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Live Video from the International Space Station (Seen From The NASA ISS Live Stream)
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By Amazing Space
Live Video from the International Space Station (Seen From The NASA ISS Live Stream)
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By Amazing Space
Live Video from the International Space Station (Seen From The NASA ISS Live Stream)
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By NASA
3 Min Read NASA Seeks Industry Input on Next Phase of Commercial Space Stations
The aurora australis appears over the Earth in this photograph taken from the International Space Station as it orbited 269 miles above the Indian Ocean southwest of Australia. Credits: NASA NASA is requesting feedback from American companies on the next phase of its commercial space stations strategy to ensure a seamless transition of activities in low Earth orbit from the International Space Station.
The agency released a draft Phase 2 Announcement for Partnership Proposals (AFPP) Friday, asking for feedback from industry partners by 1 p.m. EDT Friday, Sept. 12. NASA will hold an informational industry briefing on Monday, Sept. 8, to provide a top-level summary of the documents and expectations.
Under the direction of acting NASA Administrator Sean Duffy, the agency reassessed the commercial space stations acquisition strategy to ensure mission continuity, affordability, and national alignment, and to reduce the potential for a gap of a crew-capable platform in low Earth orbit.
“NASA has led in low Earth orbit for 25 years and counting. Now, as we prepare for deorbiting the International Space Station in 2030, we’re calling on our commercial space partners to maintain this historic human presence,” Duffy said. “The American space industry is booming. Insight from these innovative companies will be invaluable as we work to chart the next phase of commercial space stations.”
In Phase 2, NASA intends to support industry’s design and demonstration of commercial stations through multiple funded Space Act Agreements, selected through a full and open competition.
“NASA is committed to continuing our partnership with industry to ensure a continuity in low Earth orbit,” said Angela Hart, manager, Commercial Low Earth Orbit Development Program at NASA’s Johnson Space Center in Houston. “The work done under our Phase 1 contracts and agreements have put us in a prime position to be successful for this next funded Space Act Agreement phase. By leveraging these agreements, we provide additional flexibility to our commercial partners to define the best path forward to provide NASA a safe and affordable crewed demonstration.”
The Phase 2 agreements are expected to include funded milestones leading to critical design review readiness and an in-space crewed demonstration of four crew members for a minimum of 30 days. Agreements are expected to include up to a five-year period of performance.
The agency’s phased approach will culminate in a follow-on Phase 3 using Federal Acquisition Regulation-based contract(s) to purchase station services through a full and open competition. This final phase will also provide formal design acceptance and certification, ensuring the commercial stations meet NASA’s safety requirements.
NASA remains committed to fostering innovation and collaboration within the American space industry.
The agency’s commercial strategy for low Earth orbit will provide the government with reliable and safe services at a lower cost, enabling the agency to focus on the next step in humanity’s exploration of the solar system while also continuing to use low Earth orbit as an ideal environment for training and a proving ground for Artemis missions to the Moon and Mars.
Learn more about commercial space stations at:
https://www.nasa.gov/commercialspacestations
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By NASA
The Roscosmos Progress 92 cargo spacecraft approaches the International Space Station on July 5, 2025, for an automated docking to the orbital complex’s Poisk module.Credit: NASA NASA will provide live coverage of the launch and docking of a Roscosmos cargo spacecraft carrying about three tons of food, fuel, and supplies for the crew aboard the International Space Station.
The unpiloted Roscosmos Progress 93 resupply spacecraft is scheduled to launch at 11:54 a.m. EDT (8:54 p.m. Baikonur time), Thursday, Sept. 11, on a Soyuz rocket from the Baikonur Cosmodrome in Kazakhstan.
Live coverage will begin at 11:30 a.m. on NASA+, Amazon Prime, and more. Learn how to watch NASA content through a variety of platforms, including social media.
After a two-day journey to the station, the spacecraft will dock autonomously to the aft port of the station’s Zvezda module at 1:27 p.m. on Saturday, Sept. 13. NASA’s rendezvous and docking coverage will begin at 12:30 p.m. on NASA+, Amazon Prime, and more.
The Progress 93 spacecraft will remain docked to the space station for approximately six months before departing for re-entry into Earth’s atmosphere to dispose of trash loaded by the crew. Ahead of the spacecraft’s arrival, the Progress 91 spacecraft will undock from the Zvezda Service Module on Tuesday, Sept. 9. NASA will not stream the undocking.
The International Space Station is a convergence of science, technology, and human innovation enabling research not possible on Earth. For nearly 25 years, NASA has supported a continuous U.S. human presence aboard the orbiting laboratory, where astronauts have learned to live and work in space for extended periods of time. The space station is a springboard for developing a low Earth economy and NASA’s next great leaps in human exploration at the Moon and Mars.
Learn more about the International Space Station, its research, and crew, at:
https://www.nasa.gov/station
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Jimi Russell
Headquarters, Washington
202-358-1100
james.j.russell@nasa.gov
Sandra Jones / Joseph Zakrzewski
Johnson Space Center, Houston
281-483-5111
sandra.p.jones@nasa.gov / joseph.a.zakrzewski@nasa.gov
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Last Updated Sep 05, 2025 LocationNASA Headquarters Related Terms
International Space Station (ISS) ISS Research Johnson Space Center View the full article
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By NASA
NASA and Northrop Grumman are preparing to send the company’s next cargo mission to the International Space Station, flying research to support Artemis missions to the Moon and human exploration of Mars and beyond, while improving life on Earth. SpaceX’s Falcon 9 rocket will launch Northrop Grumman’s 23rd commercial resupply services mission to the orbiting laboratory.
The investigations aboard the Cygnus spacecraft aim to refine semiconductor crystals for next-generation technologies, reduce harmful microbes, improve medication production, and manage fuel pressure.
NASA, Northrop Grumman, and SpaceX are targeting launch in mid-September from Space Launch Complex 40 at Cape Canaveral Space Force Station in Florida.
Read about some of the investigations traveling to the space station:
Better semiconductor crystals
Optical micrograph of a semiconductor composite wafer with embedded semimetal phases extracted from a space grown crystal in the SUBSA facility during Mission 1United Semiconductors LLC Researchers are continuing to fine-tune in-space production of semiconductor crystals, which are critical for modern devices like cellphones and computers.
The space station’s microgravity environment could enable large-scale manufacturing of complex materials, and leveraging the orbiting platform for crystal production is expected to lead to next-generation semiconductor technologies with higher performance, chip yield, and reliability.
“Semiconductor devices fabricated using crystals from a previous mission demonstrated performance gain by a factor of two and device yield enhanced by a factor of 10 compared to Earth-based counterparts,” said Partha S. Dutta, principal investigator, United Semiconductors LLC in Los Alamitos, California.
Dutta highlighted that three independent parties validated microgravity’s benefits for growing semiconductor crystals and that the commercial value of microgravity-enhanced crystals could be worth more than $1 million per kilogram (2.2 pounds).
Space-manufactured crystals could help meet the need for radiation-hardened, low-power, high-speed electronics and sensors for space systems. They also could provide reduced power use, increased speed, and improved safety. The technology also has ground applications, including electric vehicles, waste heat recovery, and medical tools.
Learn more about the SUBSA-InSPA-SSCug experiment.
Lethal light
Germicidal Ultraviolet (UV) light is emitted by an optical fiber running through the center of an agar plateArizona State University Researchers are examining how microgravity affects ultraviolet (UV) light’s ability to prevent the formation of biofilms — communities of microbes that form in water systems. Investigators developed special optical fibers to deliver the UV light, which could provide targeted, long-lasting, and chemical-free disinfection in space and on Earth.
“In any water-based system, bacterial biofilms can form on surfaces like pipes, valves, and sensors,” said co-investigator Paul Westerhoff, a professor at Arizona State University in Tempe. “This can cause serious problems like corrosion and equipment failure, and affect human health.”
The UV light breaks up DNA in microorganisms, preventing them from reproducing and forming biofilms. Preliminary evidence suggests biofilms behave differently in microgravity, which may affect how the UV light reaches and damages bacterial DNA.
“What we’ll learn about biofilms and UV light in microgravity could help us design safer water and air systems not just for space exploration, but for hospitals, homes, and industries back on Earth,” Westerhoff said.
Learn more about the GULBI experiment.
Sowing seeds for pharmaceuticals
NASA astronaut Loral O’Hara displays the specialized sample processor used for pharmaceutical research aboard the International Space StationNASA An investigation using a specialized pharmaceutical laboratory aboard the space station examines how microgravity may alter and enhance crystal structures of drug molecules. Crystal structure can affect the production, storage, effectiveness, and administration of medications.
“We are exploring drugs with applications in cardiovascular, immunologic, and neurodegenerative disease as well as cancer,” said principal investigator Ken Savin of Redwire Space Technologies in Greenville, Indiana. “We expect microgravity to yield larger, more uniform crystals.”
Once the samples return to Earth, researchers at Purdue University in West Lafayette, Indiana, will examine the crystal structures.
The investigators hope to use the space-made crystals as seeds to produce significant numbers of crystals on Earth.
“We have demonstrated this technique with a few examples, but need to see if it works in many examples,” Savin said. “It’s like being on a treasure hunt with every experiment.”
This research also helps enhance and expand commercial use of the space station for next-generation biotechnology research and in-space production of medications.
Learn more about the ADSEP PIL-11 experiment.
Keeping fuel cool
iss0NASA astronaut Joe Acaba installs hardware for the first effort in 2017 aboard the International Space Station to test controlling pressure in cryogenic fuel tanksNASA Many spacecraft use cryogenic or extremely cold fluids as fuel for propulsion systems. These fluids are kept at hundreds of degrees below zero to remain in a liquid state, making them difficult to use in space where ambient temperatures can vary significantly. If these fluids get too warm, they turn into gas and boiloff, or slowly evaporate and escape the tank, affecting fuel efficiency and mission planning.
A current practice to prevent this uses onboard fuel to cool systems before transferring fuel, but this practice is wasteful and not feasible for Artemis missions to the Moon and future exploration of Mars and beyond. A potential alternative is using special gases that do not turn into liquids at cold temperatures to act as a barrier in the tank and control the movement of the fuel.
Researchers are testing this method to control fuel tank pressure in microgravity. It could save an estimated 42% of propellant mass per year, according to Mohammad Kassemi, a researcher at NASA’s National Center for Space Exploration Research and Case Western Reserve University in Cleveland.
The test could provide insights that help improve the design of lightweight, efficient, long-term in-space cryogenic storage systems for future deep space exploration missions.
Learn more about the ZBOT-NC experiment.
Download high-resolution photos and videos of the research highlighted in this feature.
Learn more about the research aboard the International Space Station at:
www.nasa.gov/iss-science
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