Juno de la NASA obtiene la vista de mayor resolución de la luna helada Europa de Júpiter

Detalles de la superficie de Europa Unidad de referencia estelar de Juno:

Las características de la superficie de la luna helada de Júpiter se revelan en esta imagen tomada por la Unidad de Referencia Estelar (SRU) de Juno durante el sobrevuelo de la nave espacial el 29 de septiembre de 2022. Crédito: NASA/JPL-Caltech/SwRI

Las observaciones de la nave espacial Juno del sobrevuelo de la Luna fueron los primeros primeros planos de este mundo oceánico en más de dos décadas, lo que resultó en imágenes notables y una ciencia única.

foto de mayor resolución[{» attribute=»»>NASA’s Juno mission has ever taken of a specific portion of Jupiter’s moon Europa reveals a detailed view of a puzzling region of the moon’s heavily fractured icy crust.

The image covers about 93 miles (150 kilometers) by 125 miles (200 kilometers) of Europa’s surface, revealing a region crisscrossed with a network of fine grooves and double ridges (pairs of long parallel lines indicating elevated features in the ice). Near the upper right of the image, as well as just to the right and below center, are dark stains possibly linked to something from below erupting onto the surface. Below center and to the right is a surface feature that recalls a musical quarter note, measuring 42 miles (67 kilometers) north-south by 23 miles (37 kilometers) east-west. The white dots in the image are signatures of penetrating high-energy particles from the severe radiation environment around the moon.

Jupiter Moon Europa Juno 2022

The complex, ice-covered surface of Jupiter’s moon Europa was captured by NASA’s Juno spacecraft during a flyby on September 29, 2022. At closest approach, the spacecraft came within a distance of about 219 miles (352 kilometers). Credit: NASA/JPL-Caltech/SWRI/MSSS

Juno’s Stellar Reference Unit (SRU) – a star camera used to orient the spacecraft – obtained the black-and-white image during the spacecraft’s flyby of Europa on September 29, 2022, at a distance of about 256 miles (412 kilometers). With a resolution that ranges from 840 to 1,115 feet (256 to 340 meters) per pixel, the image was captured as Juno raced past at about 15 miles per second (24 kilometers per second) or 54,000 mph (86,000 km/h) over a part of the surface that was in nighttime, dimly lit by “Jupiter shine” – sunlight reflecting off Jupiter’s cloud tops.

Designed for low-light conditions, the SRU has also proven itself a valuable science tool, discovering shallow lightning in Jupiter’s atmosphere, imaging Jupiter’s enigmatic ring system (see image below), and now providing a glimpse of some of Europa’s most fascinating geologic formations.

Jupiter's Main Dust Ring

This high-resolution image of Jupiter’s main dust ring was collected by the Stellar Reference Unit (SRU) navigation camera aboard NASA’s Juno spacecraft. The image was taken from inside the ring looking out as Juno flew between Jupiter and the radiation belts during the spacecraft’s 36th close flyby on September 2, 2021. The brightest thin dust bands are associated with the orbits of Jupiter’s small moons, Metis and Adrastea. The image is at a resolution of nearly 20 miles (32 kilometers) per pixel. Credit: NASA/JPL-Caltech

“This image is unlocking an incredible level of detail in a region not previously imaged at such resolution and under such revealing illumination conditions,” said Heidi Becker, the lead co-investigator for the SRU. “The team’s use of a star-tracker camera for science is a great example of Juno’s groundbreaking capabilities. These features are so intriguing. Understanding how they formed – and how they connect to Europa’s history – informs us about internal and external processes shaping the icy crust.”

It won’t just be Juno’s SRU scientists who will be busy analyzing data in the coming weeks. During Juno’s 45th orbit around Jupiter, all of the spacecraft’s science instruments were collecting data both during the Europa flyby and then again as Juno flew over Jupiter’s poles a short 7 ½ hours later.

“Juno started out completely focused on Jupiter. The team is really excited that during our extended mission, we expanded our investigation to include three of the four Galilean satellites and Jupiter’s rings,” said Juno Principal Investigator Scott Bolton of the Southwest Research Institute in San Antonio. “With this flyby of Europa, Juno has now seen close-ups of two of the most interesting moons of Jupiter, and their ice shell crusts look very different from each other. In 2023, Io, the most volcanic body in the solar system, will join the club.” In June 2021, Juno sailed by Jupiter’s moon Ganymede – the solar system’s largest moon.

Europa is the solar system’s sixth-largest moon with about 90% of the equatorial diameter of Earth’s moon. Scientists are confident a salty ocean lies below a miles-thick ice shell, sparking questions about the potential habitability of the ocean. In the early 2030s, NASA’s Europa Clipper spacecraft will arrive and strive to answer these questions about Europa’s habitability. The data from the Juno flyby provides a preview of what that mission will reveal.

More About the Mission

NASA’s Jet Propulsion Laboratory (JPL), a division of the California Institute of Technology (Caltech) in Pasadena, California, manages the Juno mission for the principal investigator, Scott J. Bolton, of the Southwest Research Institute in San Antonio. Lockheed Martin Space in Denver built and operates the spacecraft. Juno is part of NASA’s New Frontiers Program, which is managed at NASA’s Marshall Space Flight Center in Huntsville, Alabama, for the agency’s Science Mission Directorate in Washington.

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