Sun to snap the first pictures of the Sun’s north and south poles. Solar Orbiter, a collaboration between ESA (the European Space Agency) and NASA will have its first opportunity to launch from Cape Canaveral on Feb. 7, 2020, at 11:15 p.m. EST. Launching on a United Launch Alliance Atlas V rocket, the spacecraft will use Venus’ and Earth’s gravity to swing itself out of the ecliptic plane — the swath of space, roughly aligned with the Sun’s equator, where all planets orbit. From there, Solar Orbiter's bird’s eye view will give it the first-ever look at the Sun's poles.Read more: https://www.nasa.gov/feature/goddard/2020/new-mission-will-take-first-peek-at-sun-s-poles || ", "release_date": "2020-01-27T12:00:00-05:00", "update_date": "2023-05-03T13:45:15.119552-04:00", "main_image": { "id": 387931, "url": "https://svs.gsfc.nasa.gov/vis/a010000/a013500/a013527/13537_SolarOrbiterOverview_YouTube.00725_print.jpg", "filename": "13537_SolarOrbiterOverview_YouTube.00725_print.jpg", "media_type": "Image", "alt_text": "VideoWatch this video on the NASA Goddard YouTube channel.Music credits: “Oxide” and “Virtual Tidings” by Andrew Michael Britton [PRS], David Stephen Goldsmith [PRS]; “Progressive Practice” by Emmanuel David Lipszc [SACEM], Franck Lascombes [SACEM], Sebastien Lipszyc [SACEM]; “Political Spectrum” by Laurent Dury [SACEM} from Universal Production MusicComplete transcript available.", "width": 1024, "height": 576, "pixels": 589824 } } ], "newer_versions": [], "older_versions": [], "alternate_versions": [] }