Why young America is trending socialist  Financial Times

Why 'Tom Kean absent' is trending  CNN

The Five: Which top players are trending toward late-season surge?  PGA Tour

Trending Topics: Who will win the NBA Finals & Finals MVP?  NBA.com

Texans offseason report: Which players are trending up and down?  Houston Chronicle

1. Microsoft testing wearable AI gadget aimed at office workers  BBC
2. Build 2026: Furthering Windows as the trusted platform for development  Windows Blog
3. Microsoft unveils new AI models to lessen reliance on OpenAI and lower costs for developers  CNBC
4. Microsoft’s Project Solara is an Android OS designed for agents instead of apps  Ars Technica
5. Announcing the new Work IQ APIs  Microsoft

1. The Nvidia RTX Spark Era Starts Here: Hands On With Microsoft's Surface Laptop Ultra  PCMag
2. NVIDIA and Microsoft Reinvent Windows PCs for the Age of Personal AI  NVIDIA Newsroom
3. Two Years After Copilot+, Nvidia Is Shoving AI Into PCs Again  Gizmodo
4. Nvidia's new PC chips represent CEO Huang's bid to win at every layer of AI stack  CNBC
5. Nvidia debuts RTX Spark processor for Windows laptops, taking aim at Intel, AMD  Yahoo Finance

1. Control Resonant's release date revealed in bombshell Sony State of Play story trailer  Eurogamer
2. Control Resonant launches September 24 on PS5  PlayStation.Blog
3. Remedy’s Control sequel launches in September  The Verge
4. How to direct unconventional games like Control Resonant  Game Developer
5. New Control Resonant Trailer Shows Glimpse Of Jesse Faden And A September Release Date  Game Informer

1. Meet Microsoft Scout, Your AI Coworker That Never Logs Off  WIRED
2. Introducing Microsoft Scout: Your always-on personal agent  Microsoft
3. Microsoft launches Scout, an OpenClaw-inspired personal assistant  TechCrunch
4. Microsoft Launches AI That Works Like an Executive Assistant  Bloomberg.com
5. Microsoft Wants to 'Make People Addicted' to its New AI Assistant, Internal Documents Reveal  404 Media

1. Intel warns of "crazy" price: Arc G3 Extreme tramples AMD Ryzen Z2 Extreme for expensive price  Notebookcheck
2. I held the next-gen handheld  The Verge
3. MSI Claw 8 EX AI+ hands-on review: the most powerful gaming handheld in the world  The Shortcut | Matt Swider
4. The Intel Arc G3 Series Inside Story: How Intel Created a Purpose-built Gaming Handheld Silicon That Isn't a Hamstrung U-Segment Chip  TechPowerUp
5. MSI’s New Claw 8 Ex Could Be the Pinnacle of Gaming Handhelds  Gizmodo

From late May into early June 2026, a broad, slow-spinning storm churned north-northwest over the Philippine Sea toward southern Japan. Typhoon Jangmi’s rainbands unleashed torrential rainfall across a vast swath of the region, triggering flooding concerns in several areas.

The VIIRS (Visible Infrared Imaging Radiometer Suite) on the Suomi NPP satellite captured this nighttime image (above) of the storm at about 16:40 Universal Time on May 30 (1:40 a.m. Japan Standard Time on May 31). Around that time, the typhoon produced sustained winds of 120 kilometers (75 miles) per hour, based on 1-minute averages reported by the Joint Typhoon Warning Center (JTWC). That’s equivalent to a category 1 storm on the Saffir-Simpson hurricane wind scale.

The image shows a detailed view of the eyewall and eye, with a diameter that is on the larger end of the spectrum, according to Scott Braun, a research meteorologist at NASA’s Goddard Space Flight Center. There also appears to be some low-level rotation on the eastern side of the eye, producing features known as “mesocyclones” that are partially obscured by high-level clouds. Though they appear striking, the features are fairly typical, Braun noted.

The second image shows a wider view of the same storm one day later. The VIIRS on the NOAA-20 satellite acquired this image at about 16:40 Universal Time on May 31 (1:40 a.m. Japan Standard Time on June 1), when the storm was a slightly stronger typhoon with sustained winds of 130 kilometers (80 miles) per hour.

In both images, Jangmi’s eye was still located south of Okinawa. However, the storm’s outer cloud bands already reached over land as the storm moved north. Forecasts called for the storm to make a close approach to Okinawa and then turn northeast toward the Amami region around June 1-2. It was expected to continue delivering large amounts of rain, especially along the nation’s Pacific coast, according to news reports.

NASA Earth Observatory images by Michala Garrison, using VIIRS day-night band data from NASA EOSDIS LANCE, GIBS/Worldview, and the Joint Polar Satellite System (JPSS). Story by Kathryn Hansen.

References & Resources

• The Japan Times (2026, June 1) Tropical Storm Jangmi set to lash wide area of Japan. Accessed June 2, 2026.
• Joint Typhoon Warning Center (2026, June 1) Prognostic Reasoning for Tropical Storm 06W (Jangmi). Accessed June 2, 2026.
• The New York Times (2026, June 2) Tracking Tropical Storm Jangmi. Accessed June 2, 2026.

The Fly Foundational Robots (FFR) mission will launch a robotic arm, with seven degrees of freedom, to low Earth orbit. NASA is opening access to the robotic arm to a select group of U.S. researchers — principal investigators, post-doctoral researchers, professors, and highly qualified graduate students — who have a compelling experiment and the capability to execute it.

All participants must submit eligibility documentation at registration. Once your eligibility is reviewed and confirmed, you will receive access to the Phase 1 submission portal.

• Phase 0 — Eligibility Registration
  Begin by completing your eligibility registration. Submission documentation is required at this stage as part of federal competition requirements. Registration closes at 12:59 p.m. ET (11:59 p.m. CT) on Sept. 23.

• Phase 1 — White Paper Submission
  Submit a white paper proposing a short, focused experiment using the FFR robotic arm. Up to 15 teams advance to Phase 2. Submission closes at 12:59 p.m. ET (11:59 p.m. CT) on Oct. 2.
• Phase 2 — Simulation & Validation
  Invited participants conduct simulation and validation testing, including visits to Goddard Space Flight Center in Greenbelt, Maryland.

Prize: Teams that pass validation will receive an offer of on-orbit experiment time on the FFR Mission

Challenge Registration Open Date: May 20, 2026

Challenge Registration Close Date: September 23, 2026

For more information, visit: https://spaceroboticistchallenge.com/

Astronauts Sophie Adenot of ESA (European Space Agency) and Jack Hathaway of NASA, both Expedition 74 flight engineers, look out a window in the cupola, monitoring the automated approach and docking of the SpaceX Dragon cargo spacecraft to the International Space Station on May 17, 2026. The orbital outpost was soaring 259 miles above the Indian Ocean just west of the Maldives at the time of this photograph.

See the cupola and other parts of the space station in our guided tour.

Image credit: ESA/Sophie Adenot

A mobile wastewater treatment system built at NASA’s Kennedy Space Center in Florida that can help prepare for long-duration missions on the Moon and Mars departed the spaceport and arrived at the University of North Dakota in Grand Forks. Graduate students at the university will test the technology under conditions designed to closely mimic the challenges of operating on another planetary surface.

The Divergent Deployable Wastewater Treatment Facility is designed to turn crew wastewater into useful resources, which future explorers will need every day. At the University of North Dakota, teams will integrate this new wastewater system with the university’s Integrated Lunar/Martian Analog Habitat. Student operators and NASA researchers will study how the facility performs when connected to a habitat-like environment and exposed to the kinds of operational limits crews could face on another planet.

“NASA’s Artemis program is laying the groundwork for a sustained human presence on the Moon, where habitats will need to operate far from the steady resupply chain that supports astronauts in partial gravity,” said Luke Roberson, surface water systems lead within the Mars Campaign Office at NASA Kennedy. “To solve that challenge, we are developing the future of sustainable lunar surface systems to process wastewater into nutrient feedstocks for plants and biomanufacturing.”

How Treatment System Works

Housed inside an 8.5-by-24-foot trailer, the facility brings together three biological reactor systems, a vertical garden, water-polishing hardware, environmental monitoring, autonomous control software, and safety systems. The trailer was outfitted at NASA Kennedy to function as a deployable laboratory and to travel between at least two simulation test sites as the technology matures.

Unlike wastewater systems on Earth, this facility keeps waste streams separate. That divergent approach is important for small crews, because wastewater from four to eight people can be highly concentrated. Urine, hygiene water, laundry water, fecal waste, and food waste each contain different levels of salts, solids, carbon, nitrogen, phosphorus, and other compounds. Treating them separately allows each stream to be processed by the reactor best suited for the job.

To do that, the system uses three different bioreactors to treat waste streams. The Anaerobic Phototrophic Membrane Bioreactor processes fecal and food waste and converts it into a nutrient-rich wastewater that can support plant growth. The Suspended Aerobic Membrane Bioreactor processes urine and flush water. The Membrane Aerated Biological Reactor treats graywater from hygiene and laundry activities. Collectively, the bioreactors process nutrients to feed the facility’s vertical garden and prepare the water for reuse. Inside that garden, crops will grow hydroponically, or without using soil, by using nutrient solutions derived from the bioreactors. Researchers will compare crop performance with plants grown using standard hydroponic nutrients.

At North Dakota, under a NASA EPSCoR (Established Program to Stimulate Competitive Research) grant, the facility was connected to the Integrated Lunar/Martian Analog Habitat through a bathroom interface that includes a urine-diverting toilet. The setup will allow different waste streams to be separated at the source and sent to the correct treatment systems. In parallel, Ali Alshami’s team is developing novel membrane-based separation technologies intended for future integration into the divergent wastewater facility to improve water recovery efficiency, contaminant rejection, and overall system resilience for long-duration habitation missions.

“The tests will help NASA evaluate real-world operation, crew training needs, system reliability, and how wastewater simulants compare with actual human metabolic waste in an analog mission environment,” said Alshami.

These efforts are focused on advancing compact, energy-efficient treatment approaches capable of handling complex wastewater streams generated in closed-loop extraterrestrial environments.

“The testing campaign at the University of North Dakota supports the facility’s technology maturation from laboratory-scale validation toward demonstration in a relevant Inflatable Lunar/Martian Analog Habitat environment,” said Pablo De Leon, professor and department chair of Space Studies at the University of North Dakota.

Lessons learned could inform future higher-fidelity tests, including potential integration with NASA’s next generation of yearlong simulated Mars missions via isolation analogs at the agency’s Johnson Space Center in Houston.

Technology for Making Moon Base Sustainable

The work is part of NASA’s broader Bioregenerative Life Support Systems effort, which is developing biological approaches to reduce dependence on Earth-supplied consumables. In future lunar or Martian habitats, systems like the wastewater treatment facility could help close life support loops by recovering water, recycling nutrients, supporting crop production, and reducing the amount of waste that must be stored or discarded. Further NASA research completed trade studies demonstrating how bioregenerative life support becomes more effective for space travel over current life support technologies.

NASA researchers also are exploring how wastewater-recovered resources could support in-space manufacturing. One effort is studying how nutrient-rich water from bioregenerative wastewater systems could feed microbes that produce lactic acid, which can be turned into polylactic acid. The material could one day serve as a binder for 3D printing with lunar or Martian regolith, the loose, fragmental surface material, or could be used for replacement parts, extending the value of recovered waste beyond water and food systems.

“By sending the facility from NASA Kennedy to North Dakota, the agency is moving a key part of that circular economy out of the lab and into a real-world test,” said J.J. Edelmann, surface systems domain lead for the Mars Campaign Office at NASA Headquarters in Washington. “The work may begin with wastewater, but its goal is much larger. We want to help future crews live sustainably on the Moon, learn how to operate farther from Earth, and carry those lessons forward to Mars.”

To learn more about the agency’s lunar and Mars exploration, visit:

https://nasa.gov/esdmd

In the mid-20th century, astronomers discovered strange “clumpy” galaxies filled with mysterious bright blobs – massive stellar nurseries where stars are born at an explosive rate. Curiously, these clumpy galaxies were much more common in the early universe than they are today. We still don’t know why they vanished. 

The Euclid space telescope, an ESA (European Space Agency) mission with critical contributions from NASA, has begun to capture images of millions of galaxies. These images – far more than any team of professional scientists could ever catalog alone – include high-definition views of clumpy galaxies that promise to reveal structure within and among the clumps. Astronomers hope to use these images to obtain new information about which galaxies host clumps, where the clumps are, how and why they evolved, and more – but they need your help!

To tackle this mountain of data, scientists are creating a “digital assistant” in the form of machine learning, a kind of artificial intelligence. The machine algorithm has been partially trained with results from an earlier project called “Galaxy Zoo: Clump Scout.” Now, as a volunteer for the new Galaxy Zoo: Clump Scout II project, you’ll improve and train this tool further. You’ll examine images of galaxies that the machine has labelled with squares where it thinks it sees a real clump. The machine often gets confused by distant stars or camera glitches. So you’ll gently move those squares around, delete them, or add new ones, to help the algorithm learn.

As a part of Galaxy Zoo: Clump Scout II, you will help investigate how giant star-forming nurseries formed, solve the mystery of their disappearance over cosmic time, and reveal more about how star formation really works in galaxies. All you need is a laptop or smartphone. Click here to learn more!

Fusion startup Xcimer fired up the world's largest privately owned laser.

Even in a future of robot taxis, someone still has to return the things passengers leave behind.

The cybersecurity company is nearing a $300 million round led by Evolution Equity Partners.

Over the last few months, these DIY hardware communities have exploded in popularity as people on social media show off their solar-powered game emulators, pocket-sized ereaders, and clamshell purse computers.

Uber's cutback has occurred after the company had reportedly encouraged staff to use AI as much as possible.