NASA’s SpaceX Crew-9 Enters Quarantine Ahead of Launch

NASA’s SpaceX Crew-9 Enters Quarantine Ahead of Launch

Photo shows NASA, SpaceX Crew-9 members from right to left, Nick Hague and Roscosmos cosmonaut Aleksandr Gorbunov
From right to left, NASA SpaceX Crew-9 members Nick Hague, commander, and Roscosmos cosmonaut Aleksandr Gorbunov, mission specialist, pose for an official crew portrait at NASA’s Johnson Space Center in Houston, Texas. Photo Credit: NASA/Josh Valcarel

Members of NASA’s SpaceX Crew-9 mission will spend the next two weeks in routine preflight quarantine at the agency’s Johnson Space Center in Houston ahead of their mission to the International Space Station.

NASA and SpaceX have shifted the Crew-9 launch to no earlier than Wednesday, Sept. 25, to complete prelaunch preparations and ensure separation between operations. Liftoff is targeted for 2:28 p.m. EDT from Space Launch Complex-40 at Cape Canaveral Space Force Station in Florida aboard a SpaceX Falcon 9 rocket and Dragon spacecraft named Freedom. This is the first time a human spaceflight mission will launch from the pad. Additional launch opportunities are available on Thursday, Sept. 26, Friday, Sept. 27, and Saturday, Sept. 28.

NASA astronaut Nick Hague, commander, and Roscosmos cosmonaut Aleksandr Gorbunov, mission specialist, will remain in isolation to prevent exposure to any illnesses before they join the Expedition 72 crew at the space station. As part of the Crew-9 crew, Hague and Gorbunov will join NASA astronauts Butch Wilmore and Suni Williams, who arrived to the space station in June.

Hague and Gorbunov are set to arrive at NASA’s Kennedy Space Center in Florida on Friday, Sept. 20, where the pair will remain in quarantine at the Neil A. Armstrong Operations and Checkout Building until launch.

Crew-9 is the ninth crew rotation mission with SpaceX to the space station under NASA’s Commercial Crew Program. The crew will spend approximately five months at the orbiting laboratory conducting spacewalks, research demonstrations, and experiments before returning in February 2025.

More details about the launch will be posted on the mission blog, @commercial_crew on X, or commercial crew on Facebook.

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Elyna Niles-Carnes

Station Crew Expands to 12 as New Arrivals Work Half-Day

Station Crew Expands to 12 as New Arrivals Work Half-Day

Six Expedition 71 crew members pose for a portrait inside the Rassvet module moments before three Soyuz MS-26 crew members enter the space station.
Six Expedition 71 crew members pose for a portrait inside the Rassvet module moments before three Soyuz MS-26 crew members enter the space station.

Three new crewmates joined the International Space Station crew on Wednesday after a three-hour ride that began at the Baikonur Cosmodrome in Kazakhstan with a launch aboard the Soyuz MS-26 spacecraft. The new trio including NASA astronaut Don Pettit and Roscosmos cosmonauts Alexey Ovchinin and Ivan Wagner will live and work aboard the orbital outpost until spring 2025.

Following their arrival, the three new space residents entered the Rassvet module’s Earth-facing port and were greeted by the nine Expedition 71 crewmates expanding the orbiting lab’s crew to 12. Next, family members and teams on the ground called up to the space station and congratulated Pettit, Ovchinin, and Wagner as their mission got underway. Finally, the new trio was given a standard station safety orientation before deactivating their Soyuz crew ship, unloading cargo, and going to bed.

On Thursday, their first full day in low-Earth orbit, Pettit, Ovchinin, and Wagner woke up late and worked a half-day. Pettit began his afternoon shift getting familiar with space station systems with assistance from NASA astronaut Matthew Dominick. Pettit was last aboard the space station in 2012 as an Expedition 31 Flight Engineer when the new SpaceX Dragon cargo craft visited the orbital outpost for the first time on a test mission in May of that year. Ovchinin and Wagner continued unpacking cargo packed inside the Soyuz before attaching sensors to themselves monitoring how their circulatory system is adapting to weightlessness.

The six NASA astronauts who have been aboard the space station for a few months had a full day on Thursday studying how plants grow in microgravity, conducting eye exams, and maintaining orbital plumbing systems.

NASA Flight Engineer Jeanette Epps and Mike Barratt harvested plants growing inside the Columbus laboratory module’s Veggie space botany facility throughout the day. The space-grown samples of two types of grasses were then placed inside a science freezer for future analysis back on Earth. Researchers are seeking to understand how space affects photosynthesis and plant metabolism possibly supporting the development of bioregenerative life support systems.

Barratt also peered into the eyes of NASA astronauts Butch Wilmore and Suni Williams using standard medical imaging gear as ground personnel monitored in real-time. Some astronauts have reported vision issues so doctors continuously monitor the crew’s optic nerve, retina, cornea, and more to maintain crew health and ensure successful long-term space missions.

Earlier, Williams swapped out combustion research hardware in the Kibo laboratory module and worked on cargo transfers inside the Cygnus space freighter that has been attached to the station since Aug. 6. Wilmore checked out power supply components in Columbus then visually analyzed incubation bags containing microbe samples collected for analysis.

NASA astronaut Tracy C. Dyson joined Dominick during Thursday servicing the space station’s restroom in Tranquility module, also known as the waste and hygiene compartment. The duo removed advanced plumbing components to access and troubleshoot the toilet’s electrical power system.

Roscosmos cosmonauts Oleg Kononenko, Nikolai Chub, and Alexander Grebenkin also slept in on Thursday following their late-night support of the Soyuz MS-26 crew arrival. The trio spent the afternoon working on electrical and life support maintenance while also assisting their new crewmates.


Learn more about station activities by following the space station blog@space_station and @ISS_Research on X, as well as the ISS Facebook and ISS Instagram accounts.

Get weekly video highlights at: https://roundupreads.jsc.nasa.gov/videoupdate/

Get the latest from NASA delivered every week. Subscribe here: www.nasa.gov/subscribe

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Mark Garcia

Testing Europa Clipper’s Solar Arrays

Testing Europa Clipper’s Solar Arrays

Large black rectangular solar arrays stretch out from the foreground to the back.
NASA/Frank Michaux

On Aug. 21, 2024, engineers and technicians deployed and tested NASA’s Europa Clipper giant solar arrays. Each array measures about 46.5 feet (14.2 meters) long and about 13.5 feet (4.1 meters) high.

Europa Clipper is scheduled to launch Oct. 10, 2024, on the first mission to conduct a detailed science investigation of Jupiter’s moon Europa. Scientists predict Europa has a salty ocean beneath its icy crust that could hold the building blocks necessary to sustain life.

Learn how this spacecraft’s solar arrays will power flybys.

Image credit: NASA/Frank Michaux

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Monika Luabeya

NASA’s SpaceX Crew-9 to Conduct Space Station Research

NASA’s SpaceX Crew-9 to Conduct Space Station Research

The station pictured from the SpaceX Crew Dragon
The International Space Station is pictured from the SpaceX Crew Dragon Endeavour during a fly around.
NASA

NASA astronaut Nick Hague and Roscosmos cosmonaut Aleksandr Gorbunov are headed to the International Space Station for the agency’s SpaceX Crew-9 mission in September. Once on station, these crew members will support scientific investigations that include studies of blood clotting, effects of moisture on plants grown in space, and vision changes in astronauts.

Here are details on some of the work scheduled during the Crew-9 expedition:

Blood cell development in space

Megakaryocytes Orbiting in Outer Space and Near Earth (MeF1) investigates how environmental conditions affect the development and function of megakaryocytes and platelets. Megakaryocytes, large cells found in bone marrow, and platelets, pieces of these cells, play important roles in blood clotting and immune response.

“Understanding the development and function of megakaryocytes and platelets during long-duration spaceflight is crucial to safeguarding the health of astronauts,” said Hansjorg Schwertz, principal investigator, at the University of Utah. “Sending megakaryocyte cell cultures into space offers a unique opportunity to explore their intricate differentiation process. Microgravity also may impact other blood cells, so the insights we gain are likely to enhance our overall comprehension of how spaceflight influences blood cell production.”

Results could provide critical knowledge about the risks of changes in inflammation, immune responses, and clot formation in spaceflight and on the ground.

Two side-by-side black and white images show highly magnified individual platelets, which are roundish, pockmarked spheres with several small, arm-like protrusions.
Scanning electron-microscopy image of human platelets prior to launch to the International Space Station.
University of Utah/Megakaryocytes PI Team

Patches for NICER

The Neutron Star Interior Composition Explorer (NICER) telescope on the exterior of the space station measures X-rays emitted by neutron stars and other cosmic objects to help answer questions about matter and gravity.

In May 2023, NICER developed a “light leak” that allows sunlight to interfere with daytime measurements. Special patches designed to cover some of the damage will be installed during a future spacewalk, returning the instrument to around-the-clock operation.

“This will be the fourth science observatory and first X-ray telescope in orbit to be repaired by astronauts,” said principal investigator Keith Gendreau at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “In just a year, we diagnosed the problem, designed and tested a solution, and delivered it for launch. The space station team — from managers and safety experts to engineers and astronauts — helped us make it happen. We’re looking forward to getting back to normal science operations.”

: NICER’s X-ray concentrators are dark circles in eight staggered rows covering this image. Each one is divided into six segments, like a sliced pie, by its sunshade. The concentrators rest in a white frame of the telescope.
This view shows NICER’s 56 X-ray concentrators. Astronauts plan to cover some of them with special patches on a future spacewalk.
NASA

Vitamins for vision

Some astronauts experience vision changes, a condition called Spaceflight-Associated Neuro-ocular Syndrome. The B Complex investigation tests whether a daily B vitamin supplement can prevent or mitigate this problem and assesses how genetics may influence individual response.

“We still do not know exactly what causes this syndrome, and not everyone gets it,” said Sara Zwart, principal investigator, at the University of Texas Medical Branch, Houston. “It is likely many factors, and biological variations that make some astronauts more susceptible than others.”

One such variation could be related to a metabolic pathway that requires B vitamins to function properly. Inefficiencies in this pathway can affect the inner lining of blood vessels, resulting in leaks that may contribute to vision changes. Providing B vitamins known to affect blood vessel function positively could minimize issues in genetically at-risk astronauts.

“The concept of this study is based on 13 years of flight and ground research,” Zwart said. “We are excited to finally flight test a low-risk countermeasure that could mitigate the risk on future missions, including those to Mars.”

NASA astronaut Mark Vande Hei gets his eyes checked
NASA astronaut Mark Vande Hei conducts a vision exam on the International Space Station
NASA

Watering the space garden

As people travel farther from Earth for longer, growing food becomes increasingly important. Scientists conducted many plant growth experiments on the space station using its Veggie hardware, including Veg-01B, which demonstrated that ‘Outredgeous’ red romaine lettuce is suitable for crop production in space.

Plant Habitat-07 uses this lettuce to examine how moisture conditions affect the nutritional quality and microbial safety of plants. The Advanced Plant Habitat controls humidity, temperature, air, light, and soil moisture, creating the precise conditions needed for the experiment.

Using a plant known to grow well in space removes a challenging variable from the equation, explained Chad Vanden Bosch, principal investigator at Redwire, and this lettuce also has been proven to be safe to consume when grown in space.

“For crews building a base on the Moon or Mars, tending to plants may be low on their list of responsibilities, so plant growth systems need to be automated,” Bosch said. “Such systems may not always provide the perfect growing conditions, though, so we need to know if plants grown in suboptimal conditions are safe to consume.”

Large crinkly leaves fill two sides of the plant habitat, with a screen dividing them. There are hoses and cords to the left of the plants, which are bathed in a reddish light.
This preflight image shows lettuce grown under control (left) and flood (right) moisture treatments.
Plant Habitat-07 team

Melissa Gaskill

International Space Station Research Communications Team

NASA’s Johnson Space Center

Search this database of scientific experiments to learn more about those mentioned in this article.

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Christian M. Getteau

Printed Engines Propel the Next Industrial Revolution

Printed Engines Propel the Next Industrial Revolution

2 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

A 3D printer at RPM Innovations’ facility additively manufactures a funnel-shaped aerospike rocket engine nozzle
A laser powder directed energy deposition (LP-DED) 3D printer at RPM Innovations’ facility additively manufactures a large-scale aerospike rocket engine nozzle from one of Elementum 3D’s specialized, 3D-printable aluminum alloys.
RPM Innovations Inc.

In the fall of 2023, NASA hot fire tested an aluminum 3D printed rocket engine nozzle. Aluminum is not typically used for 3D printing because the process causes it to crack, and its low melting point makes it a challenging material for rocket engines. Yet the test was a success.

Printing aluminum engine parts could save significant time, money, and weight for future spacecraft. Elementum 3D Inc., a partner on the project, is now making those benefits available to the commercial space industry and beyond.

The hot fire test was the culmination of a relationship between NASA and Elementum that began shortly after the company was founded in 2014 to make more materials available for 3D printing. Based in Erie, Colorado, the company infuses metal alloys with particles of other materials to alter their properties and make them amenable to additive manufacturing. This became the basis of Elementum’s Reactive Additive Manufacturing (RAM) process.

An animated gif of a rocket firing on a test stand
A rocket engine nozzle 3D printed from Elementum 3D’s A6061 RAM2 aluminum alloy undergoes hot fire testing at Marshall Space Flight Center.
Credit: NASA

NASA adopted the technology, qualifying the RAM version of a common aluminum alloy for 3D printing. The agency then awarded funding to Elementum 3D and another company to print the experimental Broadsword rocket engine, demonstrating the concept’s viability.

Meanwhile, a team at NASA’s Marshall Space Flight Center in Huntsville, Alabama, was working to adapt an emerging technology to print larger engines. In 2021, Marshall awarded an Announcement of Collaborative Opportunity to Elementum 3D to modify an aluminum alloy for printing in what became the Reactive Additive Manufacturing for the Fourth Industrial Revolution project.

The project also made a commonly used aluminum alloy available for large-scale 3D printing. It is already used in large satellite components and could be implemented into microchip manufacturing equipment, Formula 1 race car parts, and more. The alloy modified for the Broadsword engine is already turning up in brake rotors and lighting fixtures. These various applications exemplify the possibilities that come from NASA’s collaboration and investment in industry. 

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Andrew Wagner