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Category: sustainability

David Brin: What’s Important Isn’t Me. And It Isn’t You. It’s Us!

David Brin warned us. In 1989.

Global warming. Cyberwarfare. The World Wide Web, named in a novel before most people had ever heard of it.

I recorded this conversation with him 14 years ago. Astrophysicist. Hugo and Nebula winner. The mind behind the Uplift novels and Existence.

We dug into the most powerful form of science fiction. Not the prophecy that comes true. The prophecy that prevents itself. Orwell’s 1984 is the classic case. The warning so loud the future course-corrects.

We also went straight at #transparency. His book asks a question that hits harder now than it did then: will technology force us to choose between #privacy and freedom? Fourteen years on, with AI watching everything, that question is no longer hypothetical.

And then there is the line from David that I have never been able to shake.

Continue reading “David Brin: What’s Important Isn’t Me. And It Isn’t You. It’s Us!” | >

Space Renaissance International at COPUOS 69, Vienna, 10

(SRI) was represented at the 69th Session of the United Nations Committee on the Peaceful Uses of Outer Space (UN COPUOS) in Vienna, Austria, by Bernard Foing, Dr. Gülin Dede, Werner Grandl, and Enes Beşli. The SRI delegation contributed to the session’s dialogue through two technical presentations: one delivered by Werner Grandl, “The Legacy of Gerard K. O’Neill and the Urgency to Start Experimentation on Simulated Gravity,” and another by Dr. Gülin Dede titled “Sustainability Beyond Earth: The Case for an 18th Sustainable Development Goal.” Throughout the session, the delegation engaged in productive discussions with international stakeholders and explored potential avenues for collaboration in support of SRI’s vision for a sustainable and inclusive space future. The delegation also attended the side event “Delivering Water Diplomacy through Space,” jointly co-organised by the European Space Policy Institute and Slovenia.

SRI further observed the “Space4Industry, UNOOSA/UNIDO Signing Ceremony,” co-organised by UNOOSA and UNIDO, as well as the “Space4Resilience Initiative, From Data to Decision: AI-Driven 3D Digital Twin Technologies for Disaster Infrastructure Resilience and Sustainable Industrial Development,” co-organized by UN-SPIDER and Japan.

SRI supports the utilization of space technologies in addressing global challenges, advancing sustainable industry, and strengthening international cooperation.

Merging Humans and AI: The Rise of Biological Computers

It’s no secret that tech companies are racing to build “artificial general intelligence,” or AI that can match a human brain without needing a lifeline. But our brains already do the same heavy lifting with just a fraction of the resources. Whether it’s energy, water, land, components, or, you know… money… human brains are just way cheaper. Right now, you can either buy a human brain cell-based computer… or rent time on a remote one. Yep, even brainpower’s got a subscription plan these days. So what can these living computers actually do? How do they work? And, most importantly, should we be freaking out a little bit?

Watch how deep sea water is now drinkable • how deep sea water is now drinkable.

Video script and citations:
https://undecided.tech/how-living-com… my achieve energy security with solar guide: https://undecided.link/solar-guide Follow-up podcast: Video version — / @stilltbd Audio version — https://undecided.link/stilltbd-podcast Join the Undecided Discord server: https://undecided.link/discord 👋 Support Undecided on Patreon! / mattferrell ⚙️ Gear & Products I Like https://undecided.tech/shop/ Visit my Energysage Portal (US): Research solar panels, heat pumps, and more to get quotes for free! https://undecided.link/energysage For a curated solar buying experience (Canada) EnergyPal’s free personalized quotes: https://undecided.link/energypal 👉 Follow Me Mastodon https://mastodon.social/@mattferrell Instagram / undecidedtech Website https://undecided.tech Some music provided by Epidemic Sound https://undecided.link/epidemic I may earn a small commission for my endorsement or recommendation to products or services linked above, but I wouldn’t put them here if I didn’t like them. Your purchase helps support the channel and the videos I produce. Thank you. Chapters 00:00 — Intro 01:54 — Why? 05:29 — How? 09:17 — What? 15:59 — The Bigger Questions 17:28 — When?

Get my achieve energy security with solar guide:
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Follow-up podcast:
Video version — / @stilltbd.
Audio version — https://undecided.link/stilltbd-podcast.

Join the Undecided Discord server:
https://undecided.link/discord.

Is extracting oxygen from lunar soil the future of space exploration?

A new race to the moon is emerging between the United States and China. Unlike fifty years ago, the goal is no longer just about landing and leaving, but establishing a base that allows for a sustainable presence and extended stays on the surface of our natural satellite. The objective is now to use the moon as a testing ground for technologies that will enable us to travel further, particularly to Mars.

One of these key technologies is in-situ resource utilization (ISRU), which involves using available resources on-site to produce the consumables necessary for human activities: oxygen, water, rocket fuels, or construction materials. By producing these essentials directly on the moon, it will be possible to significantly reduce the mass of cargo sent from Earth, thereby reducing the logistical and financial costs of space exploration. Instead of importing these resources from Earth, the goal is to learn how to live on the moon.

Breaking down lunar dust to extract oxygen At the dawn of humanity’s sustainable return to the moon, ISRU is emerging as a strategic pivot. One of the major challenges is producing oxygen from regolith, the layer of soil covering the moon, primarily composed of small rock fragments and dust. The composition of regolith is complex, mainly consisting of several minerals (plagioclase, pyroxene, olivine) themselves made up of a mixture of metal oxides—chemical compounds that combine oxygen with another element such as silicon, iron, or calcium.

AI-guided catalyst turns CO₂ and waste into fertilizer at industrially relevant rates

Researchers from the National University of Singapore (NUS) have developed a computation-guided strategy to produce urea more efficiently from carbon dioxide and nitrate. By combining large language models, density functional theory calculations and experiments, the approach identified a cadmium-modified iron oxide catalyst that maintains high urea selectivity at practical current densities.

Urea is one of the world’s most widely used fertilizers, but its conventional production comes at a heavy environmental cost. The industrial process accounts for more than two percent of global energy consumption and releases over 200 million tons of carbon dioxide each year.

A cleaner alternative is to produce urea electrochemically, using low-carbon electricity to convert carbon dioxide and nitrate into a useful product. However, this approach has been difficult to scale up. At the high current densities needed for practical production, the catalysts often favor competing side reactions, such as hydrogen gas formation or carbon dioxide reduction to other products.

One photon, two reactions—new catalyst converts CO₂ and biowaste simultaneously

Researchers have developed a solar-driven catalyst material that harnesses the energy of a single photon to reduce carbon dioxide and oxidize organic waste at the same time, producing valuable chemicals in both reactions.

Scientists at the University of Nottingham have created two catalyst materials that, when coupled together within the same reactor, can simultaneously convert carbon dioxide (CO₂) into a valuable chemical and biomass-derived feedstock into building blocks for sustainable plastics, driven solely by solar light. The research has been published in Communications Materials.

A bias-free photoelectrochemical (PEC) reactor consists of two connected compartments, each containing the newly developed catalysts. When sunlight shines on one compartment, each photon drives the oxidation of a biowaste molecule. The electron released during this process is then transferred to the second compartment, where it reduces CO₂ to formate.

New water-based material could store solar energy, power reactions in darkness, then recharge

Northwestern University scientists have developed a new liquid material that charges like a battery, transforms like a living organism and then resets itself in open air. Traditionally, harvesting energy, storing it and using it require separate materials or devices. The new platform merges all three functions into a single material, opening the door for adaptive, clean, renewable systems that don’t require plastics or metals.

The study is published in Chem. It marks the first report of a material that stores energy by physically rebuilding itself.

To design the material, the researchers drew inspiration from the cytoskeleton —a cell’s dynamic internal scaffold that enables it to maintain its shape, move and divide. Unlike animals’ rigid skeletons, cytoskeletons constantly build, dismantle and rebuild themselves. Northwestern’s new material behaves in a similar way, repeatedly assembling and disassembling as it stores and releases energy. But instead of running on biological fuels, it is powered by electrons harvested from sunlight, electricity, X-rays and other energy sources.

This specially-designed jacket pulls drinking water from thin air

Engineers at The University of Texas at Austin have developed a jacket that harvests drinking water directly from the air. The technology could benefit anyone who spends a lot of time in areas without easy access to drinking water, from hobbyist hikers, campers and runners to agricultural workers, emergency responders and soldiers. The advance in fabric technology comes alongside a new benchmark for atmospheric water harvesting.

“Water harvesting from air is usually imagined as a stationary device such as a box, a panel or a large sorbent bed,” said Guihua Yu, chair professor of the Cockrell School of Engineering’s Walker Department of Mechanical Engineering and Texas Materials Institute and one of the leaders of the new research appearing in Science Advances. “Here, we wanted to rethink the form of the technology. If the fabric itself can collect water from air, it opens a new direction for personal and portable water access.”

The textile incorporated into the jacket collects moisture and funnels it to detachable harvesting units. Those units are placed in a foldable collector piece and heated to produce water.

CO₂ injection reveals hidden cement chemistry behind 13% stronger early strength

One September day, it started to snow inside MIT’s Pierce Laboratory. Researchers depressurized a tank of liquid carbon dioxide (CO2), instantly freezing it and releasing solid flakes. These were blended into cement paste and pressed into disks roughly the size of a dime, each sealed with a thin layer of vegetable oil to keep water in and air out. The team trained lasers on each one, observing for the first time the transient chemical reaction that might explain why CO2-injected cement paste gains strength faster.

Injecting CO2 into cement products like concrete is one way to store it and keep it out of the atmosphere. The process has attracted commercial interest, with a growing number of companies offering CO2-injected concrete mixes. But until now, the underlying cement chemistry hadn’t been directly visualized.

A new paper in the Journal of the American Ceramic Society —led by associate professor Admir Masic and first-authored by graduate student Marcin Hajduczek, both of the MIT Concrete Sustainability Hub and MIT Department of Civil and Environmental Engineering—describes the chemical sequence that unfolds after CO2 meets fresh cement paste. Co-authors include MIT colleagues Santiago El Awad and Franz-Josef Ulm, alongside researchers from IIT Jodhpur and CarbonCure Technologies.

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