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Week in images: 27-31 January 2025
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By NASA
Skywatching Skywatching Home What’s Up Eclipses Explore the Night Sky Night Sky Network More Tips and Guides FAQ A Month of Bright Planets
Venus blazes at its brightest for the year after sunset, then Mars and Jupiter to rule the night amid the menagerie of bright winter stars.
Skywatching Highlights
All Month – Planet Visibility:
Mercury: Pops up just above the horizon in late February, looking relatively bright as sunset fades Venus: Looking brilliant in the west after sunset all month Mars: Bright and amber-orange colored, high in the east each evening. It’s the last planet to set in the west a couple of hours before sunrise Jupiter: Find the giant planet high overhead in the evening, looking very bright Saturn: Somewhat faint, but visible low in the west for the first hour after sunset; increasingly lower as the month goes on Daily Highlights:
February 1 – Venus & Moon: The crescent Moon cozies up to brilliant Venus tonight in the west after sunset. Saturn hangs below them.
February 5 – Moon & Pleiades: Look for the Moon only a finger’s width west of the Pleiades at nightfall, then crossing in front of the star cluster before setting
February 6 – Moon & Jupiter: The Moon is high overhead at nightfall, forming a line with bright Jupiter and reddish star Aldebaran in Taurus
February 9 – Moon & Mars: Find the nearly full Moon in the east tonight after dark, about three finger widths below reddish Mars. Bright stars Pollux and Castor in Gemini are just to its north.
February 12 – Full Moon
Transcript
What’s Up for February? The Moon’s many engagements, what’s the right term for a planetary rendezvous, and the goddess of love draws near.
Moon & Planets
Starting with the Moon’s journey across the sky this month, you’ll find the slim crescent of Earth’s natural satellite cozied up to the planet Venus on the 1st. It then visits the Pleiades on the 5th, and hops over Jupiter on the 6th, looking increasingly fuller, before arriving right next to Mars on February 9th.
Sky chart showing Jupiter and Mars high overhead after nightfall in February 2025. Jupiter and Mars rule the sky on February nights. You’ll find them high overhead in the evening, together with the winter constellations of Orion, Taurus, and Gemini.
Appulses
Astronomers sometimes get picky about their terminology. For instance, the apparent close approaches of objects on the sky, like two planets, or the Moon and a planet, are commonly called “conjunctions,” and we often use that term in this video series.
However, most of the time, the technically correct term is an “appulse.” Conjunctions technically occur when two objects have the same right ascension, and they don’t have to appear close together in the sky. (Right ascension is a way of indicating where an object is along the sky from east to west, similar to how we measure longitude on Earth’s surface.)
Appulses are simply the times when two objects appear at their closest in the sky, regardless of whether they have to have the same “space coordinates.” The term comes from a Latin word meaning “brought near” or “driven toward.” And now that you know the distinction, you can choose to keep it casual or impress others with some next-level astronomy knowledge. Either way, it’s all about enjoying the view.
Venus Draws Near
February is a month for love, so what better time to spotlight Venus, which is associated with the Roman goddess of love? This month, Venus shines at its brightest for the year. It’ll remain dazzling through the start of March as it slowly descends from its late-January high point in the sky. By mid-March, it will disappear into the glare of sunset, only to reappear as a morning object in April.
Through a telescope, Venus becomes larger as it comes closer to Earth in its orbit. It also becomes a slimmer crescent. Nonetheless, this is when the planet is at its brightest in our skies. NASA/JPL-Caltech Now, you may have heard that Venus goes through phases, just like the Moon. You can see these phases with a modest telescope. But there’s a surprising twist: unlike the Moon, Venus isn’t at its brightest when it’s “full.” Instead, it shines most brilliantly in our skies when it’s a thinner crescent! It all comes down to distance. See, Venus only appears fuller when it’s on the far side of the Sun, and much farther from Earth. As it comes closer to us, its phase becomes a crescent, but the planet also looks much larger in the sky. Even as a crescent, the light from its closer position more than makes up for the smaller phase.
So, remember this Valentine’s proverb: “The goddess of love is at her most radiant when nearby!”
Moon Phases
Sky chart showing Jupiter and Mars high overhead after nightfall in February. NASA/JPL-Caltech Above are the phases of the Moon for February. Stay up to date on all of NASA’s missions exploring the solar system and beyond at science.nasa.gov. I’m Preston Dyches from NASA’s Jet Propulsion Laboratory, and that’s What’s Up for this month.
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By NASA
Reducing reliance on resupply missions
Resupply of life support elements such as air, water, food, clothing, and hygiene items will be impractical on missions to the Moon and beyond. This research assessed current use and resupply of these elements on the International Space Station and outlines technologies needed for sustained human presence in space, such as 3D printing maintenance parts, systems for laundering clothes, and improved recovery and recycling of elements.
Researchers analyzed the types and mass of elements supplied from Earth to the station and astronaut feedback from various studies and interviews. The paper also used data from ISS Internal Environments, a wide-ranging investigation that samples various aspects of the space station environment in support of many types of research.
Japan Aerospace Exploration Agency astronaut Satoshi Furukawa exercises on the station’s treadmill. Astronauts currently have no way to launder clothes in space.NASA
Verifying a technique for analyzing emulsions
This paper presents a review of examining the behavior of emulsions (suspensions of particles in a liquid) in microgravity using a technique called diffusing wave spectroscopy. Results offer insights that could support development of technologies to improve living environments and foods for crew members on future missions.
FSL Soft Matter Dynamics – PASTA studied the dynamics of droplets in emulsions. Accurate study and characterization of the effects of additives on emulsion stability is possible in microgravity. Emulsions have applications in foods, cosmetics, pharmaceuticals, fuels, paints and coatings, chemical processing, and materials.
European Space Agency astronaut Samantha Cristoforetti exchanges samples for the FSL Soft Matter Dynamics-PASTA investigation.NASA
EEG measurements and predicting cognitive changes in spaceflight
Researchers used an electroencephalogram (EEG) to measure brainwave activity during a relaxed, wakeful state in crew members and found no significant differences before, during, and after flight. These types of measurements could serve as biomarkers of brain health status, helping to predict changes in cognitive performance and the need for prevention and countermeasure strategies during future missions.
Studies have shown that spaceflight can affect key cognitive and motor skills such as task management, attention, and movement speed and accuracy. Neurowellness in Space Ax-1 tested using a portable, easy to use EEG headset to measure ongoing and task-related brain activity in microgravity. The data could help predict and monitor neural changes on future space missions.
The 11-person crew aboard the station in April 2022 included Axiom Mission 1 astronauts (center row from left) Mark Pathy, Eytan Stibbe, Larry Conner, and Michael Lopez-Alegria.NASAView the full article
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By NASA
4 Min Read NASA Space Tech’s Favorite Place to Travel in 2025: The Moon!
The first image from space of Firefly's Blue Ghost mission 1 lunar lander as it begins its 45-day transit period to the Moon. Credits: Firefly Aerospace NASA Space Technology has big travel plans for 2025, starting with a trip to the near side of the Moon!
Among ten groundbreaking NASA science and technology demonstrations, two technologies are on a ride to survey lunar regolith – also known as “Moon dust” – to better understand surface interactions with incoming lander spacecraft and payloads conducting experiments on the surface. These dust demonstrations and the data they’re designed to collect will help support future lunar missions.
Blue Ghost Mission 1 launched at 1:11 a.m. EST aboard a SpaceX Falcon 9 rocket from Launch Complex 39A at the agency’s Kennedy Space Center in Florida. The company is targeting a lunar landing on Sunday, March 2.
The first image from space of Firefly’s Blue Ghost mission 1 lunar lander as it begins its 45-day transit period to the Moon. Firefly Aerospace NASA Space Technology on Blue Ghost Mission 1
NASA’s Electrodynamic Dust Shield (EDS) will lift, transport, and remove particles using electric fields to repel and prevent hazardous lunar dust accumulation on surfaces. The agency’s Stereo Camera for Lunar Plume-Surface Studies (SCALPSS) technology will use stereo imaging to capture the impact of rocket plumes on lunar regolith as the lander descends to the Moon’s surface, returning high-resolution images that will help in creating models to predict regolith erosion – an important task as bigger, heavier payloads are delivered to the Moon in close proximity to each other.
The EDS and SCALPSS technologies will be delivered to the Moon on Firefly’s first Blue Ghost mission, named Ghost Riders in the Sky, as part of NASA’s CLPS (Commercial Lunar Payload Services) initiative. Its landing target is a 300-mile-wide basin located on the Moon’s near side, called Mare Crisium – a large, dark, basaltic plain that filled an ancient asteroid impact. First-of-their-kind experiments will deploy after landing to gather important data in a broad spectrum of areas including geophysical characteristics, global navigation, radiation tolerant computing, and the behavior of lunar regolith.
Replicating the Moon’s harsh environment on Earth is a significant challenge because of extreme temperatures, low gravity, radiation, and dusty surface. The CLPS initiative provides unprecedented access to the lunar surface, allowing us to demonstrate technologies in the exact conditions they were designed for. Missions like Blue Ghost Mission 1 are a true game changer for NASA technology advancement and demonstration.”
Michael Johansen
Flight Demonstrations Lead for NASA’s Game Changing Development program
Dust particles scatter during an experiment for the Electrodynamic Dust Shield in a laboratory at NASA’s Kennedy Space Center in Florida. NASA NASA’s Stereo Camera for Lunar Plume-Surface Studies technology integrated on Firefly’s Blue Ghost lander. Firefly Aerospace A complex wrinkle ridge in Mare Crisium at low Sun, seen in an image captured by the Lunar Reconnaissance Orbiter Camera.NASA/GSFC/Arizona State University Understanding regolith
The Moon’s dusty environment was one of the greatest challenges astronauts faced during Apollo Moon missions, posing hazards to lunar surface systems, space suits, habitats, and instrumentation. What was learned from those early missions – and from thousands of experiments conducted on Earth and in space since – is that successful surface missions require the ability to eliminate dust from all kinds of systems. Lunar landings, for example, cause lunar dust to disperse in all directions and collect on everything that lands there with it. This is one of the reasons such technologies are important to understand. The SCALPSS technology will study the dispersion of lunar dust, while EDS will demonstrate a solution to mitigate it.
Getting this new data on lunar regolith with be pivotal for our understanding of the lunar surface. We’ve long known that lunar dust is a huge challenge. The Lunar Surface Innovation Initiative has enabled us to initiate lunar dust mitigation efforts across the agency, working with industry and international partners. The lunar science, exploration, and technology communities are eager to have new quantitative data, and to prove laboratory experiments and develop technology solutions.”
Kristen John
Technical Integration Lead for NASA’s Lunar Surface Innovation Initiative (LSII)
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[VIDEO] Dust on the lunar surface is a significant hazard for systems and astronauts living and working on the Moon. NASA space technologies are developing solutions to retire hurdles in this capability area. NASA Space Technology Dust mitigation technology has come a long way, but we still have a lot to learn to develop surface systems and infrastructure for more complex missions. LSII is actively engaged in this effort, working with the lunar community across sectors to expand knowledge and design new approaches for future technologies. Working alongside the Lunar Surface Innovation Consortium, LSII has a unique opportunity to take a holistic look at dust’s role in the development of surface infrastructure with other key capability areas including in-situ resource utilization, surface power, and surviving the lunar night.
Learning from the the Moon benefits Mars science and exploration
Capabilities for minimizing dust interaction are as important for future missions on Mars as it is for missions on the Moon. Like the Moon, Mars is also covered with regolith, also called Martian dust or Martian soil, but the properties are different than lunar regolith, both in shape and mineralogy. The challenges Mars rovers have encountered with Martian regolith have provided great insight into the challenges we will face during lunar surface missions. Learning is interwoven and beneficial to future missions whether hundreds of thousands of miles from Earth, on the Moon, or millions, on Mars.
Scientist-astronaut Harrison Schmitt, Apollo 17 lunar module pilot, uses an adjustable sampling scoop to retrieve lunar samples during the second Apollo 17 extravehicular activity (EVA). NASA NASA’s Perseverance Mars rover snagged two samples of regolith – broken rock and dust – on Dec. 2 and 6, 2022. This set of images, taken by the rover’s left navigation camera, shows Perseverance’s robotic arm over the two holes left after the samples were collected.NASA/JPL-Caltech Learn more from a planetary scientist about how science factors into lunar dust mitigation technologies:
LSIC Lunar Engineering 101 video series (Dust/Regolith module) Share
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Last Updated Jan 24, 2025 LocationNASA Headquarters Related Terms
Missions Artemis Commercial Lunar Payload Services (CLPS) Earth's Moon Game Changing Development Program Kennedy Space Center Langley Research Center Lunar Surface Innovation Consortium Lunar Surface Innovation Initiative NASA Headquarters Space Technology Mission Directorate Explore More
4 min read NASA Cameras to Capture Interaction Between Blue Ghost, Moon’s Surface
Article 1 month ago 4 min read NASA Technology Helps Guard Against Lunar Dust
Article 10 months ago 3 min read NASA Lander to Test Vacuum Cleaner on Moon for Sample Collection
Article 2 weeks ago Keep Exploring Discover More Topics From NASA
Space Technology Mission Directorate
NASA’s Lunar Surface Innovation Initiative
Game Changing Development Projects
Game Changing Development projects aim to advance space technologies, focusing on advancing capabilities for going to and living in space.
Commercial Lunar Payload Services (CLPS)
The goal of the CLPS project is to enable rapid, frequent, and affordable access to the lunar surface by helping…
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By European Space Agency
Week in images: 20-24 January 2025
Discover our week through the lens
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