OrbitalHub

NASA Jet Propulsion Laboratory dicit:

NASA’s InSight lander detected seismic waves from a meteoroid and was able to capture the sound of the space rock striking the surface of Mars for the first time. The meteoroid – the term used for incoming space rocks before they hit the ground – entered Mars’ atmosphere on Sept. 5, 2021, exploding into at least three shards that each left craters behind. Mars’ atmosphere is just 1% as dense as Earth’s, allowing far more meteoroids to pass through and impact the Red Planet’s surface.

This event marks the first time seismic and acoustic waves from an impact were detected on the Red Planet. Why does this meteoroid impact sound like a “bloop” in the video? It has to do with a peculiar atmospheric effect that’s also observed in deserts on Earth.

After sunset, the atmosphere retains some heat accumulated during the day. Sound waves travel through this heated atmosphere at different speeds, depending on their frequency. As a result, lower-pitched sounds arrive before high-pitched sounds. An observer close to the impact would hear a “bang,” while someone many miles away would hear the bass sounds first, creating a “bloop.”

NASA’s Mars Reconnaissance Orbiter flew over the estimated impact site to confirm the location. The orbiter used its black-and-white Context Camera to reveal three darkened spots on the surface.

After locating these spots, the orbiter’s team used the High-Resolution Imaging Science Experiment camera, or HiRISE, to get a color close-up of the craters. Because HiRISE sees wavelengths the human eye can’t detect, scientists change the camera’s filters to enhance the color of the image. The areas that appear blue around the craters are where dust has been removed or disturbed by the blast of the impact. Martian dust is bright and red, so removing it makes the surface appear relatively dark and blue.

Credit: NASA/JPL-Caltech/University of Maryland/University of Arizona/CNES/IPGP/Manchu/Bureau 21/ETH Zurich/Kirschner/van Driel

NASA Goddard dicit:

Welcome to one of the most active galaxies in our cosmic neighborhood, NGC 1569. This starburst galaxy creates stars at a rate 100 times faster than in our own galaxy, the Milky Way!

Scientists represented information in this Hubble image with sound to create a beautiful sonification with a bottom to top scan. Brighter light is higher pitched and louder. The three color channels used to process this image are each given their own pitch range, with red representing lower pitches, green in medium pitches, and blue in high pitches.

Sonification credits: SYSTEM Sounds (M. Russo, A. Santaguida)

Credit: NASA Goddard

Lockheed Martin dicit:

You can’t get all the way to Mars without fuel – and a lot of it. Chemical propulsion has been the standard for spaceflight for decades, but if humans are to travel to Mars, they need a propulsion technology much more powerful.

Although they’re relatively new – nuclear systems for propulsion or electrical power are simple. Fission-based systems work by splitting low-enriched uranium atoms in a reactor to create heat. Super-cooled hydrogen is flowed into the reactor and the heat from the uranium quickly turns the hydrogen into a very hot, pressurized gas.

In nuclear thermal propulsion (NTP), the super-hot pressurized hydrogen is funnelled out a nozzle to create a powerful thrust. The mechanics of an NTP engine are much simpler and vastly more efficient than chemical propellant engines.

In fission surface power systems, the heat from the splitting of uranium atoms is converted to electricity. These systems can produce at least 40 kilowatts of power and can operate on permanently shadowed regions of the Moon.

Credit: Lockheed Martin

Wikipedia dicit:

The James Webb Space Telescope (JWST) is a space telescope designed primarily to conduct infrared astronomy. As the largest optical telescope in space, its greatly improved infrared resolution and sensitivity allow it to view objects too early, distant, or faint for the Hubble Space Telescope. This is expected to enable a broad range of investigations across the fields of astronomy and cosmology, such as observation of the first stars and the formation of the first galaxies, and detailed atmospheric characterization of potentially habitable exoplanets.

The U.S. National Aeronautics and Space Administration (NASA) led JWST’s development in collaboration with the European Space Agency (ESA) and the Canadian Space Agency (CSA). The NASA Goddard Space Flight Center (GSFC) in Maryland managed telescope development, the Space Telescope Science Institute in Baltimore on the Homewood Campus of Johns Hopkins University operates JWST, and the prime contractor was Northrop Grumman. The telescope is named after James E. Webb, who was the administrator of NASA from 1961 to 1968 during the Mercury, Gemini, and Apollo programs.

The James Webb Space Telescope was launched on 25 December 2021 on an Ariane 5 rocket from Kourou, French Guiana, and arrived at the Sun–Earth L2 Lagrange point in January 2022. The first image from JWST was released to the public via a press conference on 11 July 2022. The telescope is the successor of the Hubble as NASA’s flagship mission in astrophysics.

Credit: Lockheed Martin

NASA dicit:

NASA must place more emphasis on protecting both the crew and the exploration surface systems if they hope to achieve long-duration sustainability on the lunar surface. It is now reasonably achievable with excavation, construction, and autonomy technologies to achieve a significant level of protection that architectures have been unable to achieve to date. The Lunar Safe Haven (LSH) was proposed to protect astronauts, electronics, and other surface exploration systems from the hazards of the lunar environment, including radiation, micrometeoroid strikes, lunar dust, thermal vacuum, and more.

Credit: NASA Langley Research Center

Wikipedia dicit:

SpaceX CRS-25, also known as SpX-25, is a Commercial Resupply Service mission to the International Space Station (ISS) that was launched on 15 July 2022. The mission is contracted by NASA and is flown by SpaceX using a Cargo Dragon. This is the fifth flight for SpaceX under NASA’s CRS Phase 2 contract awarded in January 2016.

The launch of CRS-25 was previously delayed to 11 July to investigate a possible leak in the Dragon’s Draco thruster propulsion system detected during pre-launch testing. The previously scheduled launch date was June 10.

SpaceX plans to reuse the Cargo Dragons up to five times. The Cargo Dragon will launch without SuperDraco abort engines, without seats, cockpit controls and the life support system required to sustain astronauts in space. This newer design comes with some benefits, like a faster process to recover, and refurbish and re-fly versus the earlier Dragon CRS design used for ISS cargo missions.

Credit: SpaceX/NASA’s Kennedy Space Center