This video uses images from NASA’s Juno mission to recreate what it might have looked like to ride along with the Juno spacecraft as it performed its 27th close flyby of Jupiter on June 2, 2020.
During the closest approach of this pass, the Juno spacecraft came within approximately 2,100 miles (3,400 kilometers) of Jupiter’s cloud tops. At that point, Jupiter’s powerful gravity accelerated the spacecraft to tremendous speed – about 130,000 mph (209,000 kilometers per hour) relative to the planet.
Citizen scientist Kevin M. Gill created the video using data from the spacecraft’s JunoCam instrument. The sequence combines 41 JunoCam still images digitally projected onto a sphere, with a virtual “camera†providing views of Jupiter from different angles as the spacecraft speeds by.
Video credit: NASA/JPL-Caltech/SwRI/MSSS/Kevin M. Gill
Using data collected by NASA’s OSIRIS-REx mission, this animation shows the trajectories of particles after their emission from asteroid Bennu’s surface. The animation emphasizes the four largest particle ejection events detected at Bennu from December 2018 through September 2019. Additional particles, some with lifetimes of several days, that are not related to the ejections are also visible.
Video credit: M. Brozovic/JPL-Caltech/NASA/University of Arizona
This animation takes the viewer on a simulated journey into Jupiter’s exotic high-altitude electrical storms. Get an up-close view of Mission Juno’s newly discovered “shallow lighting” flashes and dive into the violent atmospheric jet of the Nautilus cloud. The smallest white “pop-up” clouds on top of the Nautilus are about 100 km across. The ride navigates through Jupiter’s towering thunderstorms, dodging the spray of ammonia-water rain, and shallow lighting flashes. At these altitudes — too cold for pure liquid water to exit – ammonia gas acts like an antifreeze that melts the water ice crystals flung up to these heights by Jupiter’s powerful storms – giving Jupiter an unexpected ammonia-water cloud that can electrify the sky. The animation was created by combining an image of high-altitude clouds from the JunoCam imager on NASA’s Juno spacecraft with a computer-generated animation.
Video credit: NASA/JPL-Caltech/SwRI/MSSS/Kevin M. Gil/Animation: Koji Kuramura/Music: Vangelis
Mars’ nightside atmosphere glows and pulsates in this data animation from MAVEN spacecraft observations. Green-to-white false color shows the enhanced brightenings on Mars’ ultraviolet “nightglow” measured by MAVEN’s Imaging UltraViolet Spectrograph at about 70 kilometers (approximately 40 miles) altitude. A simulated view of the Mars globe is added digitally for context, with ice caps visible at the poles. Three nightglow brightenings occur over one Mars rotation, the first much brighter than the other two. All three brightenings occur shortly after sunset, appearing on the left of this view of the night side of the planet. The pulsations are caused by downwards winds which enhance the chemical reaction creating nitric oxide which causes the glow. Months of data were averaged to identify these patterns, indicating they repeat nightly.
Video credit: NASA/MAVEN/Goddard Space Flight Center/CU/LASP
NASA’s Lucy mission is launching in 2021 and will fly by seven different Trojan asteroids that are orbiting the same distance from the Sun as Jupiter. This video highlights the four main science objectives and the instruments aboard the spacecraft that will be utilized. Lucy will be the first space mission to study the Trojan asteroids, which are remnants of our early solar system.
Video credit: NASA’s Goddard Space Flight Center/Produced & Edited by: David Ladd (USRA)/Animations by: David Ladd (USRA), Walt Feimer (KBRwyle), Jacquelyn DeMink (USRA), Michael Lentz (USRA), Jonathan North (USRA)/Music: “Feels Good” – Wally Gagel & Xandy Barry [ASCAP], provided by Universal Production Music
Perseverance, nicknamed Percy, is a Mars rover manufactured by the Jet Propulsion Laboratory for use in NASA’s Mars 2020 mission.
The Perseverance rover was designed with help from the Curiosity’s engineering team, and they are similar to each other. Engineers redesigned the Perseverance rover wheels to be more robust than Curiosity’s wheels, which have sustained some damage. The rover has thicker, more durable aluminum wheels, with reduced width and a greater diameter (52.5 centimetres (20.7 in)) than Curiosity’s 50-centimetre (20 in) wheels. The aluminum wheels are covered with cleats for traction and curved titanium spokes for springy support. The combination of the larger instrument suite, new Sampling and Caching System, and modified wheels makes Perseverance heavier than its predecessor, Curiosity, by 17% (899 kg to 1050 kg). The rover will include a five-jointed robotic arm measuring 2.1 metres (6 ft 11 in) long. The arm will be used in combination with a turret to analyze geologic samples from the Martian surface.
The rover’s power generator (MMRTG) has a mass of 45 kilograms (99 lb) and uses 4.8 kilograms (10.6 lb) of plutonium dioxide as the source of steady supply of heat that is converted to electricity. The electrical power generated is approximately 110 watts at launch with little decrease over the mission time. Two lithium-ion rechargeable batteries are included to meet peak demands of rover activities when the demand temporarily exceeds the MMRTG’s steady electrical output levels. The MMRTG offers a 14-year operational lifetime, and it was provided to NASA by the US Department of Energy. Unlike solar panels, the MMRTG provides engineers with significant flexibility in operating the rover’s instruments even at night and during dust storms, and through the winter season.
The rover’s computer uses the BAE RAD750 radiation-hardened single board computer. The computer contains 128 Megabytes of volatile DRAM, and is run at 133 MHz. The flight software is able to access 4 gigabytes of NAND non-volatile memory on a separate card.
Also travelling with Perseverance as a part of Mars 2020 is the Mars helicopter experiment, named Ingenuity. A solar-powered helicopter drone with a mass of 1.8 kilograms (4.0 lb), it will be tested for flight stability and for its potential to scout the best driving route for the rover over a planned 30-day period. Other than cameras, it carries no scientific instruments.
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