SiFive is the first company to produce a chip implementing the RISC-V ISA.

They've now been selected to provide the core CPU for NASA's next generation High-Performance Spaceflight Computing processor (or HSPC), according to a SiFive announcement: HPSC is expected to be used in virtually every future space mission, from planetary exploration to lunar and Mars surface missions.

HPSC will utilize an 8-core, SiFive® Intelligence X280 RISC-V vector core, as well as four additional SiFive RISC-V cores, to deliver 100x the computational capability of today's space computers. This massive increase in computing performance will help usher in new possibilities for a variety of mission elements such as autonomous rovers, vision processing, space flight, guidance systems, communications, and other applications....

The SiFive X280 is a multi-core capable RISC-V processor with vector extensions and SiFive Intelligence Extensions and is optimized for AI/ML compute at the edge. The X280 is ideal for applications requiring high-throughput, single-thread performance while under significant power constraints. The X280 has demonstrated a 100x increase in compute capabilities compared to today's space computers..

In scientific and space workloads, the X280 provides several orders of magnitude improvement compared to competitive CPU solutions.
A business development executive at SiFive says their X280 core "demonstrates orders of magnitude performance gains over competing processor technology," adding that the company's IP "allows NASA to take advantage of the support, flexibility, and long-term viability of the fast-growing global RISC-V ecosystem.

"We've always said that with SiFive the future has no limits, and we're excited to see the impact of our innovations extend well beyond our planet."

And their announcement stresses that open hardware is a win for everybody: The open and collaborative nature of RISC-V will allow the broad academic and scientific software development community to contribute and develop scientific applications and algorithms, as well optimizing the many math functions, filters, transforms, neural net libraries, and other software libraries, as part of a robust and long-term software ecosystem.

Stefanie Waldek reports via Space.com: Led by the Massachusetts Institute of Technology (MIT), the Mars Oxygen In-Situ Resource Utilization Experiment (MOXIE) is a small instrument on the Perseverance rover that's designed to transform carbon dioxide, which comprises some 96% of the atmosphere on Mars, into breathable oxygen. Oxygen, of course, is crucial for a human mission to Mars. Since February 2021, the device has run seven times, each time producing about 0.2 ounces (6 grams) of oxygen per hour. That's on par with the abilities of small trees here on Earth.

MOXIE has now operated in a variety of conditions on Mars, both day and night, through all four seasons. The researchers expect that a version of the instrument approximately 100 times larger than MOXIE could potentially create breathable oxygen for future astronauts who visit the Red Planet. If explorers can't make their own oxygen on Mars, supplies from Earth would take up valuable mass on a spacecraft. Furthermore, MOXIE's products could also be used as an ingredient for rocket fuel -- pretty crucial to ensuring the mission isn't one-way. A rocket would need 33 to 50 tons (30 to 45 metric tons) of liquid oxygen propellant in order to launch humans off Mars. "This is the first demonstration of actually using resources on the surface of another planetary body, and transforming them chemically into something that would be useful for a human mission," MOXIE deputy principal investigator Jeffrey Hoffman, a professor of the practice in MIT's Department of Aeronautics and Astronautics and a former NASA astronaut, said in a statement. "It's historic in that sense."

The research has been published in the journal Science Advances.

Slashdot reader tedlistens writes that "Nuclear is booming again. And with a serious pile of private and public funding behind them—and physics (see the recent breakthrough at Livermore National Lab) — these companies say they're getting closer to fusion."

The companies were profiled in a Fast Company article titled "The frontrunners in the trillion-dollar race for limitless fusion power." Last year, investors like Bill Gates and Jeff Bezos injected a record $3.4 billion into firms working on the technology, according to Pitchbook. One fusion firm, Seattle-based Helion, raised a record $500 million from Sam Altman and Peter Thiel. ... The Fusion Industry Association says that at least 33 different companies were now pursuing nuclear fusion, and predicted that fusion would be connected to the energy grid sometime in the 2030s.... And you'd be forgiven for missing another milestone in July, when the Energy Dept. announced awards of between $50,000 and $500,000, to ten fusion companies working on projects with universities and national labs.

Here are a few of the awardees, who include some of the industry's leading companies, and whose projects offer a sampling of the opportunities — and hard problems — in fusion....

Commonwealth Fusion Systems is building their first machine, SPARC, with a goal of producing power by 2025. "You'll push a button," CEO and cofounder Bob Mumgaard told the Khosla Ventures CEO Summit this summer, "and for the first time on earth you will make more power out than in from a fusion plasma. That's about 200 million degrees — you know, cooling towers will have a bunch of steam go out of them — and you let your finger off the button and it will stop, and you push the button again and it will go." With an explosion in funding from investors including Khosla, Bill Gates, George Soros, Emerson Collective and Google to name a few — they raised $1.8 billion last year alone — CFS hopes to start operating a prototype in 2025....

One morning last December, the company fired up its newest supermagnet — a 10-ton, 8-foot-tall device made of hundreds of tightly-twisted coils — and quietly pushed its magnetic field beyond a whopping 20 tesla, a record for a magnet of its size. (Most MRIs operate at a strength of about 1 tesla.) Eventually, 18 of these magnets will surround the SPARC's tokamak, which CFS says could produce as much as 11 times more energy than it consumes, and at prices cheaper than fossil fuels.
Other fusion-energy companies profiled in the article:

• Southern California-based TAE Technologies, which uses a unique non-radioactive reaction between hydrogen and boron. (Since its founding in 1998 TAE has raised $1.2 billion, with $250 million in its latest round led by Google and Chevron's venture capital arm). TAE "says it plans to start delivering power to grids by 2030, followed by 'broader commercialization' during the next decade."

• General Atomics, of San Diego, California, which built eight of the magnet modules for the ground-breaking IITER facility, "including its wild Central Solenoid — the world's most powerful magnet."

• Canada-based General Fusion (backed by Jeff Bezos and building on technology originally developed by the U.S. Navy), which hopes to generate the data need to build a commercial pilot plant.

• Princeton Fusion Systems of Plainsboro, New Jersey, uses radio-frequency electromagnetic fields to generate a plasma formation in a magnetic bottle — holding the record for the longest time such a reaction has been stably held.

• UK-based Tokamak Energy has reached the 100 million Celsius threshold for commercially viable nuclear fusion, the first to do so with a spherical, privately-funded device.

• Helicity Space, based in Pasadena, California, has 10 employees and over $4 million in funding to pursue its goal of "enabling humanity's access to the solar system, with a Helicity Drive-powered flight to Mars expected to take two months, without planetary alignment."

• Magneto-Intertial Fusion Technologies, of Tustin, California.

Redwire says it would launch the first commercial space greenhouse in Spring next year to boost crop production research outside Earth and support exploration missions. From a report: The space infrastructure company's project will help deliver critical insights for NASA's Artemis missions and beyond, said Dave Reed, Redwire's manager for the greenhouse project. The Artemis program of the National Aeronautics and Space Administration (NASA) aims at sending astronauts to the moon and establishing a long-term lunar colony as a precursor to the eventual human exploration of Mars.

The navigation strategy of NASA's Curiosity rover means it has to stop frequently to check its position, but soon a software update will allow it to move almost continuously. From a report: A new software update will soon give NASA's Curiosity Mars rover a 50 per cent speed boost, allowing it to cover a greater distance and complete more science. But the update very nearly didn't happen because of a mysterious bug in the software that eluded engineers for years. Curiosity, which landed on Mars 10 years ago this month, has already greatly outlived its planned two-year lifespan.

sciencehabit shares a report from Science Magazine: Last year, NASA achieved something science fiction writers have been dreaming about for decades: It created oxygen on Mars. A microwave-size device [called MOXIE, or the Mars Oxygen In-Situ Resource Utilization Experiment] attached to the agency's Perseverance rover converted carbon dioxide into 10 minutes of breathable oxygen. Now, physicists say they've come up with a way to use electron beams in a plasma reactor to create far more oxygen, potentially in a smaller package. The technique might someday not just help astronauts breathe on the Red Planet, but could also serve as a way to create fuel and fertilizer, says Michael Hecht, an experimental scientist at the Massachusetts Institute of Technology. But Hecht, who leads the oxygenmaking rover instrument, says the new approach still has a number of challenges to overcome before it can hitch a ride to our solar neighbor.
[...]
In the lab, he and his colleagues pumped air designed to match the pressure and composition of Mars into metal tubes. Unlike MOXIE, they didn't need to compress or heat the air. Yet, by firing an electron beam into the reaction chamber, they were able to convert about 30% of the air into oxygen. They estimate that the device could create about 14 grams of oxygen per hour: enough to support 28 minutes of breathing, the team reports today in the Journal of Applied Physics. Guerra's team still needs to solve some practical problems, Hecht notes. To work on Mars, the plasma device would need a portable power source and a place to store the oxygen it makes, all of which could make it just as -- if not more -- bulky than MOXIE, he says. If space agencies were willing to spend millions of dollars developing it -- as NASA did with MOXIE -- the plasma approach could mature, Hecht says. He especially likes how the electron beam could be tuned to split other atmospheric molecules, such as nitrogen, to create fertilizer. "There's nothing wrong with the plasma technique other than it's a lot less mature [than MOXIE]," he says.

Did Mars ever support life? One clue might be quantifying just how much ice (and other minerals) are lurking just below the planet's surface, a team of researchers argued this month. "If life exists on Mars, that is where it would be," they said in a news release this week. "There is no liquid water on the surface," but in a contrary scenario, "subsurface life would be protected from radiation."

Locating ice and minerals has another benefit too, they write in the journal Geophysical Research Letters: to "prepare for human exploration." And fortunately, there's a tool on the InSight lander (which touched down in 2018) that can help estimate the velocity of seismic waves inside the geological crust of Mars — velocities which change depending on which rock types are present, and which materials are filling pores within rocks (which could be ice, water, gas, or other mineral cements).

That's the good news. But after running computer models of applied rock physics thousands and thousands of times, the researchers believe it's unlikely that there's any layers saturated with water (or ice) in the top 300 meters (1,000 feet) of the crust of Mars. "Model results confirm that the upper 300 meters of Mars beneath InSight is most likely composed of sediments and fractured basalts."

The researchers reached a discouraging conclusion, reports Space.com "The chances of finding Martian life appear poor at in the vicinity of NASA's InSight lander." The subsurface around the landing zone — an equatorial site chosen especially for its flat terrain and good marsquake potential — appears loose and porous, with few ice grains in between gaps in the crust, researchers said.... The equatorial region where InSight is working, in theory, should be able to host subsurface water, as conditions are cold enough even there for water to freeze. But the new finding is challenging scientists' assumptions about possible ice or liquid water beneath the subsurface near InSight, whose job is to probe beneath the surface.

While images from the surface have suggested there might be sedimentary rock and lava flows beneath InSight, researchers' models have uncertainties about porosity and mineral content. InSight is helping to fill in some of those gaps, and its new data suggests that "uncemented material" largely fills in the region blow the lander. That suggests little water is present, although more data needs to be collected.

It's unclear how representative the InSight data is of the Martian subsurface in general, but more information may come courtesy of future missions. NASA is considering a Mars Life Explorer that would drill 6 feet (2 meters) below the surface to search for possible habitable conditions. Additionally, a proposed Mars Ice Mapper Mission could search for possible water reservoirs for human missions.
And of course, as the researchers point out in their announcement, "big ice sheets and frozen ground ice remain at the Martian poles."

Alphabet's "urban innovation" arm Sidewalk Labs planned to build a model "smart city" along a 12-acre patch of Toronto waterfront known as Quayside.

But they abandoned the project in 2020, points out MIT's Technology Review, "at the tail end of years of public controversy over its $900 million vision for a data-rich city within the city."

Sidewalk's big idea was flashy new tech. This unassuming section of Toronto was going to become a hub for an optimized urban experience featuring robo-taxis, heated sidewalks, autonomous garbage collection, and an extensive digital layer to monitor everything from street crossings to park bench usage. Had it succeeded, Quayside could have been a proof of concept, establishing a new development model for cities everywhere. It could have demonstrated that the sensor-Âladen smart city model embraced in China and the Persian Gulf has a place in more democratic societies. Instead, Sidewalk Labs' two-and-a-half-year struggle to build a neighborhood "from the internet up" failed to make the case for why anyone might want to live in it....

The project's tech-first approach antagonized many; its seeming lack of seriousness about the privacy concerns of Torontonians was likely the main cause of its demise. There is far less tolerance in Canada than in the U.S. for private-sector control of public streets and transportation, or for companies' collecting data on the routine activities of people living their lives. "In the U.S. it's life, liberty, and the pursuit of happiness," says Alex Ryan, a senior vice president of partnership solutions for the MaRS Discovery District, a Toronto nonprofit founded by a consortium of public and private funders and billed as North America's largest urban innovation hub. "In Canada it's peace, order, and good government. Canadians don't expect the private sector to come in and save us from government, because we have high trust in government."

With its very top-down approach, Sidewalk failed to comprehend Toronto's civic culture. Almost every person I spoke with about the project used the word "hubris" or "arrogance" to describe the company's attitude. Some people used both.
In February Toronto announced new plans for the area, the article points out, with "800 affordable apartments, a two-acre forest, a rooftop farm, a new arts venue focused on indigenous culture, and a pledge to be zero-carbon.... Indeed, the philosophical shift signaled by the new plan, with its emphasis on wind and rain and birds and bees rather than data and more data, seems like a pragmatic response to the demands of the present moment and the near future."

The article calls it "a conspicuous disavowal not only of the 2017 proposal but of the smart city concept itself."

Slashdot reader sciencehabit shared this thought-provoking anecdote from Science magazine: NASA's Lunar Crater Observation and Sensing Satellite mission was brutish and short. It began on 9 October 2009, when the hull of a spent Centaur rocket stage smashed into Cabeus crater, near the south pole of the Moon, with the force of about 2 tons of TNT. And it ended minutes later, when a trailing spacecraft flew through and analyzed the lofted plume of debris before it, too, crashed. About 6% of the plume was water, presumably from ice trapped in the shadowed depths of the crater, where the temperature never rises above -173ÂC. The Moon, it turned out, wasn't as bone dry as the Apollo astronauts believed. "That was our first ground truth that there is water ice," says Jennifer Heldmann, a planetary scientist at NASA's Ames Research Center who worked on the mission.

Today, Heldmann wants to send another rocket to probe lunar ice — but not on a one-way trip. She has her eye on Starship, a behemoth under development by private rocket company SpaceX that would be the largest flying object the world has ever seen. With Starship, Heldmann could send 100 tons to the Moon, more than twice the lunar payload of the Saturn V, the workhorse of the Apollo missions. She dreams of delivering robotic excavators and drills and retrieving ice in freezers onboard Starship, which could return to Earth with tens of tons of cargo. By analyzing characteristics such as the ice's isotopic composition and its depth, she could learn about its origin: how much of it came from a bombardment of comets and asteroids billions of years ago versus slow, steady implantation by the solar wind. She could also find out where the ice is abundant and pure enough to support human outposts. "It's high-priority science, and it's also critical for exploration," Heldmann says.

When SpaceX CEO Elon Musk talks up Starship, it's mostly about human exploration: Set up bases on Mars and make humans a multiplanetary species! Save civilization from extinction! But Heldmann and many others believe the heavy lifter could also radically change the way space scientists work. They could fly bigger and heavier instruments more often — and much more cheaply, if SpaceX's projections of cargo launch costs as low as $10 per kilogram are to be believed. On Mars, they could deploy rovers not as one-offs, but in herds. Space telescopes could grow, and fleets of satellites in low-Earth orbit could become commonplace. Astronomy, planetary science, and Earth observation could all boldly go, better than they ever have before.

Of course, Starship isn't real yet. All eyes will be on a first orbital launch test, expected sometime in the coming months.
Starship would've made it easier to deploy the massive James Webb Space Telescope, the article points out, while in the future Starship's extra fuel capacity could make it easier to explore Mercury, earth's outermost planets, and even interstellar space. In fact, Heldmann and colleagues have now suggested that NASA create a dedicated funding line for missions relying on Starship. Heldmann argues that "We on the science side need to be ready to take advantage of those capabilities when they come online."

The article notes that at an event in February, Elon Musk "explained how a single Starship, launching three times per week, would loft more than 15,000 tons to orbit in a year — about as much as all the cargo that has been lifted in the entire history of spaceflight."

A sad announcement was posted online today, reports CNN: "Last night, my mother, Nichelle Nichols, succumbed to natural causes and passed away. Her light however, like the ancient galaxies now being seen for the first time, will remain for us and future generations to enjoy, learn from, and draw inspiration," Johnson said in a statement shared to Nichols' official site on Sunday. "Hers was a life well lived and as such a model for us all."

Nichols died from natural causes, he said...

George Takei, who portrayed the USS Enterprise's helmsman Hikaru Sulu, posted a touching tribute to his co-star.

"I shall have more to say about the trailblazing, incomparable Nichelle Nichols, who shared the bridge with us as Lt. Uhura of the USS Enterprise, and who passed today at age 89," wrote Takei on Twitter. "For today, my heart is heavy, my eyes shining like the stars you now rest among, my dearest friend."

"We lived long and prospered together," he added with a photo of the pair making the iconic Vulcan salute.
It was Nichols herself who came up with the name "Uhura" for her character, she revealed years in a 2010 interview. After the series Nichols authored the science fiction novels Saturn's Child and Saturna's Quest, as well as a memoir titled Beyond Uhura — Star Trek and Other Memories.

But Nichols also served on the board of directors of the National Space Society (a charity advocating for space advocacy) — and maintained ties to other real-world space agencies. "Nichols was always interested in space travel," according to a NASA web page. "She flew aboard the C-141 Astronomy Observatory, which analyzed the atmospheres of Mars and Saturn on an eight hour, high altitude mission." But in addition, "From the late 1970's until the late 1980's, NASA employed Nichelle Nichols to recruit new astronaut candidates" (including Dr. Sally Ride).

NASA and the European Space Agency (ESA) hope to take custody of the samples Perseverance has been patiently collecting and return them safely to Earth, and they'll need the help of two more helicopters. IFLScience reports: NASA and the ESA are collaborating on putting a lander on Mars that is capable of taking off again and making a rendezvous with an orbiter which will then bring the cargo back to Earth. Rather than collect its own samples, the return mission will take over those collected by Perseverance, and the biggest change to the plans lies in how that transfer will occur. The project has not got funding yet but the space agencies are refining their plans. In a quest for the backing they need new details have been announced, along with a return date -- 2033 -- only slightly further off than 1969 was when Kennedy promised a Moon landing "before this decade is out."

Previously the Sample Return Lander was planned to carry a Sample Fetch Rover and its associated second lander. Instead, NASA and the ESA are now proposing to equip the lander with two helicopters based on the phenomenally successful Ingenuity. They will be able to traverse the gap between the Mars Ascent Vehicle and where Perseverance left them much more quickly and having two offers redundancy if one fails. There's also a possibility that Perseverance could deliver the samples directly to the Mars Ascent Vehicle if it is still operating when the ascent vehicle lands.

If everything goes to plan the Earth Return Orbiter and Sample Retrieval Lander will launch in 2027 and 2028 respectively. Although delays are common for space missions, the fact Ingenuity has continued to operate -- and even set records for its flights -- well beyond its anticipated mission time has increased the sample return team's optimism.

A Mars orbiter has captured stunning pictures of the largest canyon in the solar system, called Valles Marineris. It stretches across 2,500 miles of the red planet's equator, a distance that is roughly equivalent to the diameter of the continental United States. Motherboard reports: Mars Express, a European Space Agency (ESA) mission that arrived at Mars in 2003, recently imaged the deepest reaches of this epic canyon, where its slopes descend more than four miles into the Martian surface, which is five times deeper than the Grand Canyon, according to an ESA statement. The observations reveal two massive "chasma," or trenches, that run parallel along the western portion of Valles Marineris, known as Tithonium Chasma in the south and Ius Chasma in the north. These trenches are each about 500 miles in length, making them twice as long as the Grand Canyon -- and they encompass only about a fifth of Valles Marineris' full extent.

Mars Express snapped these shots of the chasma in April with its High Resolution Stereo Camera, during its 23,123th orbit around the planet. The images are so sharp that ESA scientists used them to generate close-up perspectives of Tithonium Chasma that resemble aerial photographs. The pictures show dark dunes, huge mountains, and the fallout of landslides within the chasma, which are annotated in an accompanying map. Canyons on Earth are usually whittled out by the flow of rivers over millions of years, but scientists believe Valles Marineris was formed by tectonic activity on Mars more than three billion years ago. [...] Valles Marineris may have also hosted liquid water billions of years ago, when Mars was wetter, warmer, and potentially habitable.

Microbes are the smallest known living organisms on Earth and can be found just about everywhere, even in the cold, Mars-like conditions of lava caves. From a report: On the island of Hawai'i, scientists recently found a marvelous assortment of novel microbes thriving in geothermal caves, lava tubes, and volcanic vents. These underground structures were formed 65 and 800 years ago and receive little to no sunlight. They can also harbor toxic minerals and gases. Yet microbial mats are a common feature of Hawai'ian lava caves. Samples of these mats, taken between 2006 and 2009 and then again between 2017 and 2019, reveal even more unique life forms than expected. When researchers sequenced 70 samples for a single RNA gene, commonly used for identifying microbial diversity and abundance, they could not match any results to known genuses or species, at least not with high confidence.

"This suggests that caves and fumaroles are under-explored diverse ecosystems," write the study's authors. e biomass in Earth's deep subsurface. Yet because these organisms are so tiny and live in such extreme environments, scientists have historically overlooked them. In recent years, underground microbes have received more interest because they exist in environments very similar to those found on Mars. But there's still a long way to go. Recent estimates suggest 99.999 percent of all microbe species remain unknown, leading some to refer to them as "dark matter." The new research from Hawai'i underscores just how obscure these life forms are.

The European Space Agency has officially terminated cooperation with Russia on a mission to put a rover on Mars, with Russia's space chief furiously responding by banning cosmonauts on the ISS from using a Europe-made robotic arm. France 24 reports: The ESA had previously suspended ties on the joint ExoMars mission, which had planned to use Russian rockets to put Europe's Rosalind Franklin rover on the red planet to drill for signs of life, due to Russia's invasion of Ukraine. ESA Director-General Josef Aschbacher tweeted on Tuesday that because the war and resulting sanctions "continue to prevail," the agency would "officially terminate" ties with Russia on ExoMars and its landing platform.

The firebrand head of Russian space agency Roscosmos Dmitry Rogozin issued an angry response. "Has the head of the European Space Agency thought about the work of thousands of scientists and engineers in Europe and Russia which has been ended by this decision? Is he prepared to answer for sabotaging a joint Mars mission?" Rogozin said on Telegram. "I, in turn, order our crew on the ISS to stop working with the European manipulator ERA," he added.

"Researchers and engineers from Kyoto University and the Kajima Corporation have released their joint proposal for a three-pronged approach to sustainable human life on the Moon and beyond," reports Gizmodo. The first element involves "The Glass," which aims to bring simulated gravity to the Moon and Mars through centrifugal force. From the report: Gravity on the Moon and Mars is about 16.5% and 37.9% of that on Earth, respectively. Lunar Glass and Mars Glass could bridge that gap; they are massive, spinning cones that will use centrifugal force to simulate the effects of Earth's gravity. These spinning cones will have an approximate radius of 328 feet (100 meters) and height of 1,312 feet (400 meters), and will complete one rotation every 20 seconds, creating a 1g experience for those inside (1g being the gravity on Earth). The researchers are targeting the back half of the 21st century for the construction of Lunar Glass, which seems unreasonably optimistic given the apparent technological expertise required to pull this off.

The second element of the plan is the "core biome complex" for "relocating a reduced ecosystem to space," according to a Google-translated version of the press release. The core biome complex would exist within the Moon Glass/Mars Glass structure and it's where the human explorers would live, according to the proposal. The final element of the proposal is the "Hexagon Space Track," or Hexatrack, a high-speed transportation infrastructure that could connect Earth, Mars, and the Moon. Hexatrack will require at least three different stations, one on Mars's moon Phobos, one in Earth orbit, and one around the Moon.

This month will mark a new chapter in the search for extraterrestrial life, when the most powerful space telescope yet built will start spying on planets that orbit other stars. Astronomers hope that the James Webb Space Telescope will reveal whether some of those planets harbor atmospheres that might support life. New York Times: Identifying an atmosphere in another solar system would be remarkable enough. But there is even a chance -- albeit tiny -- that one of these atmospheres will offer what is known as a biosignature: a signal of life itself. "I think we will be able to find planets that we think are interesting -- you know, good possibilities for life," said Megan Mansfield, an astronomer at the University of Arizona. "But we won't necessarily be able to just identify life immediately."

So far, Earth remains the only planet in the universe where life is known to exist. Scientists have been sending probes to Mars for almost 60 years and have not yet found Martians. But it is conceivable that life is hiding under the surface of the Red Planet or waiting to be discovered on a moon of Jupiter or Saturn. Some scientists have held out hope that even Venus, despite its scorching atmosphere of sulfur dioxide clouds, might be home to Venusians. Even if Earth turns out to be the only planet harboring life in our own solar system, many other solar systems in the universe hold so-called exoplanets. In 1995, Swiss astronomers spotted the first exoplanet orbiting a sunlike star. Known as 51 Pegasi b, the exoplanet turned out to be an unpromising home for life -- a puffy gas giant bigger than Jupiter, and a toasty 1,800 degrees Fahrenheit. In the years since, scientists have found more than 5,000 other exoplanets. Some of them are far more similar to Earth -- roughly the same size, made of rock rather than gas and orbiting in a "Goldilocks zone" around their star, not so close as to get cooked but not so far as to be frozen.

Photosynthesis "is very inefficient, with only about 1% of the energy found in sunlight ending up in the plant," according to a new announcement from the University of California, Riverside. But now scientists at the school and the University of Delaware "have found a way to bypass the need for biological photosynthesis altogether and create food independent of sunlight by using artificial photosynthesis." The research, published in Nature Food, uses a two-step electrocatalytic process to convert carbon dioxide, electricity, and water into acetate, the form of the main component of vinegar. Food-producing organisms then consume acetate in the dark to grow. Combined with solar panels to generate the electricity to power the electrocatalysis, this hybrid organic-inorganic system could increase the conversion efficiency of sunlight into food, up to 18 times more efficient for some foods.

"With our approach we sought to identify a new way of producing food that could break through the limits normally imposed by biological photosynthesis," said corresponding author Robert Jinkerson, a UC Riverside assistant professor of chemical and environmental engineering...

Experiments showed that a wide range of food-producing organisms can be grown in the dark directly on the acetate-rich electrolyzer output, including green algae, yeast, and fungal mycelium that produce mushrooms. Producing algae with this technology is approximately fourfold more energy efficient than growing it photosynthetically. Yeast production is about 18-fold more energy efficient than how it is typically cultivated using sugar extracted from corn. "We were able to grow food-producing organisms without any contributions from biological photosynthesis..." said Elizabeth Hann, a doctoral candidate in the Jinkerson Lab and co-lead author of the study. The potential for employing this technology to grow crop plants was also investigated. Cowpea, tomato, tobacco, rice, canola, and green pea were all able to utilize carbon from acetate when cultivated in the dark....

By liberating agriculture from complete dependence on the sun, artificial photosynthesis opens the door to countless possibilities for growing food under the increasingly difficult conditions imposed by anthropogenic climate change. Drought, floods, and reduced land availability would be less of a threat to global food security if crops for humans and animals grew in less resource-intensive, controlled environments. Crops could also be grown in cities and other areas currently unsuitable for agriculture, and even provide food for future space explorers.

"Using artificial photosynthesis approaches to produce food could be a paradigm shift for how we feed people," said corresponding author Robert Jinkerson, a UC Riverside assistant professor of chemical and environmental engineering. "By increasing the efficiency of food production, less land is needed, lessening the impact agriculture has on the environment. And for agriculture in non-traditional environments, like outer space, the increased energy efficiency could help feed more crew members with less inputs...."

"Imagine someday giant vessels growing tomato plants in the dark and on Mars — how much easier would that be for future Martians?" said co-author Martha Orozco-Cárdenas, director of the UC Riverside Plant Transformation Research Center.
Thans to Slashdot reader John.Banister for sharing the link!

CNN reports that a professor and his students at Stanford's Autonomous Systems Lab have received "phase II" funding from NASA's Innovative Advanced Concepts Program (which supports space robotics research) after proving the feasibility of their plan for robots to crawl through space caves. "The team will use the next two years to work on 3D simulations, a robot prototype, develop strategies that help the robot avoid risk, and test out [their cave robot] in a realistic mission environment — likely a cave site in New Mexico or California."

One of the students explains to CNN that "Caves are risky environments, but they're scientifically interesting. Our idea for this robot is to go far before people would get there to do interesting science and scope out the area."

CNN explains why space caves are so crucial: New research suggests that the best chance of finding past or present evidence of life on Mars requires going below its surface — at least 6.6 feet (2 meters) below. Mars has an incredibly thin atmosphere, which means that the surface of the red planet is bombarded by high energy radiation from space, and that could quickly degrade substances like amino acids that provide fragile evidence of life. Those harsh surface conditions also present a challenge for astronauts, which is one reason scientists have suggested that caves on other planets could be the key to future exploration. Vast cave systems on the moon and Mars could act as shelters for future space travelers.

Caves could also contain resources like water, reveal more about the history of a planet — and be havens for evidence of microbial life. On Earth, there are a varied range of cave systems, many of which remain unexplored, and they support diverse groups of microorganisms. But caves are dangerous — and since we've never peered inside a Martian cave, it's difficult to know what to expect.
The cave robot would presumably to be equipped with cameras, microscopes and LIDAR remote sensing, and the team envisions it will be tethered to a power-supplying rover on the surface.

One team member even told CNN the robots could be adapted to perform maintenance and upkeep on the planned "Gateway" lunar outpost between Earth and the moon.

Martian rock samples collected by NASA's Curiosity Mars rover show signs of key ingredients for life as we know it on Earth. Space.com reports: The venerable Curiosity Rover drilled samples from Gale crater, the site of an ancient lake on Mars. Using these samples, scientists were able, for the first time, to measure the total amount of organic carbon in Martian rocks, according to a statement from NASA. Organic carbon, which is carbon bound to a hydrogen atom, is a prerequisite for organic molecules created and used by all known forms of life. However, organic carbon can also come from non-living sources, such as meteorites and volcanic eruptions. While previous studies have detected organic carbon in smaller quantities in Martian rock samples, the new measurements provide insight into the total amount of carbon in organic compounds.

"Total organic carbon is one of several measurements [or indices] that help us understand how much material is available as feedstock for prebiotic chemistry and potentially biology," Jennifer Stern, lead author of the study and a space scientist at NASA's Goddard Space Flight Center in Greenbelt, Maryland, said in the statement. "We found at least 200 to 273 parts per million of organic carbon. This is comparable to or even more than the amount found in rocks in very low-life places on Earth, such as parts of the Atacama Desert in South America, and more than has been detected in Mars meteorites."

[...] However, in addition to organic carbon, the researchers identified other signs suggesting Gale crater may have once supported life, including the presence of chemical energy sources, and chemical compounds such as oxygen, nitrogen and sulfur and low acidity. "Basically, this location would have offered a habitable environment for life, if it ever was present," Stern said in the statement. Their findings were published in the Proceedings of the National Academy of Sciences.

"China's Mars sample return mission aims to collect samples from the Red Planet and deliver them to Earth in 2031, or two years ahead of a NASA and ESA joint mission," reports SpaceNews: Lifting off in late 2028... the complex, multi-launch mission will have simpler architecture in comparison with the joint NASA-ESA project, with a single Mars landing and no rovers sampling different sites. However, if successful, it would deliver to Earth the first collected Martian samples; an objective widely noted as one of the major scientific goals of space exploration....

The mission will build on the Mars entry, descent and landing technologies and techniques demonstrated by Tianwen-1 in May 2021, as well as the regolith sampling, automated lunar orbit rendezvous and docking, and high velocity atmospheric reentry success achieved by the 2020 Chang'e-5 lunar sample return mission.... Landing on Mars would take place around September 2029. Sampling techniques will include surface sampling, drilling and mobile intelligent sampling, potentially using a four-legged robot.

The ascent vehicle will consist of two stages, using either solid or liquid propulsion, and will be required to reach a speed of 4.5 kilometers per second, according to the presentation. After rendezvous and docking with the waiting orbiter, the spacecraft will depart Mars orbit in late October 2030 for a return to Earth in July 2031.

Sun Zezhou [chief designer of the Tianwen-1 Mars orbiter and rover mission], added that the Tianwen-1 orbiter will conduct an aerobraking test in Mars orbit later this year as part of the sample return mission preparation.
Thanks to Slashdot reader Hmmmmmm for sharing the story!