This Feb. 5, 1971, photo gives an excellent view of the Apollo 14 lunar module on the Moon’s surface after landing. At left, we can see that the astronauts – Alan Shepard and Edgar Mitchell – deployed the U.S. flag before taking this photo of the lunar module.
Shepard and Mitchell touched down in the Fra Mauro highlands region and conducted two moonwalks lasting more than nine hours in total. They set up an experiment package and collected 93 pounds of rock and soil samples to return to waiting scientists on Earth. In the meantime, astronaut Stuart Roosa, who remained in orbit aboard the command module, conducted observations and photography of the lunar surface from orbit. After their 33-hour lunar surface stay, Shepard and Mitchell rejoined Roosa in orbit, and left lunar orbit for the three-day return trip to Earth.
NASA Goes Live: First Twitch Stream from Space Station
NASA astronaut Don Pettit aboard the International Space Station. (Credit: NASA)
For the first time, NASA is hosting a live Twitch event from about 250 miles off the Earth aboard the International Space Station, bringing new audiences closer to space than ever before. Viewers will have the opportunity to hear from NASA astronauts live and ask questions about life in orbit.
The event will begin at 11:45 a.m. EST on Wednesday, Feb. 12, livestreamed on the agency’s official Twitch channel:
“This Twitch event from space is the first of many,” said Brittany Brown, director, Office of Communications Digital and Technology Division, at NASA Headquarters in Washington. “We spoke with digital creators at TwitchCon about their desire for streams designed with their communities in mind, and we listened. In addition to our spacewalks, launches, and landings, we’ll host more Twitch-exclusive streams like this one. Twitch is one of the many digital platforms we use to reach new audiences and get them excited about all things space.”
Although NASA has streamed events to Twitch previously, this conversation will be the first NASA event from the International Space Station developed specifically for the agency’s Twitch platform.
During the event, viewers will hear from NASA astronaut Don Pettit, who is currently aboard the orbiting laboratory, and NASA astronaut Matt Dominick, who recently returned to Earth after the agency’s Crew-8 mission.
The NASA astronauts will discuss daily life aboard the space station and the research conducted in microgravity. Additionally, the event will highlight ways for Twitch users to engage with NASA, including citizen science projects and science, technology, engineering, and math programs designed to inspire the Artemis Generation.
NASA is committed to exploring new digital platforms to engage with new audiences. Last year, the agency introduced its own streaming platform, NASA+, and redesigned nasa.gov and science.nasa.gov websites, creating a new homebase for agency news, Artemis information, and more.
To keep up with the latest news from NASA and learn more about the agency, visit:
A sky chart showing Mars, Jupiter, Saturn, and Venus in a “planet parade.”
Credits: NASA/JPL-Caltech
On most nights, weather permitting, you can spot at least one bright planet in the night sky. While two or three planets are commonly visible in the hours around sunset, occasionally four or five bright planets can be seen simultaneously with the naked eye. These events, often called “planet parades” or “planetary alignments,” can generate significant public interest. Though not exceedingly rare, they’re worth observing since they don’t happen every year.
Why Planets Appear Along a Line in The Sky
“Planet parade” isn’t a technical term in astronomy, and “planetary alignment” can refer to several different phenomena. As the planets of our solar system orbit the Sun, they occasionally line up in space in events called oppositions and conjunctions. A planetary alignment can also refer to apparent lineups in our sky with other planets, the Moon, or bright stars.
The planets of our solar system always appear along a line on the sky. This line, referred to as the ecliptic, represents the plane in which the planets orbit, seen from our position within the plane itself.
NASA/Preston Dyches
When it comes to this second type of planetary alignment, it’s important to understand that planets always appear along a line or arc across the sky. This occurs because the planets orbit our Sun in a relatively flat, disc-shaped plane. From Earth, we’re looking into that solar system plane from within. We see the racetrack of the planets from the perspective of one of the racers ourselves. When viewed edge-on, this disc appears as a line, which we call the ecliptic or ecliptic plane.
So, while planet alignment itself isn’t unusual, what makes these events special is the opportunity to observe multiple planets simultaneously with the naked eye.
Will the Planets Actually be Visible?
Before preparing to observe a planet parade, we have to consider how high the planets will appear above the horizon. For most observers to see a planet with the naked eye, it needs to be at least a few degrees above the horizon, and10 degrees or higher is best. This is crucial because Earth’s atmosphere near the ground dims celestial objects as they rise or set. Even bright planets become difficult or impossible to spot when they’re too low, as their light gets scattered and absorbed on its path to your eye. Buildings, trees, and other obstructions often block the view near the horizon as well.
This visibility challenge is particularly notable after sunset or before sunrise, where the sky is still glowing. If a planet appears very low within the sunset glow, it is very difficult to observe.
The Planets You Can See, and Those You Can’t
Five planets are visible without optical aid: Mercury, Venus, Mars, Jupiter, and Saturn. Ancient civilizations recognized these worlds as bright lights that wandered across the starscape, while the background stars remained fixed in place. In fact, the word “planet” comes to us from the Greek word for “wanderer.”
The solar system includes two additional major planets, Uranus and Neptune, plus numerous dwarf planets like Pluto and Ceres. Uranus and Neptune orbit in the dim, cold depths of the outer solar system. Neptune absolutely requires a telescope to observe. While Uranus is technically bright enough to detect with good eyesight, it’s quite faint and requires dark skies and precise knowledge of its location among similarly faint stars, so a telescope is recommended. As we’ll discuss in the next section, planet parades necessarily must be observed in twilight before dawn or after sunset, and this is not a good time to try observing extremely faint objects like Uranus and Neptune.
Thus, claims about rare six- or seven-planet alignments which include Uranus and Neptune should be viewed with the understanding that these two distant planets will not be visible to the unaided eye.
What Makes Multi-Planet Lineups Special
Lineups of four or five planet naked-eye planets with optimal visibility typically occur every few years. Mars, Jupiter, and Saturn are frequently seen in the night sky, but the addition of Venus and Mercury make four- and five-planet lineups particularly noteworthy. Both orbit closer to the Sun than Earth, with smaller, faster orbits than the other planets. Venus is visible for only a couple of months at a time when it reaches its greatest separation from the Sun (called elongation), appearing just after sunset or before sunrise. Mercury, completing its orbit in just 88 days, is visible for only a couple of weeks (or even a few days) at a time just after sunset or just before sunrise.
Planet parades aren’t single-day events, as the planets move too slowly for that. Generally, multi-planet viewing opportunities last for weeks to a month or more. Even five-planet events last for several days as Mercury briefly emerges from and returns to the Sun’s glare.
In summary, while they aren’t once-in-a-lifetime events, planetary parades afford an uncommon opportunity to look up and appreciate our place in our solar system, with diverse worlds arrayed across the sky before our very eyes.
Other Planet Lineups
Other recent and near-future multi-planet viewing opportunities:
January 2016 – Four planets visible at once before sunrise
Late April to Late August 2022 – Four planets visible at once before sunrise
Mid-June to Early July 2022 – Five planets visible at once before sunrise
January to mid-February 2025 – Four planets visible at once after sunset
Late August 2025 – Four planets visible at once before sunrise
Late October 2028 – Five planets visible at once before sunrise
Late February 2034 – Five planets visible at once after sunset (Venus and Mercury challenging to observe)
About the January/February 2025 Planet Parade
The current four-planet lineup concludes by mid-February, as Saturn sinks increasingly lower in the sky each night after sunset. By mid-to-late February, Saturn appears less than 10 degrees above the horizon as sunset fades, making it difficult to observe for most people. While Mercury briefly joins Saturn in the post-sunset glow at the end of February, both planets will be too low and faint for most observers to spot.
Robotics Demonstration, Air and Water Quality Checks Aboard Orbital Lab
Astronaut Suni Williams checks out the Astrobee robotic free-flyer outfitted with tentacle-like arms containing gecko-like adhesive pads to demonstrate satellite capture techniques.
Free-flying robotics and science maintenance topped the work schedule aboard the International Space Station on Tuesday. The Expedition 72 crew also analyzed station air and water quality and set up a student-controlled camera for Earth observations.
NASA engineers are using the weightless environment of the orbital lab to study how robots might capture objects in space and remove debris and service satellites in low Earth orbit. Station Commander Suni Williams contributed to that investigation on Tuesday by activating the Astrobee robotic free-flyer and outfitting it with tentacle-like arms containing gecko-like adhesive pads. She monitored the toaster sized Astrobee, with the experimental grippers attached, as it demonstrated autonomously detecting and grappling a “capture cube”, like she did previously in December. Results may expand the space infrastructure and extend the life of assets such as satellites.
NASA Flight Engineer Don Pettit worked throughout the day on sample analysis and science maintenance. Pettit first collected station water samples and analyzed them using the Total Organic Carbon Analyzer to assess the on-orbit water quality. Next, he swapped fuel bottles inside the Combustion Integrated Rack that enables safe fuel and flame research in microgravity. Finally, Pettit relocated an airborne particulate monitor to measure air quality in the Zvezda service module.
NASA Flight Engineer Nick Hague spent Tuesday primarily on lab upkeep. Hague worked inside Northrop Grumman’s Cygnus space freighter transferring cargo in and out of the spacecraft that has been berthed to the station since Aug. 6, 2024. Afterward, he installed new software on an EXPRESS rack laptop computer that supports research operations. NASA Flight Engineer Butch Wilmore continued stowing tools inside the Quest airlock used during last week’s spacewalk then wrapped up his shift with orbital plumbing duties inside the Tranquility module.
Roscosmos Flight Engineer Aleksandr Gorbunov installed the EarthKAM Earth observation hardware inside the Harmony module, pointed the camera out a window toward Earth, and focused its lens. The camera can be remotely controlled by students on Earth to target and photograph Earth landmarks.
Flight Engineers Alexey Ovchinin and Ivan Vagner partnered together throughout Tuesday on maintenance activities inside the Zvezda service module. Ovchinin also deployed gas analyzers monitoring carbon dioxide near crew work areas and crew quarters in the orbital outpost’s Roscosmos segment.
NASA Tests in Simulated Lunar Gravity to Prep Payloads for Moon
3 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
Launch of Blue Origin’s New Shepard suborbital rocket system on Feb. 4, 2025. During the flight test, the capsule at the top detached from the booster and spun at approximately 11 rpm to simulate lunar gravity for the NASA-supported payloads inside.
Blue Origin
The old saying — “Practice makes perfect!” — applies to the Moon too. On Tuesday, NASA gave 17 technologies, instruments, and experiments the chance to practice being on the Moon… without actually going there. Instead, it was a flight test aboard a vehicle adapted to simulate lunar gravity for approximately two minutes.
The test began on February 4, 2025, with the 10:00 a.m. CST launch of Blue Origin’s New Shepard reusable suborbital rocket system in West Texas. With support from NASA’s Flight Opportunities program, the company, headquartered in Kent, Washington, enhanced the flight capabilities of its New Shepard capsule to replicate the Moon’s gravity — which is about one-sixth of Earth’s — during suborbital flight.
“Commercial companies are critical to helping NASA prepare for missions to the Moon and beyond,” said Danielle McCulloch, program executive of the agency’s Flight Opportunities program. “The more similar a test environment is to a mission’s operating environment, the better. So, we provided substantial support to this flight test to expand the available vehicle capabilities, helping ensure technologies are ready for lunar exploration.”
NASA’s Flight Opportunities program not only secured “seats” for the technologies aboard this flight — for 16 payloads inside the capsule plus one mounted externally — but also contributed to New Shepard’s upgrades to provide the environment needed to advance their readiness for the Moon and other space exploration missions.
“An extended period of simulated lunar gravity is an important test regime for NASA,” said Greg Peters, program manager for Flight Opportunities. “It’s crucial to reducing risk for innovations that might one day go to the lunar surface.”
One example is the LUCI (Lunar-g Combustion Investigation) payload, which seeks to understand material flammability on the Moon compared to Earth. This is an important component of astronaut safety in habitats on the Moon and could inform the design of potential combustion devices there. With support from the Moon to Mars Program Office within the Exploration Systems Development Mission Directorate, researchers at NASA’s Glenn Research Center in Cleveland, together with Voyager Technologies, designed LUCI to measure flame propagation directly during the Blue Origin flight.
The rest of the NASA-supported payloads on this Blue Origin flight included seven from NASA’s Game Changing Development program that seek to mitigate the impact of lunar dust and to perform construction and excavation on the lunar surface. Three other NASA payloads tested instruments to detect subsurface water on the Moon as well as to study flow physics and phase changes in lunar gravity. Rounding out the manifest were payloads from Draper, Honeybee Robotics, Purdue University, and the University of California in Santa Barbara.
Flight Opportunities is part of the agency’s Space Technology Mission Directorate and is managed at NASA’s Armstrong Flight Research Center.
By Nancy Pekar, NASA’s Flight Opportunities program
