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On Oct. 14, 2023, a “ring of fire,” or annular, solar eclipse will travel from Oregon coast to the Gulf of Mexico. Weather permitting, most of the Americas will be able to view at least a partial solar eclipse. Click here to see the NASA 2023 and 2024 Solar Eclipse Map: https://go.nasa.gov/USEclipseMaps An annular solar eclipse occurs when the Moon passes between the Sun and the Earth, but is just far away enough in its orbit that the Sun is not completely covered—creating a large, bright ring in the sky. WARNING: During an annular eclipse, it is never safe to look directly at the Sun without specialized eye protection designed for solar viewing. How to safely view an eclipse: https://solarsystem.nasa.gov/eclipses... Not in the path of the eclipse? Watch with us from anywhere in the world. We will provide live broadcast coverage on Oct. 14 from 11:30 a.m. to 1:15 p.m. EDT (1530-1715 UTC) on NASA TV, NASA.gov, the NASA app, and right here on YouTube: https://youtube.com/live/LlY79zjud-Q Learn more about the upcoming annular solar eclipse: https://solarsystem.nasa.gov/eclipses... Credit: NASA Producer: Sonnet Apple Music: Universal Production Music

Our Webb Space Telescope captures a cosmic ring, the team behind our upcoming Psyche mission, and the unique thing about a star that was ripped apart by a black hole … a few of the stories to tell you about – This Week at NASA! Link to download this video: https://images.nasa.gov/details/NHQ_2... Video Producer: Andre Valentine Video Editor: Andre Valentine Narrator: Andre Valentine Music: Universal Production Music Credit: NASA

We’re testing a new way of landing on Mars… by crashing into its surface. The Simplified High Impact Energy Landing Device (SHIELD) is a lander concept being tested at NASA’s Jet Propulsion Laboratory (JPL). It could one day provide a new way for low-cost missions to land on Mars. Rather than rely on parachutes or retrorockets, SHIELD would include a collapsible, accordion-like base to absorb the energy of a landing. A full-size prototype of the base was tested on Aug. 12, 2022. The prototype was hurled at the ground from the top of a nearly 90-foot-tall (27-meter-tall) drop tower at JPL. A steel plate ensured the impact was even harder than what would be experienced on Mars. The design worked: After crushing against the steel plate at 110 mph (177 kph), several electronic components inside the SHIELD prototype, including a smartphone, survived the impact. Credit: NASA/JPL-Caltech/California Academy of Sciences

NASA’s Lucy mission is heading to the Jupiter Trojans – two swarms of primitive asteroids trapped in Jupiter’s orbit that may hold clues to the formation of the planets. Lucy launched on October 16, 2021. After a year in orbit around the Sun, it is returning home on its launch anniversary for the first of three Earth gravity assists. On October 16, 2022, Lucy will fly by the Earth like a partner in a swing dance, boosting its speed and elongating its orbit around the Sun. At 7:04 am, Eastern Time, Lucy will make its closest approach at just 219 miles above the planet: lower than the International Space Station. This exceptionally close shave will increase its velocity by four-and-a-half miles per second, setting Lucy on track to gain even more speed when it returns to Earth for its second gravity assist in December 2024. Read more: https://www.nasa.gov/feature/goddard/2022/lucy-ega Credit: NASA’s Goddard Space Flight Center Dan Gallagher (KBRwyle): Producer Kel Elkins (USRA): Lead Visualizer Walt Feimer (KBRwyle): Lead Animator Jenny McElligott (AIMM): Animator Krystofer Kim (KBRwyle): Animator Jonathan North (KBRwyle): Animator Katherine Kretke (SwRI): Support Ernie Wright (USRA): Support Aaron E. Lepsch (ADNET): Technical Support Universal Production Music: “Determined Arrival 5” by Joel Goodman; “Finding Solace” by Eric Chevalier; “Subtle Confidence 3” by Joel Goodman This video can be freely shared and downloaded at https://svs.gsfc.nasa.gov/14225. While the video in its entirety can be shared without permission, the music and some individual imagery may have been obtained through permission and may not be excised or remixed in other products. Specific details on such imagery may be found here: https://svs.gsfc.nasa.gov/14225. For more information on NASA’s media guidelines, visit https://nasa.gov/multimedia/guidelines. If you liked this video, subscribe to the NASA Goddard YouTube channel: https://www.youtube.com/NASAGoddard Follow NASA’s Goddard Space Flight Center · Instagram http://www.instagram.com/nasagoddard · Twitter http://twitter.com/NASAGoddard · Twitter http://twitter.com/NASAGoddardPix · Facebook: http://www.facebook.com/NASAGoddard · Flickr http://www.flickr.com/photos/gsfc

Watch live as the Dragon Freedom spacecraft undocks with the four crew members of NASA’s SpaceX Crew-4 mission aboard: NASA astronauts Kjell Lindgren, Bob Hines, and Jessica Watkins, as well as ESA (European Space Agency) astronaut Samantha Cristoforetti. Undocking from the International Space Station (ISS) is targeted for Friday, Oct. 14. Splashdown is targeted several hours later at 4:55 p.m. EDT (2055 UTC) Friday off the coast of Florida. During their stay of nearly six months on the ISS, Crew-4 members contributed to ongoing and new scientific investigations and technology demonstrations, work that is helping to prepare humans for future space exploration missions and generating innovations and benefits for humanity on Earth: https://youtu.be/J61Y5AJ-Kog

About Video:- step 1 rough breaking phase In this step, the lander left its orbit and started braking to land. When rough braking starts, the lander remains 30 kilometers above the lunar surface. Step 2 altitude hold Altitude hold phase will start from 7.4km moon surface. In this step, lander will hold its altitude at one place and study thehazardous free lunar surface for land. Step 3 fine breaking In the fine braking state, the lander will gradually reduce the verticalvelocity. Step 4 terminal descent When the lander is about to land on the surface of the moon, at that time it will turn on all its boosters and successfully land slowly.

India on August 23 scripted history by becoming the first country to successfully soft-land on the moon's south pole. Following the landing, congratulations poured in from all across the world including major space giants NASA and the UK Space Agency were among the ones who congratulated India immediately after it landed on the moon. Taking to X Handle, NASA’s Bill Nelson said that “We are glad to be your partner on this mission!” The UK Space Agency was also quick to congratulate India for the historic achievement. In a statement, Anu Ojha said that “Chandrayaan-3 on the moon is further evidence that we are living in a new space age”. With this success, India has become the fourth country- after the US, China and Russia – to have successfully landed on the moon’s surface. India has also earned a place in record books as the first to touchdown on the south side of Earth’s only natural satellite. #NASA #Chandrayan3 #ISRO

How do spacecraft slow down? Rigid heat shields and retropropulsion have been the favorites of engineers for years. Now NASA is testing a new inflatable heat shield technology that could allow us to carry even larger payloads to worlds with atmospheres: https://www.nasa.gov/loftid Launching on Nov. 1 aboard a United Launch Alliance Atlas V rocket along with NOAA’s JPSS-2 mission, the Low-Earth Orbit Flight Test of an Inflatable Decelerator, or LOFTID, will demonstrate the heat shield’s ability to slow down and survive atmospheric entry: https://go.nasa.gov/3N7yzBG Producers: Scott Bednar, Jessica Wilde Editor: Daniel Salazar Credit: NASA #NASA #Technology #Spacecraft

NASA’s Perseverance Mars rover is filling sample tubes with rocky material on the Red Planet as the agency works on the next steps to get them safely back to Earth. The Mars Sample Return campaign would bring samples collected by the Perseverance rover to Earth for detailed study. The campaign involves an international interplanetary relay team, including the European Space Agency (ESA). These samples could answer a key question: did life ever exist on Mars? Aaron Yazzie, who works on the Mars Sample Return campaign, explains the work being done at NASA’s Jet Propulsion Laboratory to ensure the safe return of the sample tubes. For more information on Mars Sample Return, visit mars.nasa.gov/msr Credit: NASA/JPL-Caltech

chronicles solar activity from Aug. 12 to Dec. 22, 2022, as captured by NASA’s Solar Dynamics Observatory (SDO). From its orbit in space around Earth, SDO has steadily imaged the Sun in 4K x 4K resolution for nearly 13 years. This information has enabled countless new discoveries about the workings of our closest star and how it influences the solar system. With a triad of instruments, SDO captures an image of the Sun every 0.75 seconds. The Atmospheric Imaging Assembly (AIA) instrument alone captures images every 12 seconds at 10 different wavelengths of light. This 133-day time lapse showcases photos taken at a wavelength of 17.1 nanometers, which is an extreme-ultraviolet wavelength that shows the Sun’s outermost atmospheric layer: the corona. Compiling images taken 108 seconds apart, the movie condenses 133 days, or about four months, of solar observations into 59 minutes. The video shows bright active regions passing across the face of the Sun as it rotates. The Sun rotates approximately once every 27 days. The loops extending above the bright regions are magnetic fields that have trapped hot, glowing plasma. These bright regions are also the source of solar flares, which appear as bright flashes as magnetic fields snap together in a process called magnetic reconnection. While SDO has kept an unblinking eye pointed toward the Sun, there have been a few moments it missed. Some of the dark frames in the video are caused by Earth or the Moon eclipsing SDO as they pass between the spacecraft and the Sun. Other blackouts are caused by instrumentation being down or data errors. SDO transmits 1.4 terabytes of data to the ground every day. The images where the Sun is off-center were observed when SDO was calibrating its instruments. SDO and other NASA missions will continue to watch our Sun in the years to come, providing further insights about our place in space and information to keep our astronauts and assets safe. The music is a continuous mix from Lars Leonhard’s “Geometric Shapes” album, courtesy of the artist. Credit: NASA's Goddard Space Flight Center Scott Wiessinger (PAO): Lead Producer Tom Bridgman (SVS): Lead Visualizer Scott Wiessinger (PAO): Editor This video can be freely shared and downloaded at https://svs.gsfc.nasa.gov/14263. While the video in its entirety can be shared without permission, the music and some individual imagery may have been obtained through permission and may not be excised or remixed in other products. Specific details on such imagery may be found here: https://svs.gsfc.nasa.gov/14263. For more information on NASA’s media guidelines, visit https://nasa.gov/multimedia/guidelines. Video Description: On the left side of the frame is the full circle of the Sun. It appears in a golden yellow color, but splotchy and with thin yellow wisps extending from the surface. Some areas are very bright and others almost black. The whole Sun rotates steadily, with one full rotation taking 12 minutes in this time lapse. There are usually only a few bright regions visible at a time and they shift and flash like small fires. From these regions there are wispy loops reaching up above the surface that rapidly change shape and size. On the right side of the frame are two white-outlined squares with enlargements of interesting regions of the Sun. If you liked this video, subscribe to the NASA Goddard YouTube channel: https://www.youtube.com/NASAGoddard Follow NASA’s Goddard Space Flight Center · Instagram http://www.instagram.com/nasagoddard · Twitter http://twitter.com/NASAGoddard · Twitter http://twitter.com/NASAGoddardPix · Facebook: http://www.facebook.com/NASAGoddard · Flickr http://www.flickr.com/photos/gsfc

A new Earth science mission, led by NASA and the French space agency Centre National d’Études Spatiales (CNES), will help communities plan for a better future by surveying the planet’s salt and freshwater bodies. The Surface Water and Ocean Topography (SWOT) mission will measure the height of water in lakes, rivers, reservoirs, and the oceans. As climate change accelerates the water cycle, more communities around the world will be inundated with water while others won’t have enough. SWOT data will be used to improve flood forecasts and monitor drought conditions, providing essential information to water management agencies, civil engineers, universities, the U.S. Department of Defense, disaster preparedness agencies, and others who need to track water in their local areas. In this video, examples of how SWOT data will be used in these communities are shared by a National Weather Service representative in Oregon, an Alaska Department of Transportation engineer, researchers from the University of Oregon and University of North Carolina, a NASA Jet Propulsion Laboratory scientist working with the Department of Defense, and a JPL scientist working with the Louisiana Coastal Protection and Restoration Agency. :30 - Flood Watches & Warnings - Portland, Oregon 1:08 - Water Management - Fern Ridge Lake, Oregon 2:05 - Protecting Infrastructure - Alaska 2:54 - National Security - Department of Defense 3:24 - Coastal Protection - Mississippi River Delta SWOT is expected to launch from Vandenberg Space Force Base in California in December 2022. The mission is a collaboration between NASA and CNES, with contributions from the Canadian Space Agency and UK Space Agency. JPL, which is managed for NASA by Caltech in Pasadena, California, leads the U.S. component of the project. To learn more about the mission, visit: https://swot.jpl.nasa.gov Credit: NASA/JPL-Caltech/CNES/Thales Alenia Space